Spectre Circuit Simulator User Guide
Contents
1. Product Version 5 0 Spectre Circuit Simulator User Guide with the save and nestlvl parameters 217 229 groups of signals in main circuits with the save parameter 217 229 in subcircuits 218 230 in subcircuits with the nestlvl parameter 217 229 individual currents with current probes 214 226 with the save statement 211 224 individual signals of subcircuits 213 225 main circuit signals See save statement 211 224 measurements for current controlled components 214 227 parameter values 202 232 signals from subcircuit calls 213 225 saving power 215 228 scalarfile parameter Monte Carlo analysis 167 scale factors 83 scale parameter devices scaled by 118 how affected by default units of components 119 in alter statement 189 266 scalem parameter devices scaled by 118 how affected by default component 11 in alter statement 189 266 scaling parameter values in Spectre 83 inSPICE 83 physical dimensions of components 118 schematic 26 screen printout example 33 second order Gear integration method 144 seed parameter Monte Carlo analysis 166 selected as save parameter option 217 230 units of sens analysis 151 sens command example 152 formatting 151 sensitivity analysis 151 set statement to modify options statement January 2004 settings 267 setting tolerances with the quantity statement 76 shell initialization file and C2. When the environment variable CMI CONFIG is set to site cmi config only libstmodels so is loaded A model developer can create a file SHOME myLib libmybjt so consisting of the BUT model under development To check the results of the BUT under development in January 2004 315 Product Version 5 0 Spectre Circuit Simulator User Guide Dynamic Loading libmybjt so with the BUT503 models in 1ibphilips so the developer can create a CMI configuration file in the home directory as follows this is SHOME cmiconfig file I want to include libphilips so released by Cadence so that 7I can check my BJT with BJT503 load libphilips so I also want to include my BJT model from libmybjt so append SHOME myLib load libmybjt so CMI Versioning The version format for CMI is ma jor minor The value of ma jor is increased when there are major changes that require CMI developers to recompile their components Type spectre cmiversion to display the current CMI version The Spectre circuit simulator checks for CMI version compatibility for each shared object as well as for each primitive This ensures that WB A shared object is compiled with the latest version of CMI m The source code for each device primitive is up to date Note A primitive can be installed only once Different versions of the same primitive cannot be used January 2004 316 Product Version 5 0 Spectre Circuit Si
3. 269 Description of Spectre Predefined Percent Codes 270 Customizing Percent Codes 3 esu hos Chee es eee Ga LR RA UR R ele wee 271 Creating Filenames from Parts of Input Filenames 00 0055 272 13 Identifying Problems and Troubleshooting 275 ERROR OMOMMOMS xoi sch do xod eo Et c No dos Odes aes ek ae ako IE ra ca Sa lack e eae 275 Invalid Parameter Values That Terminate the Program s 275 Sing lar Matrices 4o pim iai en end ace dee neta d atra uds bet re dea 276 Internal Error Messages xcumemed n hau ori Det e Bee iC uad ek Ede poll 277 Time Is Not Strictly Increasing lt 2 2 235 dudes ones ates die alegaeke dee eed 278 Spectre Warning Messages cece tenets 278 P N Junction Warning Messages 0c cece eee eens 278 Tolerances Might Be Set Too Tight ccc eee 280 Parameter Is Unusually Large or Small 2 5xit eet ads eee RE RS Sees 280 gmin Is Large Enough to Noticeably Affect the DC Solution 280 Minimum Timestep Used a esso eer LREKENE ERES bL e As ie 281 SyntexEITOIS 42 214 E etote i dives 14 020 tani beta chet panis ES d 281 Topology Messages 5 2 2 2 wb oie Bidje wileons acd 209 090 OHA ket A cR onu a dete wok ad edt 282 Model Parameter Values Clamped llle 282 Invalid Parameter WWarrnitiS 5x vr Y uter he RA COME Ere xa eq oe deo A RUE 282 Redefine Primitiv
4. OK Cancel Appy Add 2 In the Foreground field select the color for the trace 3 Click OK Learning More about WaveScan The WaveScan display tool gives you a number of additional options for displaying your data To learn more about using WaveScan see the WaveScan User Guide January 2004 38 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre January 2004 39 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre January 2004 40 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility While SPICE is an industry standard language there are many variations of SPICE syntax on the market today Most of the language is common across the major commercial simulators but each vendor has extended or modified it with different capabilities and or slightly different syntax For the convenience of SPICE users the Spectre circuit simulator provides a SPICE Reader as an extension to its native language that accepts most variations of SPICE input The SPICE Reader provides support for SPICE2 SPICE3 and common extensions found in other simulators such as PSPICE and HSPICE This chapter focuses on how to use the SPICE Reader with Spectre This chapter is not intended to describe the syntax variations of SPICE as they are well documented in other places nor an exact listing of syntax supported by the SPICE Reader m Re
5. Artificial numerical damping can reduce accuracy when you simulate low loss high Q resonators such as oscillators and filters Second order Gear shows this damping and backward Euler exhibits heavy damping Improving Transient Analysis Convergence If the circuit you simulate can have infinitely fast transitions for example a circuit that contains nodes with no capacitance the Spectre simulator might have convergence problems To avoid these problems set cmin which is the minimum capacitance to ground at each node to a physically reasonable nonzero value You also might want to adjust the time step parameters step and maxstep step iS a suggested time step you can enter Its default value is 001 stop start maxstep is the largest time step permitted Controlling the Amount of Output Data The Spectre simulator normally saves all computed data in the transient analysis Sometimes you might not need this much data and you might want to save only selected results At other times you might need to decrease the time interval between data points to get a more precise measurement of the activity of the circuit You can control the number of output data points the Spectre simulator saves for the transient analysis in these ways m With strobing which lets you select the time interval between the data points the Spectre simulator saves The simulator forces a time step on each point it saves so the data is computed not interpolate
6. B Set the nest1v1 parameter to the number of levels in the hierarchy you want to save The default setting for nest 1v1 is infinity which saves all levels Saving Groups of Currents The currents parameter of the opt ions statement computes and saves terminal currents You use it to create settings for currents that apply to all terminals in the netlist January 2004 230 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options For two terminal components the Spectre simulator saves only the first terminal entering currents You must use a save statement or use the global redundant_currents parameter of the options statement to save data for the second terminal of a two terminal component For more information about the save statement see Saving Signals for Individual Nodes and Components on page 223 Setting the currents Parameter The currents parameter has the following options Setting Action selected Saves only currents that you specifically request with save statements or save parameters Also saves naturally computed branch currents currents through current probes voltage sources and inductors This is the default setting nonlinear Saves all terminal currents for nonlinear devices naturally computed branch currents currents through current probes voltage sources and inductors and currents you specify with save statements Can significantly increase simulatio
7. Bitwise exclusive NOR of integer NOR operands Bitwise OR Bitwise OR of integer operands Logical AND amp amp True only if both operands true Logical OR ll True if either operand is true Conditional selection cond Returns x if cond is true y if not where x and y are expressions Algebraic and Trigonometric Functions The trigonometric and hyperbolic functions expect their operands to be specified in radians The atan2 and hypot functions are useful for converting from Cartesian to polar form Function Description Domain log x Natural logarithm x gt 0 log10 x Decimal logarithm x gt 0 exp x Exponential x lt 80 sqrt x Square root x gt 0 January 2004 88 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Function Description Domain min x y Minimum value All x all y max x y Maximum value All x all y abs x Absolute value All x pow x y x to the power of y All x all y sin x Sine All x cos x Cosine All x tan x Tangent All x except x n x 2 where n is odd asin x Arc sine 1 lt x lt 1 acos x Arc cosine 1 lt x lt 1 atan x Arc tangent All x atan2 x y Arc tangent of x y All x all y hypot x y sinh x cosh x tanh x asinh x acosh x atanh x int x ceil x floor x fmod x y sqrt x x y y All x all y Hyperbolic sine All x Hyperbolic cosine All
8. a base TNSA subckt that is a simple TNSA bipolar transistor subcircuit with model statement inline subckt TNSA B C B E S parameters MULT 1 IS 1e 15 BF 100 model modX bjt type npn is IS bf BF a model statement TNSA B CB E S modX m MULT inline device instance ends TNSA B a base resistor a simple RPLR resistor subcircuit inline subckt RPLR B A B parameters R MULT 1 RPLR B A B resistor r R m MULT inline device ends RPLR B define process geometry dependent bipolar and resistor devices a geometrical process TNSA subcircuit a BJT subcircuit with process and geometry effects modeled bipolar model parameters IS and BF are functions of effective emitter area perimeter taking process factors for example nonideal etching into account inline subckt TNSA PR CB E S parameters WE LE MULT 1 dIS 0 dBF 0 WEA WE SNDW effective or Actual emitter width LEA LE SNDW effective or Actual emitter length AE WEA LEA effectiv mitter area F Is 1e 1 BAERSHETAAET Ue DUNS f ac sqrE AE XISNbfac dIS 2 XISN 1 sqrt MULT UNE di ce AE XBFNbfac dBF 2 XBFN 1 sqrt MULT Tj TNSA PR CB E S TNSA B IS IS BF BF MULT MULT inline ends TNSA PR a geometrical process RPLR resistor subcircuit resistance is function of effective device geometry taking
9. m The current for inductor L1 is set to 1p Specifying State Information for Individual Analyses You can specify state information for individual analyses in two ways January 2004 199 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements m You can use the ic parameter of the transient analysis to choose which previous specifications are used m You can create a state file that is read by an individual analysis Choosing Which Initial Conditions Specifications Are Used for a Transient Analysis The ic parameter in the transient analysis lets you select among several options for which initial conditions to use You can choose the following settings Parameter Setting Action Taken dc Initial conditions specifiers are ignored and the existing DC solution is used node The ic statements are used and the ic parameter settings on the capacitors and inductors are ignored dev The ic parameter settings on the capacitors and inductors are used and the ic statements are ignored all Both the ic statements and the ic parameters are used If specifications conflict ic parameters override ic statements Specifying State Information with State Files You can also specify initial conditions and estimate solutions by creating a state file that is read by the appropriate analysis You can create a state file in two ways m You can instruct the Spectre simulator to create a state file in a previous an
10. process factors for example nonideal etching into account inline subckt RPLR PR A B parameters Rnom WB MULT 1 dR 0 t LB Rnom WB RSHSPnom AB LB WB SPDW January 2004 105 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features RPLR_PR A B RPLR_B R RSHSP LB WB SPDW 1 XRSPafac sqrt AB XRSPbfac dR 2 XRSP 1 sqrt MULT ends RPLR_PR The following file Plain h provides the designer with a plain device interface without geometrical or process modeling File Plain h simulator lang spectre plain TNSA no geometrical or process modeling inline subckt TNSA C B E S parameters MULT 1 IS 1e 15 BF 100 TNSA CB E S TNSA B IS IS BF BF MULT MULT call TNSA B ends TNSA plain RPLR no geometrical or process modeling inline subckt RPLR A B parameters R 1 MULT 1 RPLR A B RPLR B R R MULT MULT ends RPLR The following file Process h provides the designer with the geometrical device interface File Process h simulator lang spectre call to the geometrical TNSA model inline subckt TNSA C B E S parameters WE 1u LE 1u MULT 1 dIS 0 dBF 0 TNSA CB E S TNSA PR WE WE LE LE MULT MULT dIS dIS dBF dBF call TNSA PR ends TNSA call to the geometrical RPLR model inline subckt RPLR A B parameters Rnom 1 WB 10u MULT 1 dR 0 RPLR A B RPLR PR R
11. Configuration File The Spectre circuit simulator can be configured to load a specific set of shared objects based on the content of a set of configuration files The default CMI compiled model interface configuration file is shown below The default search path is SCDS_ROOT tools spectre lib cmi M This file is automatically generated Any changes made to it will not be saved load libnortel so load libphilips so load libsiemens so load libstmodels so The CMI file allows legal UNIX file paths and Spectre predefined percent codes For more information on predefined percent codes see Description of Spectre Predefined Percent Codes on page 270 Configuration File Format The following commands can be used in the configuration file Command Action setpath Specifies the search path prepend Adds a path before the current search path append Adds a path after the current search path January 2004 312 Product Version 5 0 Spectre Circuit Simulator User Guide Dynamic Loading Command Action load Adds a shared object to the list of shared objects to load unload Removes a shared object from the list of shared objects to load The following examples show the syntax for these commands To specify a search path setpath path path2 path N Example 1 setpath SHOME cds 4 4 6 tools CDS_SYSNAME spectre lib cmi M Example 2 setpath SHOME myLib cmi M SHOME cds 4 4 6
12. Error conditions terminate a Spectre run If you receive any of the messages described in this section you must fix the problem and rerun the simulation Invalid Parameter Values That Terminate the Program If you enter a parameter that causes the Spectre simulator to stop or puts a model in an invalid region such as giving z0 0 to a transmission line the Spectre simulator sends you a message like this one and exits Error from spectre during hierarchy flattening tll Value of z0 should be nonzero Spectre terminated prematurely due to fatal error To run the simulation you must change the parameter to an acceptable value January 2004 275 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Singular Matrices If you receive an error message that says a matrix is singular your netlist contains either a floating node which is causng the problem or a loop of zero resistance branches for example a loop of voltage sources or inductors The following procedures might help you find the problem B Check the options statement in your netlist to ensure that topcheck yes in at least one statement The topology checker normally helps you identify singular matrix problems but it cannot do so if it is disabled m If the error message appears only for particular components or circuit parameters or only for particular voltages or currents try one of the following procedures Q
13. Avoid using very small floating resistors particularly small parasitic resistors in semiconductors Use voltage sources or iprobes to measure currents instead Small floating resistors connected to high impedance nodes can cause convergence difficulties rbm in the bipolar model is especially troublesome If the minr model parameter is set make certain it is set to 1 mOhm or larger Use realistic device models Make sure that all component parameters are reasonable particularly nonlinear device model parameters Increase the value of gmin with the opt ions statement Loosen tolerances particularly absolute tolerances such as iabstol on the options statement January 2004 296 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting B Simplify the nonlinear component models Try to avoid regions in the model that might cause convergence problems m When you have a solution write it to a nodeset file using the write parameter When you run the simulation again read the solution back in using the readns parameter in the dc statement W Ifthisis not the first analysis the solution from the previous analysis might be an inadequate solution estimate because it differs too much from the solution for the current analysis If this is so set restart yes M f you have an estimate of the solution use nodeset statements or a nodeset file to set as many nodes as possible W f using no
14. The specified model All instances of the specified primitive type All models of the specified primitive type Device X1 over all instances of the specified subcircuit Same as row 1 All instances of the specified model over all instances of the specified subcircuit Same as row 2 The specified model over all instances of the specified subcircuit Same as row 3 All instances of the specified primitive over all instances of the specified subcircuit Same as row 4 All models of the specified primitive type over all instances of the specified subcircuit Same as row 5 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Assert parameters Description Applies to 11 sub subcircuit master paramnameisa All instances of the param paramname subcircuit parameter subcircuit 12 expr expr Valid conditional Expression specific expression or instances node voltages combination of operating etc points 13 expr mdl expr The expression is Expression specific min value evaluated and compared instances node voltages max value against the min and max etc values If you define an assert statement within a subcircuit block without the sub parameter the check is applied to that block only If you use the sub parameter the specified subcircuit master must be defined within the block All assert statement violations are written to the Spectre log file st aout irrespective of the m
15. This chapter covers the following topics B Encrypting a Netlist on page 248 B Encrypted Information During Simulation on page 254 January 2004 247 Product Version 5 0 Spectre Circuit Simulator User Guide Encryption Encrypting a Netlist To encrypt a netlist 1 Open the netlist you want to encrypt in a text editor Note Make sure your netlist is clean before encrypting it The Spectre circuit simulator does not support encryption of netlists containing analysis statements 2 Type protect above the data you want to protect 3 Type unprotect after the last line of the data you want to protect You must use the protect and unprotect keywords in pairs 4 Save the netlist 5 In aterminal window type spectre encrypt i input file o output file all where input file The path and name of the netlist to be encrypted If you do not specify the input file the netlist from standard input is encrypted output file The path and name of a file to hold the encrypted netlist The extension that you use for output file must be the same extension used on input file If you do not specify the output file the encrypted netlist is displayed as standard output in the terminal window all Encrypts the entire netlist ignoring of the protect and unprotect keywords The Spectre circuit simulator uses the IEJIBSAFE library to encrypt your netlist The protect and unprotect keywords are replaced with
16. scale or scalem Units Scaling action scale meters m Multiplied by scale scalem meters m Multiplied by scalem scale meters m Multiplied by scale With n a real number scalem meters m Multiplied by scalem With n a real number scale 1 meters 1 m Divided by scale scalem 1 meters 1 m Divided by scalem January 2004 119 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features scale or scalem Units Scaling action scale 1 meters 1 m Divided by scale With n a real number scalem 1 meters 1 m Divided by scale With n a real number String Parameters You can use quoted character strings as parameter values String values you might use as Spectre parameter values include filenames and labels When you use a string asa parameter enclose the string in quotation marks In the following example the value for the parameter named file is the character string Spara data model sp_data nport file Spara data N Ports When you model N ports you must first create a file listing the S Y or Z parameters Then you complete the modeling by using this file as input for an nport statement You can create the S Y or Z parameter file listing in two different ways m You can run an sp analysis and create a listing of S parameter estimates automatically m If you already know the S parameter values you can create an S parameter li
17. 71 2358 0 69817 61 6117 0 16581 71 2358 0 02804 38 6500 CITIfile Format CITIfile stands for Common Instrumentation Transfer and Interchange file format A typical CITIfile package consists of a m header containing keywords and setup information W data section containing one or more data arrays A data array is numeric data arranged with one data element per line A data array starts after the BEGIN keyword and the END keyword follows the last data element in an array Example The following example shows the basic structure of a CITIfile package CITIFILE A 01 00 NAME Momentum SP January 2004 127 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features CONSTANT NBR_OF_PORTS 2 CONSTANT NORMALIZATION 1 VAR freq MAG 12 DATA S 1 1 RI DATA S 1 2 RI VAR LIST BEGIN 1000000000 2000000000 VAR LIST END BEGIN 0 017216494 0 0 040005801 0 116494405 END BEGIN 0 9827835 0 0 944136351 0 176952631 END In the above example the vaR_LIST_BEGIN Section contains the frequency data points Each data array block marked by BEGIN and END keywords corresponds to an S parameter and contains the value of that parameter for each frequency point The first block corresponds to S 1 1 the second block corresponds to S 1 2 and so on You can use the SEG LIST keyword to specify a frequency range For example SEG LIST
18. Changing Parameter Values for Circuits When you change a circuit parameter you use the same syntax as when you change a device or model parameter except that you do not enter a dev or a mod parameter This example changes the ambient temperature to 0 C change2 alter param temp value 0 The following table describes the circuit parameters you can change with the alter statement Parameter Description temp Ambient temperature tnom Default measurement temperature for component parameters scalem Component model scaling factor scale Component instance scaling factor Note If you change temp or t nom using an alter statement all expressions with temp or tnom are reevaluated The assert Statement You can set custom characterization checks to determine the safe operating area of your circuit using the assert statement You can add these checks to a netlist or model card for transient DC and DC sweep analyses The Spectre circuit simulator notifies you when parameters of instances models or expressions fall outside the bounds specified in your check You can set checks for any of the following M Top level netlist parameter m Model parameter m Instance parameter B Expressions The syntax for defining a check is January 2004 189 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Name assert sub subcircuit_master dev instance mod model primitive primitive p
19. SetCkptInterval options ckptclock 210 Creating Recovery Files from the Command Line You can create a checkpoint file when a transient analysis is running with a UNIX interrupt signal from the command line gt Tocreate a checkpoint file from the command line send a USR2 signal with a UNIX kill command kill USR2 PID You find the necessary process identification number by running the UNIX ps utility The Spectre simulator also attempts to write a checkpoint file after QUIT TERM INT or HUP interrupts After other interrupt signals the Spectre simulator might be unable to write a checkpoint file Setting Recovery File Specifications for a Single Analysis When you specify a transient analysis you can also create periodic checkpoint files for that analysis January 2004 243 Product Version 5 0 Spectre Circuit Simulator User Guide Running a Simulation gt Tocreate periodic checkpoint files for a transient analysis set the ckptperiod parameter in the transient analysis statement The following example creates a checkpoint every 20 seconds during the transient analysis SineResponse SineResponse tran stop 150u ckptperiod 20 Restarting a Transient Analysis gt Torestartatransient analysis from the last checkpoint file start the simulation again with the spect re command Make sure to enter the recover command line argument Controlling Command Line Defaults There are many run options you can specify with
20. Spectre scale factors see Scaling Numerical Literals on page 83 for more information The Spectre Netlist Language uses the ANSI standard SI scale factors January 2004 49 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility m Options that are analysis specific are found on the global options card in SPICE In Spectre options pertaining to an analysis are listed on the analysis card B Spectre supports the idea of named analyses which allows you to include multiple analyses of the same type in a single netlist The SPICE Reader takes advantage of Spectre s ability to have more than one analysis of each type mapping each analysis statement to the equivalent Spectre analysis and providing each a unique name If multiple analysis of the same type are listed within the SPICE deck each will be simulated instead of the last one wins mode of SPICE m In both Spectre and Spice the first line is always the title card and ignored by the simulator B Acard other than the title or a comment can be continued onto the next card by putting the continuation character in the first column of the next card Spectre also supports continuations at the end of the line in its native mode with the backslash character B In many versions of Spice there are punctuation characters such as parentheses and commas that are treated as white space Spectre will treat all characters as relevant input The S
21. TooThin paramtest warnif w lt lum message Channel width for nmos must be greater than lu January 2004 116 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features TooNarrow paramtest warnif ls lt lum warnif ld lt lum message Stripe width for nmos must be greater than lu Model selection include models scs include all model definitions include select model scs section typical include code to auto choose models ends nmos Set the temperatur nmosSetTempTo27C alter param temp value 27 The following file models scs contains the models which depend on circuit temperature temp Each model parameter can take on one of two values depending on the value of parameter t emp Fast models Ai model fast_1x1 mos3 type n vto temp gt 27_C 0 8 0 77 Pf wu ete model fast 1x3 mos3 type n vto temp gt 27 C 0 9 0 78 ff etc model fast 3x1 mos3 type n vto temp gt 27 C 0 95 0 79 etc model fast 3x3 mos3 type n vto temp gt 27 C 0 98 0 81 etc LI Typical models model typ 1x1 mos3 type n vto temp 27 C 0 90 0 75 MI teo model typ 1x3 mos3 type n vto temp gt 27 C 0 91 0 73 ff i e model typ 3x1 mos3 type n vto temp gt 27 C 0 97 0 77 Tf uet model typ 3x3 mos3 type n vto t
22. Voltage controlled voltage sources transform single ended signals to differential and common mode signals and vice versa This approach does not generate or dissipate any power The power dissipation reported by the Spectre simulator is that of the differential amplifier Fully Differential Operational Amplifier Test Circuit define PROCESS_CORNER TYPICAL simulator lang spectre global gnd vdd vss parameters VDD 5 0_V GAIN 0 5 include cmos mod section typical include opamp ckt January 2004 112 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features power supplies Vdd vdd gnd vsource dc VDD Vss vss gnd vsource dc VDD compute differential input Vcm cmin gnd vsource type dc dc 0 val0 0 vall 2 width 1u delay 10ns Vdif in gnd vsource type dc dc 0 val0 0 vall 2 width lu delay 10ns Ridif in gnd resistor Eicmp pin cmin in gnd VCVS gain GAIN Eicmn nin cmin in gnd VCVS gain GAIN feedback amplifier Al pout nout pvg nvg opamp Cf1 pout tl capacitor c 8p C E2 e t2 capacitor c 8p Vtl t nvg vsource mag 0 Vt2 t pvg vsource mag 0 ELL oe gnd capacitor c 8p C12 out gnd capacitor c 8p CT pin pvg capacitor c 2p CIZ nin nvg capacitor c 2p compute differential output Edif out gnd pout nout vcvs gain 1 Rodif out gnd resistor Ecmp cmout mid pout gnd vcvs gain GAIN Ecmn mid
23. Y or Z parameters Each line of the the two port noise data has the following five entries xd x2 x3 x4 x5 where x1 x2 x3 x5 x4 Frequency in units Minimum noise figure in DB Source reflection coefficient to realize minimum noise figure in units specified in the option line MA DB or R Normalized effective noise resistance The frequencies for noise parameters and network parameters need not match The only requirement is that the lowest noise parameter frequency be less than or equal to the highest January 2004 126 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features network parameter frequency This allows the simulator to determine where the network parameters end and noise parameters begin The source reflection coefficient has the same format as specified for the network parameters Example The following is two port noise data in Touchstone format with three frequency points POWER DIVIDER 3 PORT GHZ S MA R 50 0 5 00000 0 24254 136 711 0 68599 43 3139 0 6859 43 3139 0 68599 43 3139 0 08081 66 1846 0 28009 59 1165 0 68599 43 3139 0 28009 59 1165 0 08081 66 1846 6 00000 0 20347 127 652 0 69232 52 3816 0 69232 52 3816 0 69232 52 3816 0 05057 52 0604 0 22159 65 1817 0 69232 52 3816 0 22159 65 1817 0 69817 61 6117 7 00000 0 15848 118 436 0 69817 61 6117 0 69817 61 6117 0 69817 61 6117 0 02804 38 6500 0 16581
24. example of analysis statement 32 formatting 66 67 fourier 153 handling of prerequisite 68 Monte Carlo performing 164 no default analysis 68 order performed 68 parameter sweep examples 163 parameter value defaults 135 rules fornaming 68 sens 151 setting probes 135 specifying 32 66 134 statistical 164 subcircuits composed of calling 139 formatting example 138 analysis order netlist example of effective use 135 analysis statement 66 examples 32 67 formatting 66 annotate parameter in Monte Carlo analysis 171 in Spectre analyses 242 append path 313 appendsd parameter Monte Carlo Product Version 5 0 Spectre Circuit Simulator User Guide 170 189 analysis assert statement examples 193 syntax 190 associated reference direction 58 automated testing 19 automatic model selection examples in netlist 115 automatic recovery in transient analyses customizing 242 AWD Analog Waveform Display using 34 B backslash in Spectre syntax 59 backward Euler integration method behavioral expressions 90 benchmark suite MCNC 19 BERT model for hot electron degradation 108 144 simulation 179 stress parameters 179 binning 107 auto model selection 108 by conditional instantiation conditional instances 109 rules 111 BJT operating regions determining 292 blowup parameter 76 braces in syntax 15 brackets in syntax 14 breakdown region warnings example of messages 279 requesting for transistors 290 BSIM 3v3
25. extremes option Specifying the Output Destination You can choose among several output destination options for the parameters you list with the info statement With the info statement where parameter you can January 2004 233 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options m Display the parameters on a screen B Send the parameters to a log file to the raw file or to a file you create Examples of the info Statement You format the info statement as follows StatementName info parameter value The following example tells the Spectre simulator to send the maximum and minimum input parameters for all models to a log file Inparams info what models where logfile extremes only For a complete description of the parameters available with the info statement consult the lists of analysis and control statement parameters in the Spectre online help spectre h Preparing Output for Viewing In this section you will learn how to format output data files so you can view them with a postprocessor Output Formats Supported by the Spectre Simulator You can choose from among seven format settings for output data files or directories The default setting is psfbin Option Format wsfbin Cadence waveform storage format WSF binary wsfascii Cadence waveform storage format WSF ASCII psfbin Cadence parameter storage format PSF binary psfascii Cadence parameter storage format P
26. following is an example of binding a captab analysis to a transient analysis tranl tran stop 1u infotimes 0 lu 0 5u infoname capInfo capInfo info what captab where fil file capNodes detail nodetonod Output Table The output for the captab analysis is printed in the following format m The first column displays the names of the two nodes From node To Node m The second column displays the fixed linear capacitance between the two nodes m The third column is the variable non linear capacitance between the two nodes m The last column displays the total capacitance between the nodes Table 7 1 displays the output for the circuit below when detail nodetonode C3 1p 0 5p demos cens C5 2p n2 e 1p EF SP e Cp January 2004 206 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements In this circuit the total capacitance at node 2 n2 n2 in the table is C4 Cot C3 5p The total capacitance between node 2 and node 1 n2 n1 is Co Linear C3 Non Linear 3p Table 7 1 Node Capacitance Table Sorted by Value n2 n2 Fixed 2p Variable 3p Sum 5p n2 n1 Fixed 2p Variable 1p Sum 3p ni nl Fixed 3 5p Variable 1p Sum 4 5p n1 0 Fixed 1p Variable 0 Sum l1p ni n2 Fixed 2p Variable 1p Sum 3p n1 n3 Fixed 0 5p Variable 0 Sum 0 5p n3 n3 Fixed 1 5p Variable 0 Sum 1 5p n3 0 Fixed 1p Variable 0 Sum 1p n3 nl Fixed 0 5p Variable 0 Sum 0 5p
27. nl n12 capacitor c bw 0 9705 6 2832 fc fc r0 L2 n12 n2 inductor 1 r0 0 9705 6 2832 bw C3 n2 0 capacitor c 2 2034 6 2832 bw r0 L3 n2 0 inductor l r0 bw 2 2034 6 2832 fc fc ends filter instantiate 50 Ohm filter with 10 4MHz center frequency and 1MHz bandwidth Parameter F1 in out filter bw 1MHz fc 10 4MHz r0 50 Values instantiate 1 Ohm filter with 10Hz ca changed from center frequency and 1Hz bandwidth defaults F2 nl n2 filter fc 10 for these subcircuit calls You can use such parameterized subcircuits when the Spectre simulator is reading either Spectre or SPICE syntax Unlike subcircuit calls in SPICE the names of Spectre subcircuit calls do not have to start with an x This is useful if you want to replace individual components in an existing netlist with subcircuits for more detailed modeling Checking for Invalid Parameter Values When you define subcircuits such as the one in Modifying Subcircuit Parameter Values on page 98 you might want to put error checking on the subcircuit parameter values Such error checking prevents you from entering invalid parameter values for a given subcircuit call The Spectre paramtest component lets you test parameter values and generate necessary error warning and informational messages For example in the example of the bandpass filter in Modifying Subcircuit Parameter Values on page 98 the center
28. results of the export expressions You can then see correlations between process parameter variations and circuit performance variations This data merging takes place whenever the scalarfile and processscalarfile are written in the same directory paramfile This file contains the titles sweep variable values and the full expression for each of the columns in scalarfile The default name for this file is name mcparam where name is the name of the Monte Carlo analysis instance The file is created in the psf directory by default unless you specify some path information in the filename saveprocessparams This specifies yes or no whether to save scalar data for statistically varying process parameters that are subject to process variation January 2004 167 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Parameter Description processscalarfile If saveprocessparams is set to yes the process batch to batch values of all statistically varying parameters are saved to this scalar data file You can use saveprocessvec to filter out a subset of parameters in which case the Spectre simulator saves only the parameters specified in saveprocessvec 0 processscalarfile processscalarfile is equivalent to scalarfile except that the data in scalarfile contains the values of the scalar export statements whereas the data in processscalarfile contains the corresponding process parameter values The default name for thi
29. 0 Wwn 2613948 L1 1 300902E 10 Lw 0 Lwl 0 Ll1n 316394 Lwn 0 kt1 3 kt2 051 At 22400 Ute 1 48 Ual1 3 31E 10 Ub1 2 61E 19 Ucl 3 42e 10 Kt11 0 Prt 764 3 Spectre BSIM 3v3 Model Berkeley Spice Compatibility Lmin 35 Lmax 20 Wmin 6 Wmax 20 simulator lang spectre model nch bsim3v3 tversion 3 1 type n tnom 27 0 tnch 2 498E 17 tox 9E 09 xj 1 00000E 07 tlint 9 36e 8 wint 1 47e 7 tvth0 6322 k1 756 k2 3 83e 2 k3 2 612 tdvt0 2 812 dvt1 0 462 dvt2 9 17e 2 tn1x 3 52291E 08 w0 1 163e 6 k3b 2 233 tvsat 86301 58 ua 6 47e 9 ub 4 23e 18 uc 4 706281e 11 rdsw 650 u0 388 3203 wr 1 a0 3496967 ags 1 b0 0 546 bl 1 dwg 6 0e 09 dwb 2 3 56e 09 prwb 213 tketa 3 605872e 02 al 2 778747e 02 a2 9 tvoff 6 735529e 02 nfactor 1 139926 cit 1 622527e 04 tcdsc 2 147181e 05 cdscb 0 tdvtO0w 0 dvtlw 0 dvt2w 0 cdscd 0 prwg 0 teta0 1 0281729e 02 etab 5 042203e 03 dsub 31871233 tpcim 1 114846 pdiblcl 2 45357e 03 pdiblc2 6 406289e 03 tdrout 31871233 pscbel 5000000 psche2 5e 09 pdiblcb 234 pvag 0 delta 0 01 twl 0 ww 1 420242e 09 wwl 0 twln 0 wwn 2613948 11 1 300902e 10 t lw 0 lwl 0 Ilin 316394 lwn 0 kt1 3 kt2 051 tat 22400 tute 1 48 tual 3 31e 10 ub1 2 61e 19 ucl 3 42e 10 kt11 0 prt 764 3 Ring Oscillator Spectre Deck for Inverter Ring with No Fanouts inverter_ring sp This example uses Spectre
30. 10 0 The description in the previous table has the following exceptions B The errpreset parameter sets the value of reltol as described in the table except that the value of reltol cannot be larger than 0 01 m Except for reltol and maxstep errpreset does not change the value of any parameters you have specified B With naxstep the specified value in the preceding table is an upper bound You can always specify a smaller maxstep value If you need to check the errpreset settings for a simulation you can find these values in the log file January 2004 142 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Uses for errpreset You adjust errpreset to the speed and accuracy requirements of a particular simulation For example you might set errpreset to liberal for your first simulation to see if the circuit works After debugging the circuit you might switch to moderate to get more accurate results If the application requires high accuracy or if you want to verify that the moderate solution is reasonable you set errpreset to conservative You might also have different errpreset settings for different types of circuits For logic gate circuits the 1iberal setting is probably sufficient A moderate setting might be better for analog circuits Circuits that are sensitive to errors or circuits that require exceptional accuracy might require a conservative setting Controlling the Accuracy You can contr
31. 2004 This specifies an array of statistically varying process parameters which are subject to process variation to save as scalar data in processscalarfile For example saveprocessvec RSHSP TOX This acts as a filter so that you do not save all process parameters to the file If you do not want to filter the list of process parameters do not specify this parameter This specifies the run that Monte Carlo begins with The default is 1 If irstrunis specified as a number n where n is greater than one the previous n 1 iterations are skipped The Monte Carlo analysis behaves as if the first n 1 iterations were run without performing the child analyses for those iterations The subsequent stream of random numbers generated for the remaining iterations is the same as if the first n 1 iterations were run By specifying the first iteration number you can reproduce a particular run or sequence of runs from a previous experiment for example to examine an earlier case in more detail Note To reproduce a run or sequence of runs you need to specify the same value for the seed parameter This parameter specifies the type of statistical variation to apply B process batch to batch variations only B mismatch per instance variations only B all both process and mismatch variations applied The default is process This assumes that you have specified the appropriate statistical distributions in the statistics block You cannot r
32. 26 and netlist Sample Netlist on page 28 and compare Spectre netlist syntax with that of SPICE like simulators you have used If you have prepared netlists for SPICE like simulators before you can skim Elements of a Spectre Netlist on page 29 With this method you can learn a fair amount about the Spectre simulator in a short time Approach this chapter as an overview You will probably have unanswered questions about some topics when you finish the chapter Each topic is covered in greater depth in subsequent chapters Do not worry about learning all the details now To give you a complete overview of a Spectre simulation the example in this chapter includes the display of simulation results with WaveScan a waveform display tool that is included with the Spectre simulator If you use another display tool the procedures you follow to display results are different This user guide does not teach you how to display waveforms with different tools If you need more information about how to display Spectre results consult the documentation for your display tool The example used in this chapter is a small circuit an oscillator you run a transient analysis on the oscillator and then view the results The following sections contain the schematic and netlist for the oscillator If you have used SPICE like simulators before looking at the schematic and netlist can help you compare Spectre syntax with those of other simulators If
33. 273 163 273 273 Product Version 5 0 Spectre Circuit Simulator User Guide of input filenames 272 r root 273 t tail 273 colons in Spectre syntax 59 comments formatting for 59 compatible parameter 210 compiled model interface CMI description 20 components naming 30 60 rules fornames 60 specifying initial conditions for 198 259 Composer to Spectre direct simulation environment 20 conditional if statements example of use in netlist formatting example 109 conditional instantiation 110 specifying 109 warning 111 configuration file default 312 example 315 format 312 precedence 314 connections inherited 78 constants built in table of 91 continuation characters 50 52 continuation methods 267 control statements 68 69 definition 31 formatting 69 paramset 210 statistics 221 use of in instance statement controls specifying 68 conventions typographic and syntax convergence problems 295 backward Euler integration method to correct 297 correcting with current probes 296 correcting with DC sweeps 297 dividing the circuit into parts to correct 297 floating resistors causing 296 gmin parameter increasing 296 loosening iabstol parameter to correct 296 loosening truncation error criteria to correct 297 Iteratio parameter 11 31 14 297 January 2004 319 maxiters parameter 296 nodesets to correct 297 nonlinear component models simplifying 297 numeric pivoting in
34. 310 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits ac dec 10 1 10MEG print ac vdb 3 vp 3 end LH Modified Open Loop Opamp openloop1 sp Allen amp Holmberg p 438 Modified Open Loop OpAmp Configuration vinp 10 dc 0 ac 1 0 vdd 4 0 dc 5 0 vss 0 5 dc 5 0 vinm 2 0 dc 0 cl3 0 20p x11234 5 opamp Bring in opamp subcircuit include opampl cir Bring in models here model nch bsim3v3 model pch bsim3v3 type p Op simulator lang spectre tf 3 0 xf save lvlpub nestlvl 1 start 1 stop 1K dec 20 simulator lang spice dc vinp 0 10 0 10 10u print dc v 3 ac dec 10 1 10MEG print ac vdb 3 vp 3 end Gl Example Model Directory q35d4h5 modsp example model directory simulator lang spectre library mosmodels section tt model n bsim3v3 tox 1 194e 08 model p bsim3v3 type p tox 7 4e 09 endsection section ss model n bsim3v3 tox 1 242e 08 model p bsim3v3 type p tox 7 724e 09 endsection section ff model n bsim3v3 tox 1 1544e 08 model p bsim3v3 type p tox 7 148e 09 endsection endlibrary January 2004 311 Product Version 5 0 Spectre Circuit Simulator User Guide Dynamic Loading The Spectre circuit simulator supports dynamic loading of device models This feature allows you to dynamically load device primitives stored in shared objects at run time This is useful for developing and distributing models
35. 5 0 Spectre Circuit Simulator User Guide Analyses vary xxx dist lnorm std 12 vary uuu dist unif N 10 percent yes mismatch mismatch generate a random number per instance vary rshsp dist gauss std 2 vary xisn dist gauss std 0 5 vary xisp dist gauss std 0 5 some process parameters are correlated correlate param rshsp rshpi cc 0 6 specify a global distribution truncation factor truncate tr 6 0 6 sigma a separate statistics block to specify correlated i e matched components where m1 and m2 are subckt instances statistics correlate dev ml m2 param xisn xisp cc 0 8 Note You can specify the same parameter for example rshsp for both process and mismatch variations In the process block the process parameter rshsp is varied with a Gaussian distribution where the standard deviation is 12 percent of the nominal value percent yes When percent is set to yes the value for the standard deviation std is a percentage of the nominal value When percent is set to no the specified standard deviation is an absolute number This means that parameter rshsp should be varied with a normal distribution where the standard deviation is 12 percent of the nominal value of rshsp The nominal or mean value for such a distribution is the current value of the parameter just before the Monte Carlo analysis starts If the nominal value of the parameter rshsp was 200 the preceding e
36. 75 library statements using 75 limits selecting for operating region warnings 291 lin parameter 163 line extension formatting 59 listing parameter values 202 2 literal characters 14 Inorm parameter 175 LO definition of 22 2 load shared object 314 local truncation error 143 log 294 log 294 log 294 log files specifying options 294 log normal distribution 175 log parameter 163 login file and environment defaults 245 loop gain example of measuring in netlist 112 Iteratio parameter 142 143 convergence problems and 297 lvl as save parameter option 217 230 IvIpub as save parameter option 217 230 M m factor 65 M predefined percend code 270 magnetic flux in Webers 77 magnetomotive force in Amperes 76 main circuit signals saving See save statement 211 224 Product Version 5 0 Spectre Circuit Simulator User Guide masternames 31 definition 30 model statements 31 maxdelta parameter 76 maximum and minimum parameter values listing 202 233 maxiters parameter 296 maxstep parameter 142 145 setting to correct accuracy problems 299 MCNC benchmark suite 19 measuring differential signals example in netlist 112 loop gain example in netlist 112 135 output resistance netlist example discussed 136 power supply rejection netlist example discussed 136 melting current warnings 279 message control specifying the destination of
37. 9 9824 Failed x11 m1 0 086872 9 9824 9 9789 9 961 Passed x5 m1 0 086451 9 9389 9 9354 9 9176 Passed x2 m2 0 070474 8 2693 8 265 8 243 Passed x3 m2 0 060787 7 2389 7 2351 7 2157 Passed x6 m2 0 060025 7 1572 7 1534 7 1342 Passed x1 m2 0 059703 7 1226 7 1189 7 0997 Passed x10 m2 0 059668 7 1189 7 1151 7 096 Passed x4 m2 0 059025 7 0498 7 0461 7 0271 Passed x8 m2 0 058728 7 0178 7 0141 6 9952 Passed x4 m1 0 055291 6 6471 6 6447 6 6324 Passed x1 m1 0 049069 5 9699 5 9677 5 9566 Passed x10 m1 0 044038 5 4161 5 4141 5 4039 Passed x6 m1 0 044 5 4119 5 41 5 3998 Passed x8 m1 0 04301 5 3021 5 3002 5 2902 Passed x9 m2 0 030815 3 9276 3 9255 3 9145 Passed x5 m2 0 030724 3 9171 3 915 3 9041 Passed x7 m2 0 030223 3 8597 3 8576 3 8468 Passed x11 m2 0 030096 3 845 3 8429 3 8322 Passed January 2004 185 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements The Spectre circuit simulator lets you place a sequence of control statements in the netlist You can use the same control statement more than once Different Spectre control statements are discussed throughout this manual The following are control statements The alter and altergroup Statements on page 187 The assert Statement on page 189 The check Statement on page 194 The checklimit Statement on page 195 The ic and nodeset Statements on page 197 The info Statement on page 202 The options Statement on page 208 The paramset Statement on page 210
38. CI Ck Ck Sk Sk Sk x x A KG kx ko ko Ax kx Narration of transient analysis progress Te D dues V ue Due ae Dave dE DE bee sre ee RR oett ed e pte es O Number of accepted tran steps 23508 Initial condition solution time 0 s Intrinsic tran analysis time 7 07 s Total time required for tran analysis OscResp was 7 08 s Aggregate audit 1 22 02 PM Wed Aug 20 2003 Time used CPU 7 29 s elapsed 8 s util 91 1 Virtual memory used 1 3 Mbytes spectre completes with O0 errors 0 warnings and 0 notices January 2004 33 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre Viewing Your Output The waveform display tool for this simulation example is WaveScan a display tool you receive when you purchase the Spectre simulator In this section you will learn the following m How to start WaveScan B How to plot signals B Howto change the color of a trace Starting WaveScan gt Type the following at the command line wavescan amp Note To start WaveScan for the simulation example type the following at the command line from the directory where the Spectre simulator was run wavescan dataDir osc raw The Results Browser window appears with the osc raw data directory displayed in the right panel Ic i Results Browser e File Settings Tools Help c cA O IR EN R
39. Ibb to the numerical value of Ib m Two analysis statements SwoVccDC and SwpVccAC which run a DC analysis followed by an AC analysis January 2004 138 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Calling Analysis Subcircuits Each subcircuit call for sweepVcc in the netlist causes all the analyses in the sweepVcc to be performed Each of the following statements is a subcircuit call to subcircuit sweepVcc IbbluA sweepVcc stop 2 Ib 1lu Ibb3uA sweepVcc stop 2 Ib 3u IbblO0uA sweepVcc stop 2 Ib 10u Ibb30uA sweepVcc stop 2 Ib 30u Ibbl00uA sweepVcc stop 2 Ib 100u Note the following important syntax features m Each subcircuit call has a unique name W Each subcircuit call overrides the default values for the stop and Ib parameters m The start steps and omega parameters are not defined in the subcircuit calls They take the default values assigned in the subcircuit DC Analysis The DC analysis finds the DC operating point or DC transfer curves of the circuit To generate transfer curves specify a parameter and a sweep range The swept parameter can be circuit temperature a device instance parameter a device model parameter a netlist parameter or a subcircuit parameter for a particular subcircuit instance You can sweep the circuit temperature by giving the parameter name as param t emp with no dev mod Or sub parameter You can sweep a top level netlist parameter by giving the param
40. Managing Files how to construct the filename You can use percent codes in environment variables in spectre command parameters or in your netlist wherever you need to specify filenames for simulation results For example C is the predefined percent code for the name of the input circuit file If your circuit file is named opamp1 and you place the following raw setting for your UNIX environment variable setenv SPECTRE DEFAULTS raw C raw the Spectre simulator sends simulation results to a file named opamp1 raw Description of Spectre Predefined Percent Codes These are the percent code options that can help you organize your simulation data oe A A is replaced by the name of the current analysis that is running If it is specified in a device statement it is expanded to a blank string because there is no current analysis C is replaced by the input circuit filename as it is used in the command line If the circuit filename is opamp1 the specification C raw generates a file named opampl raw oe Q When the Spectre simulator does not know the name of the input file as when the circuit is read from the standard input from a pipe or from a redirected file the Spectre simulator substitutes the name stdin for C D is replaced by the date when the program started For example the specification D opamp1 might generate a file named 94 09 19 o0pampl1 oe tJ oe The date is in year
41. Set gmin 1e 12 the default value Q Ifyou are working with simplified semiconductor models try using more complex models A CMOS complementary metal oxide semiconductor inverter whose model parameters have infinite output impedance in saturation demonstrates the usefulness of these techniques When either the N or P type device is in the ohmic region the solution is unique However when both devices are saturated there is a range of output voltages that all satisfy Kirchhoff s Current Law In this situation the Newton Raphson method forms a linearized circuit that is singular for that iteration m Check ideal transformers N ports or transmission lines for floating nodes or loops of zero resistance branches and modify the circuit to eliminate them For example consider this center tapped transformer m1 m2 b1 b2 subckt ct xfmr tl bl t2 m2 b2 Tt t1 ml t2 m2 transformer n1 2 Tb ml bl m2 b2 transformer n1 2 end ct xfmr January 2004 276 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting If you use this transformer and leave the center tap terminal m2 floating the Spectre simulator notifies you of a singular matrix Because both m1 and m2 are floating the DC solution is not unique If you choose a different topology for the transformer like the one in the following example you can avoid the problem t t2 m2 b1 b2 subckt ct xfmr tl bl
42. Statement 529 4 ce eases heel es ween back ee eas 210 INE SadveStatettebib suono sore aie wy and eat dor cnm eee ala P ba cr EQ 211 Saving Signals for Individual Nodes and Components 211 Saving Groups Or SIONGIS 3 2 i EUN SR EROEDERND SORS eh tates keh ELE 217 Thes t Statement Sac pe acea ma 0 sal sec P Jer a ri af de A Jee Porn ie dei b dad det 220 The SHES ICME saisir nanen aa Pop RO Go ota a Pra I d gd CAR D d t OD bebes rs 221 Th e statisties Statement 22 cece at EE Otter h dut qoo ER RE ca Keri eI ECCE CARES 221 8 Specifying Output Options 0000 0 0 aeiaai anran 222 Sigrials as OLIDUE 131 5 X stored Se ai ap toe vs De DE diu addita d 8 eS acie e cri ud 223 Saving Signals for Individual Nodes and Components 20000005 223 Saving Main Circuit Signals a fers 2 223 2335 1 dote tA NOUS E i EE d ee 224 saving Subcircuit Signals ote Rr Uh 8a SHAW or Id do Reap ome ete 225 January 2004 8 Product Version 5 0 Spectre Circuit Simulator User Guide Examples of the save Statement sx Pia weed de RV eee DDR 225 Saving Individual Currents with Current Probes 00 0c cece eee 226 SAINI ROWEN Suseaxuceeetne lieto bis De Ne et oe SWS he ARG Park Nok a he tie 228 Saving Groups of Signals us edie a wa wd ke Mie nee oleh RS RE Oe eles ple x st 229 Formatting the save and nestlvl Parameters 2 2 es 229
43. The save Statement on page 211 The set Statement on page 220 The shell Statement on page 221 The statistics Statement on page 221 January 2004 186 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements The alter and altergroup Statements You modify individual parameters for devices models circuit and subcircuit parameters during a simulation with the alter statement The modifications apply to all analyses that follow the alter statement in your netlist until you request another parameter modification You also use the alter statement to change the following options statement temperature parameters and scaling factors B temp tnom E scale E scalem You can use the altergroup statement to respecify device model and circuit parameter statements that you want to change for subsequent analyses You can also change subcircuits if you do not change the topology Changing Parameter Values for Components To change a parameter value for a component device or model you specify the device or model name the parameter name and the new parameter value in the alter statement You can modify only one parameter with each alter statement but you can put any number of alter statements in a netlist The following example demonstrates alter statement syntax SetMag alter dev Vt1 param mag value 1 B SetMag is the unique netlist name for this alter statement Like many Spectre statements each
44. User Guide Analyses the Spectre simulator reads the state information contained in this state file and speeds analysis by using this state information as an initial estimate of the solution Analysis Drift computes DC solutions as a function of temperature The Spectre simulator computes the solution at the initial temperature and saves this solution to a state file to use as an estimate in the next analysis and in subsequent simulations Analysis XferVsTemp computes the small signal characteristics of the amplifier versus temperature Analysis XferVsTemp starts up quickly because it begins with the initial temperature of the DC solution that was placed in a state file by the previous analysis Analysis OpenLoop computes the loop gain of an amplifier in closed loop configuration Analysis OpenLoop starts quickly because it begins with the initial temperature of the DC solution that was placed in a state file during analysis OpPoint Analysis XferVsF req computes several small signal quantities of interest such as closed loop gain the rejection ratio of the positive and negative power supply and output resistance The analysis again starts quickly because the operating point remains from the previous analysis Analysis StepResponse computes the step response that permits the measurement of the slew rate and settling times The alter statement please4 then changes the input stimulus from a pulse to a sine wave Finally the Spectre simul
45. Values 0 0 cece ees 98 MIE SHDCIECUMS 355559 1 3 sree Re Sitio E CST D eS Exo b Ene ard 99 Modeling Parasites oien vue en v auem cas AOT IE pd reu EX PIE qu PE 100 Parameterized Models osse y uto e E TER RENE ER a a lh ea AU 102 Inline Subcircuits Containing Only Inline model Statements 103 Process Modeling Using Inline Subcircuits ce eee 104 BINNING Sse by ind ese pes o ages awa asa ione BY nk cad So ee ae ra Rcg A E t rra 107 Auto Model Selection oru iex ew Sar Ole Maer x t e Belk al kw ate week e 108 Conditional Instances 6G oad Rote gue Rm 9o Bln RA oci Dod ra edent aci d Whose 109 Scaling Physical Dimensions of Components 0 000 118 N PORS gas beds dead oe Rea ah Ife de te la tay AR i Pobre NC RES TER Ae o A ESS 120 BEPOrEEXamiple 2 ex ue du an dece e UR QE RUE Se a eaten dn die eR Sea Rd 120 Creating an S Parameter File Automatically ssl 121 Creating an S Y or Z Parameter File Manually slllssess 121 Reading the S Y or Z ParameterFile lelslllslsss 122 To chstone F rmat raene a 1949 Jodeci Nw to tan dee va 3 0 09 ch oic D Seal ras oo 124 S Parameter File Format Translator leen 128 6 Andy SE eee ee oti Le RUD MEE UL ELE LEE 130 AVDSSOPANAIVSES sie ETE 131 Analysis P Srarmeleres see cc tac ated Se avo E aic e dye eles See a ane Bee ae ate Aaa d i ee 134 Probesir Aralyses sarene i
46. a reasonable length and ordinarily both the N and P channel models are in the same file If you added the model parameters and a pmos model this file could replace cmos mod in the previous example N CHANNEL MOS 1u NMOS PROCESS The following group of models represent N channel MOSFETs over the following ranges lu lt 1 lt oo lu lt w lt oo Or lt Ty lt 55 process corners FAST TYPICAL SLOW Warnings are issued if these limits are violated This model takes 4 parameters l w ls and ld The defaults for each of these parameters is lum Source Gate Drain simulator lang spectre Complain if global constants are out of rang TooCold paramtest warnif temp lt 0 message The nmos model is not accurate below 0 C l ooHot paramtest warnif temp gt 55 message The nmos model is not accurate above 55 C Define inline subcircuit that implements automatic model selection this uses user supplied parameters 1 and w which represent devic geometry and the built in parameter temp to perform model binning based on both geometry and temperature inline subckt nmos d g s b parameters l lum w lum ls lum ld 1um Complain if subcircuit parameters are out of rang TooShort paramtest warnif l lt lum message Channel length for nmos must be greater than lu
47. alter statement must have a unique name B The keyword alter is the primitive name for the alter statement B dev Vt1 identifies vc 1 as the netlist name for the component statement you want to modify You identify an instance statement with dev and a mode1 statement with mod When you use the alter statement to modify a circuit parameter you leave both dev and mod unspecified B param mag identifies mag as the parameter you are modifying If you omit this parameter the Spectre simulator uses the first parameter listed for each component in the Spectre online help as the default B value 1 identifies 1 as the new value for the mag parameter If you leave value unspecified it is set to the default for the parameter January 2004 187 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Changing Parameter Values for Models To change a parameter value for model files with the altergroup statement you list the device model and circuit parameter statements as you would in the main netlist Within an alter group each model is first defaulted and then the model parameters are updated You cannot nest alter groups You cannot change from a model to a model group and vice versa The following example demonstrates altergroup statement syntax agl altergroup parameters pl 1 model myres resistor rl le3 af pl model mybsim bsim3v3 lmax pl lmin 3 5e 7 The following example shows the full replacement
48. and Cadence range limits 284 ps utility UNIX 241 pseudotransient method 267 PSF parameter storage format 234 formatting output files 246 psfascii output format 234 psfbin output format 234 pss analysis brief description of 133 ptran as homotopy parameter option 267 punctuation characters in Spectre syntax 59 PWL definition 74 Pwr 77 270 m3 SIO a no 71 pwr 213 215 225 228 pwr parameter 215 228 pxf analysis brief description of 133 Q quantity statement 76 Product Version 5 0 Spectre Circuit Simulator User Guide abstol parameter 76 blowup parameter 76 example 77 huge parameter 76 maxdelta parameter 76 predefined quantities 76 R t colon modifier 273 range checking for subcircuit parameters 292 reading state files 201 263 recover spectre command option 244 recovering from transient analysis terminations automatic recovery customizing 242 243 restarting a transient analysis 244 setting recovery checkpoint file specifications for a single analysis 243 recursive inclusion 73 redirected files and percent codes 272 reducing simulation time with previous solutions 258 reference direction associated 58 reference to alibrary 75 relative error tolerance 143 relref parameter 142 143 allglobal setting 144 alllocal setting 144 pointlocal setting 144 sigglobal setting 144 reltol parameter 142 143 209 setting to correct accuracy problems 298 reserved words Spe
49. and Modeling Features in odd is 50 If however the subcircuit call sets zodd to 100 the value of zodd in odd is 100 subckt twist paramete odd pl tfla pl tflb n1 even el tf2a p2 tf2b n2 ends twisted ed pl nl p2 n2 rs zodd 50 zeven 50 veven 1 vodd 1 len 0 tline z0 zodd vel vodd len len transformer tl1 2 t2 1 nl p2 n2 0 el cl 0 0 0 e2 c2 0 e2 0 tlin cl 0 transformer t1 2 t2 1 z0 zeven vel veven len len transformer tl1 2 t2 1 c2 0 transformer t1 2 t2 1 Indenting the contents of a subcircuit definition is not required However it is recommended to make the subcircuit definition more easily identifiable Subcircuit GaAs Traveling Wave Amplifier Example GaAs Traveling wave distributed amplifier 2 26 5GHz Designed by Jerry Orr MWI D Hewlett Packard Co 1986 MTT symposium unpublished material global gnd vdd Simulator lang spectre Models model nGaAs gaas type n vto 2 beta 0 012 cgs 148p cgd 016p fc 0 5 subckt cell o gl g2 TL fe gnd d gnd tline len 355u vel 0 36 Gt d g2 s nGaAs Ctgd d S capacitor c 0 033p Cgg g2 gnd capacitor c 3p Gb S gl gnd nGaAs Cbgd s gnd capacitor c 0 033p Ro d cC resistor r 4k Co G gnd capacitor c 0 165p ends cell subckt stage i0 08 Devices Ql ol il b2 cell Q2 02 i2 b2 cel Q3 03 i2 b2 cell Q4 04 i4 b2 cell Q
50. backwards compatibility and might be removed in a future release to be replaced by the SPICE Reader This limited SPICE netlist reader is no longer documented as of the 4 4 3 release In the rest of this chapter SPICE Reader refers to the full SPP SPICE Reader and not this limited version January 2004 42 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility Running the SPICE Reader from Cadence Analog Design Environment When using Spectre within Cadence Analog Design Environment the need to read SPICE netlists is usually limited to model files and information from extraction tools that comes into the netlist by included files For all other design data Analog Artist produces netlists in the Spectre native syntax You can enable the use of the SPICE Reader by choosing the Setup Environment form and toggling the Use SPICE Netlist Reader spp button to Y Be sure that you do not have any relative paths specified for included files such as model files and that the Include Path field in the Setup gt Simulation Files field is blank The SPICE Reader s inability to handle relative paths is documented in the Spectre Known Problems and Solutions Running the SPICE Reader from the Command Line When you run Spectre from the command line outside of the Artist Composer environment the SPICE Reader is disabled by default As described in Running the SPICE Reader on page 42 you must use the spect resp
51. brief description 17 built in constants 91 bvbc parameter and breakdown region warnings 290 bvbe parameter and breakdown region warnings 290 bvj parameter and breakdown region warnings 290 bvsub parameter and breakdown region warnings 290 11 C C predefined percent code 270 C preprocessor CPP January 2004 318 defaults 244 using the include statement with Cadence Customer Support contacting 20 277 Cadence parameter storage format PSF 234 246 Cadence range limits defaults 284 Cadence Signal Scan output format Cadence waveform storage format WSF 234 center parameter check statement controlling checks on parameter values 194 290 example 194 290 formatting 194 290 what parameter 195 290 291 checking simulation status 241 checklimit statement 195 examples 196 syntax 195 checkpoint files automatic creation after interrupts 243 creating automatically 242 creating from the command line 243 specifications for a single analysis 243 checkpoint spectre command option 243 checks on parameter values controlling the number of 290 choosing output file formats 234 circuit age controlling for 178 example 181 circuit parameters 84 85 ckptperiod parameter in transient analysis 244 closed loop gain in netlist example of measuring 136 CMI compiled model interface description 20 CMI versioning 316 colon modifiers colon character chaining 273 e extension examples 274 formatting 274 th head
52. choose the following settings Parameter Setting Action Taken dc Initial conditions specifiers are ignored and the existing DC solution is used node The ic statements are used and the ic parameter settings on the capacitors and inductors are ignored dev The ic parameter settings on the capacitors and inductors are used and the ic statements are ignored all Both the ic statements and the ic parameters are used If specifications conflict ic parameters override ic statements Specifying State Information with State Files You can also specify initial conditions and estimate solutions by creating a state file that is read by the appropriate analysis You can create a state file in two ways m You can instruct the Spectre simulator to create a state file in a previous analysis for future use m You can create a state file manually in a text editor Telling the Spectre Simulator to Create a State File You can instruct the Spectre simulator to create a state file from either the initial point or the final point in an analysis To write a state file from the initial point in an analysis use the write parameter To write a state file from the final point use the writefinal parameter Each of the following two examples writes a state file named ua741 dc The first example writes the state file from the initial point in the DC sweep and the second example writes the state file from the final point in the DC sweep Drift dc
53. circuit it is usually faster to start the DC analysis from a previous solution than to start from the beginning Saving Time by Modifying Parameters during a Simulation The Spectre simulator lets you place specifications in the netlist to modify parameters and then resimulate This lets you accomplish tasks with a single Spectre run that might require multiple runs with another simulator To change parameter settings during a run you use the following Spectre control statements BH The aiter statement You use this statement to change the parameters of circuits subcircuits and individual models or components You also use it to change the following options statement temperature parameters and scaling factors Q temp a tnom Q scale Q scalem You can use the altergroup statement to specify device model and netlist parameter statements that you want to change the values of with analyses m The set statement Except for temperature parameters and scaling factors you use the set statement to modify any options statement parameters you set at the beginning of the netlist The new settings apply to all analyses that follow the set statement in the netlist The alter and set statements are queued up with analysis statements and are processed in order January 2004 264 Product Version 5 0 Spectre Circuit Simulator User Guide Time Saving Techniques Changing Circuit or Component Parameter Values You modify pa
54. components 64 nestlvl parameter 217 229 nodeset statement 199 261 options statement 209 parameter range limits file 285 parameter sweeps 159 163 paramtest specification 292 probe statement 215 227 pwr parameter 215 228 rules fornames 60 save parameter 215 217 228 229 save statement 211 224 scaling parameter values 83 scaling physical dimensions sens command 151 set statement 220 267 S parameter files 121 specifying parameter values 84 13 65 74 65 11 Product Version 5 0 Spectre Circuit Simulator User Guide spectre command 240 starting a simulation 240 state files 201 263 write parameter writefinal parameter subcircuit calls 97 subcircuit definitions 94 fourier component synopsis 154 model definition 154 Fourier analysis improvements in 17 fourier analysis 153 freq parameter 161 functions algebraic 88 hyperbolic 88 trigonometric 88 functions user defined 92 G GaAs traveling wave amplifier sample input file 95 gauss parameter 175 Gaussian distribution 175 gear2 integration method parameter 144 200 262 201 262 142 gear2only integration method parameter 142 144 gmin parameter increasing value with convergence problems 296 resetting to correct error conditions setting to correct accuracy problems 298 299 warning about size of 281 gmin stepping 267 gmin as homotopy parameter option 267 ground definition of 59 H h
55. currents that flow through gmin You see a message such as the one given above if the current flowing through the gmin conductors when treated as an error current does not meet the gmin criteria That is the message is displayed if the current that enters any node from all attached gmin conductors is larger than either iabstol or reltol multiplied by the sum of the absolute value of the individual currents that enter the node If your circuit is not sensitive to small leakage currents you can ignore this message If your circuit is sensitive to these currents reduce the gmin value or set it to zero Minimum Timestep Used If this problem occurs the analysis continues and a warning message is displayed at each time point that does not meet the convergence criteria In the Spectre simulator this is very rare but it does occur Occasionally this needs to be remedied to get the correct solution 1 Make sure devices have junction and overlap capacitance specified 2 Increase maxiters but do not go higher than 200 3 Change to the gear2 or gear2on1y method of integration 4 Reduce other occurrences of the local truncation error cutting the timestep Increase lteratio and increase the absolute error tolerances vabstol and iabstol Do not go too high with any of these 5 Combine 2 3 and 4 and set cmin to prevent instantaneous change at every node in the circuit 6 Relax reltol in combination with 5 Syntax Errors
56. eed wae wd 15 1 Introducing the Spectre Circuit Simulator 16 Improvements ovet SPICE 2244s d saves ge ke Ree eit Oleg ote ote UG od x 17 Improved Capacity 4 5 2t es tuo E ep SebSpREELLLSEG bed ERN 17 improved ACOU BO 6 udcudruiy oe Dir det Acb ae Donec OE kay Die BS dorky eS bd iud v aa aceon fe 17 Improved Speed EP 18 Improvec Heliabiliby arrra cee ia ik ones ere DAE Ae cad ea ha ds ea ata ed 19 IimMmpr ved Models 1 22 20 12 9 30959 9r cia coa dal alba ee ata eared Vie eee eect 20 Spectre Usability Features and Customer Service 00 00 ce eee 20 Analog HDLS see hunni ch wie ibe ead tere ea Ma ee hive Me ed he Peas buo ER a de BE ae 21 HE Capabilti s petetichnieee sis tte tes het Eke eee ee ebb ke Bt 21 Mixed Signal Simulation 4 5 2hatigestwdtawneud pas APRES eae aeet ee E RENE 23 ENVIFONMENIS 33 dens REGIGECIRRGCEUNR or aS bh cesta se retos uk CRUCE EUER E 23 2 Getting Started with Spectre sisoosoosuuuuuuu 25 Using the Example and Displaying Results 0 000 e eee eee eee 26 Salis Schematic 24 An erste ds iD e dl Loro d coke RE LC pe tet 26 Sample Netlist 22433305 tates EX Ey Ty o S bue ta d ead oer db dae eee et 28 Elements of a Spectre Netlist lille 29 Instructions for a Spectre Simulation RUN 2 ee 32 Following Simulation Progress ux nx Ree E SERE OA RR RR dena E 33 ScreenmPHmOUE C a ers Eee EAE AVV it I ns tea AO 33 Viewing Your Output 2 route
57. either the spect xe command or the options statement The Spectre simulator provides defaults for many of these options so you can avoid the inconvenience of specifying many options for each simulation Spectre defaults are satisfactory for most situations but if you have specialized needs you can also set your own defaults Spectre command line defaults control the following general areas Messages from the Spectre simulator Destination and format of results Default values for the C preprocessor Default values for percent codes Creating checkpoints and initiating recoveries Screen display Name of the simulator Simulation environment such as opus edge and so on Examining the Spectre Simulator Defaults You can identify the various Spectre defaults by consulting the detailed description of spectre command options in the Spectre Circuit Simulator Reference manual January 2004 244 Product Version 5 0 Spectre Circuit Simulator User Guide Running a Simulation Setting Your Own Defaults You can set your own defaults by setting the UNIX environment variables S_DEFAULTS or SPECTRE_DEFAULTS In 8 DEFAULTS S is replaced by the name of the simulator so this variable is typically SPECTRE_DEFAULTS However the name created by the S substitution is different if you move the executable to a file with a different name or if you call the program with a symbolic or hard link with a different name Consequently you can create mu
58. evaluating export statements and so on The default is sweep title This specifies the analysis title Specifying the First Iteration Number The advantages of using the irstrun parameter to specify the first iteration number are as follows m You can reproduce a particular run from a previous experiment when you know the starting seed and run number but not the corresponding seed m If you are a standalone Spectre user you can run a Monte Carlo analysis of 100 runs analyze the results decide they are acceptable and then decide to do a second analysis January 2004 171 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses of 100 runs to give a total of 200 runs By specifying the irstrun 101 for the second analysis the Spectre simulator retains the data for the first 100 runs and runs only the second 100 runs This gives the same results and random sequence as if you ran just a single Monte Carlo analysis of 200 runs Sample Monte Carlo Analyses For a Monte Carlo analysis the Spectre simulator performs a nominal run first if requested calculating the specified outputs If there is any error in the nominal run or in evaluating the export statements after the nominal run the Monte Carlo analysis stops If the nominal run is successful then depending on how the variations parameter is set the Spectre simulator applies process variations to the specified parameters and mismatch variations if speci
59. file of the file that is piped to the spect re command As a default action it puts the output simulation data in the directory stdin raw setenv SPECTRE DEFAULTS raw C raw sed e s S g cktfile spectre In the second example redefining the C percent code causes the Spectre simulator to base the output filename on the input filename The spect re command in the environment variable redefines the normal predefined c code The Spectre simulator substitutes the name ckt file for all C specifications and puts the output simulation data in the directory cktfile raw setenv SPECTRE DEFAULTS raw C raw sed e s S g cktfile spectre C cktfile Note For more information about Spectre defaults see Selecting Limits for Parameter Value Warning Messages on page 284 and the Spectre Circuit Simulator Reference manual Creating Filenames from Parts of Input Filenames Colon modifiers x create filenames from parts of input filenames You can use colon modifiers with all percent codes except the code January 2004 272 Product Version 5 0 Spectre Circuit Simulator User Guide Managing Files For example if you apply C r raw to the input filename opamp ckt C is the input filename opamp ckt r is the root of the input filename opamp raw is the new filename extension The result is the output filename opamp raw In this example x is the colon modif
60. format but the order and format used must be consistent through out the file and must match the order and format specified in the format line Reading the S Y or Z Parameter File After you create the S Y or Z parameter file you must place instructions in the netlist for the Spectre simulator to read it You can give these instructions with an nport model statement or directly on the instance line The following example shows how to enter an S parameter file into a netlist This model statement reads S parameters from the file Spara data model Sdata nport file Spara data datafmt spectre touchstone citiformat If the S parameter file is not in the same directory as the Spectre simulator you can use a path to the S parameter file as a value for the nport statement file parameter or you can specify a search path using the 1 command line argument The Spectre circuit simulator reads the S Y or Z parameter data file in the Spectre CITIfile or Touchstone format If you do not specify the input file format the Spectre circuit simulator detects it automatically by reading the first line in the input file as follows as Spectre as Touchstone GC as CITIfile H The Spectre circuit simulator supports B two port noise data and noise correlation matrix data in Spectre format B two port noise data in Touchstone format Spectre Format An S Y or Z parameter file in the Spectre format must have a header The
61. frequency needs to be greater than half the bandwidth January 2004 98 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Here is a version of the previous three pole filter that issues an error message if the center frequency is less than or equal to half the bandwidth define passive 3 pole bandpass filter subckt filter n1 n2 parameters bw 1 r0 1 fc 1 2 paramtest checkFreqs paramtest errorif bw 2 fc 0 4 component message center frequency must be greater than half the bandwidth C1 nl 0 capacitor c 0 3374 6 2832 bw r0 Li nl 0 inductor l r0 bw 0 3374 6 2832 fc fc C2 nl nl12 capacitor c bw 0 9705 6 2832 fc fc r0 L2 n12 n2 inductor 1 r0 0 9705 6 2832 bw C3 H2 0 capacitor c 2 2034 6 2832 bw r0 L3 n2 0 inductor l r0 bw 2 2034 6 2832 fc fc ends filter The paramtest component checkFreqs has no terminals and no effect on the simulation results It monitors its parameters and issues a message if a given condition is satisfied by evaluating to a nonzero number In this case errorif specifies that the Spectre simulator issues an error message and stops the simulation If you specify printif the Spectre simulator prints an informational message and continues the simulation If you specify warnif the Spectre simulator prints a warning and continues For more information
62. frequency small signal analyses such as ac if you sweep some parameter other than frequency you must still specify a fixed frequency value for that analysis using the freq parameter January 2004 161 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Parameter Description paramset For the sweep analysis only allows sweeping of multiple parameters defined by the paramset statement For all analyses that support sweeping to sweep the circuit temperature use param temp with no dev mod or sub parameter You can sweep a top level netlist parameter by giving the parameter name with no dev mod or sub parameter You can sweep a subcircuit parameter for a particular subcircuit instance by specifying the subcircuit instance name with the sub parameter and the subcircuit parameter name with the param parameter You can do the same thing for a particular device instance by using dev for the device instance name or for a particular model by using mod for the device model name Note If frequency is a sweep option for an analysis the Spectre simulator sweeps frequency if you leave dev mod and param unspecified That is frequency is the default swept parameter for that analysis Specifying Parameter Sets You Want to Sweep For the sweep analysis only the paramset statement allows you to specify a list of parameters and their values This can be referred by a sweep analysis to sweep the set of parameters over the v
63. gnd nout gnd vcvs gain GAIN Rocm cmout gnd resistor Perform measurements spectre options save lvlpub nestlvl 1 printParams info what output where logfile operating point opPoint dc readns C r dc write C r dc printOpPoint info what oppoint where logfile differential mode characteristics closed loop gain Av Vdif p power supply rejection ratio Vdd PSR Vdd p Vss PSR dmXferFunctions xf start 1k stop 1G dec 10 probe Rodif dmNoise noise start 1lk stop 1G dec 10 oprobe Edif oportv 1 iprobe Vdif iportv 1 step response dmEnablePulse alter dev Vdif param type value pulse annotate no dmStepResponse tran stop 2us errpreset conservative dmDisablePulse alter dev Vdif param type value dc annotate no loop gain Tv tl nvg open loop gain av out pvg nvg dmEnableTestl alter dev Vtl param mag value 1 annotate no dmEnableTest2 alter dev Vt2 param mag value 1 annotate no dmLoopGain ac start 1k stop 1G dec 10 dmDisableTestl alter dev Vtl param mag value 0 annotate no dmDisableTest2 alter dev Vt2 param mag value 0 annotate no common mode characteristics closed loop gain Av Vcm p Vss p power supply rejection ratio Vdd PSR Vdd p Vss PSR Vss p cmXferFunctions xf start 1k stop 1G dec 10 probe Rocm cmNoise noise start 1k stop 1G dec 10 oprobe Rocm oportv 1 iprobe Vcm iportv 1 step response cmEnablePulse alter dev Vcm p
64. has a unique name and component instances created from the original mode1 statement are instances of the new model created for the subcircuit The full name of each new model is the flattened name of the subcircuit followed by a dot followed by the name of the model as given in the model statement If you request the output of model data you can see these expanded models in the output B Subcircuit parameter names are local only You cannot access the value of a subcircuit parameter outside of the scope of the subcircuit in which it was declared B Parameter names must be lowercase if you want to instantiate components from SPICE mode Calling Subcircuits To call a subcircuit place an instance statement in your netlist The nodes for this instance statement are the connections to the subcircuit and the master field in the subcircuit call contains the name of the subcircuit You can enter parameters in a subcircuit call to override the parameters in the subcircuit definition for that subcircuit call The following example shows a subcircuit call and its corresponding subcircuit definition cell is the name of the subcircuit being called Q1 is the unique name of the subcircuit call and o1 i1 and b2 are the connecting nodes to the subcircuit from the subcircuit call When you call the subcircuit the Spectre simulator substitutes these connecting node names in the subcircuit call for the connecting nodes in the subcircuit definition o
65. header must have a comment beginning with a semicolon as the first line m must define the reference resistance of ports and the S Y or Z parameter formats B can include any number of comment and blank lines January 2004 122 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features When reading the file the simulator ignores all the lines beginning with semicolons spaces commas and newlines in the header The simulator reads the numbers immediately after on the lines after the reference resistance line as impedance data of the ports The format section is treated as the format definition of S parameter data entries You can enter the S Y or Z parameters in any order but the frequency must be first and is separated from the parameters with a colon Each parameter can be expressed as real imag mag deg mag rad db deg or db rad You can use commas to separate the two parts of a parameter Any number of frequency points can be presented They do not need to be equally spaced but the frequency index must be monotonic and the frequency data must be given explicitly with no hidden scale factors There is no limit to the number of ports S parameters use the syntax 13 15 when either port number is greater than 9 Adding Noise Parameters An S parameter file in Spectre format can contain external two port noise data as well as noise correlation matrix data The syn
66. i c parameters are used with the ic parameters overriding the ic statements If you specify a force file with the readforce parameter force values read from the file are used and any ic statements are ignored Once you specify the force conditions the Spectre simulator computes the DC analysis with the specified nodes forced to the given value by using a voltage source in series with a resistor whose resistance is rforce see options AC Analysis The AC analysis linearizes the circuit about the DC operating point and computes the response to all specified small sinusoidal stimulus For more information on specifying small January 2004 140 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses sinusoidal stimulus see Chapter 4 Component Statements Part 2 in the Spectre Simulator Reference The Spectre simulator can perform the analysis while sweeping a parameter The parameter can be frequency temperature component instance parameter component model parameter or netlist parameter If changing a parameter affects the DC operating point the operating point is recomputed on each step You can sweep the circuit temperature by giving the parameter name as t emp with no dev or mod parameter You can sweep a netlist parameter by giving the parameter name with no dev or mod parameter After the analysis has completed the modified parameter returns to its original value The syntax is as follows Name ac parameter
67. ii parameter parameter p Stability Analysis A e e e stb Note To generate transfer curves with the DC analysis specify a parameter and a sweep range If you specify the oppoint parameter for a DC analysis the Spectre simulator computes the linearized model for each nonlinear component If you specify both a DC sweep and an operating point the operating point information is generated for the last point in the Sweep Setting Up Parameter Sweeps To specify a parameter sweep you must identify the component or circuit parameter you want to sweep and the sweep limits in an analysis statement A parameter you sweep can be circuit temperature a device instance parameter a device model parameter a netlist parameter or a subcircuit parameter for a particular subcircuit instance Within the sweep analysis only you specify child analyses statements These statements must be bound with braces The opening brace is required at the end of the line defining the sweep Specifying the Parameter You Want to Sweep You specify the components and parameters you want to sweep with the following parameters Parameter Description dev The name of an instance whose parameter value you want to sweep sub The name of the subcircuit instance whose parameter value you want to sweep mod The name of a model whose parameter value you want to sweep param The name of the component parameter you want to sweep freq For analyses that normally sweep
68. initialization file the Spectre simulator reads parameter limits from your install dir tools dfII etc spectre range lmts You can override a SPECTRE_DEFAULTS setting with the param option of the spectre command Specifying param as a command line argument overrides param in SPECTRE DEFAULTS and tells the Spectre simulator to read range limits from the file you specify Specifying param tells the Spectre simulator to ignore the param given in SPECTRE DEFAULTS without giving the Spectre simulator a new location to find range limits Note For more information about Spectre defaults see the Spectre Circuit Simulator Reference manual and Customizing Percent Codes on page 271 January 2004 284 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Creating a Parameter Range Limits File In some circumstances you might want to set your own parameter limits for warning messages This might be the case for example if you are maintaining your own sets of model libraries If you want to choose your own parameter limits for warnings you must use a text editor to create a parameter range limits file A parameter range limits file requires the following syntax Fields enclosed by single brackets are optional ComponentKeyword model LowerLimit lt Param lt UpperLimit Observe the following syntax rules for a parameter limits file
69. m You can specify limits for input output or operating point parameters for either component instances or models You can also specify limits for analysis parameters B You must specify the limits for each parameter on a single line m You can specify open bounds using angle brackets lt or closed bounds using an angle bracket with an equal sign If you specify closed bounds there can be no space between and m You can specify inclusive or exclusive ranges If you specify exclusive ranges the upper limit must be smaller than the lower limit The diagram on the following pages shows you the proper formats for range specifications January 2004 285 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Examples of Range Limits Specifications Single boundary 1 p Inclusive boundaries 1 p 2 1 lt p lt 2 lt p lt 2 lt p lt 2 Exclusive boundaries 2 lt p lt 1 2 lt p lt 1 January 2004 286 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Examples of Range Limits Specifications continued 2 lt p lt 1 x 2 lt p lt 1 Single point boundaries 1 p 1 I 1 lt p lt 1 fH 2 lt p lt 2 Invalid boundaries 2 lt p lt 2 m The component keyword must be a Spectre name not a name used for SPICE compatibility For example use mos3 rather tha
70. month day format All leading zeros are included This format generates filenames that you can sort alphabetically into chronological order H is replaced by the host name network name of the system on which the Spectre simulator is running oe T oe ES M is replaced by the current CMIVersion oe FU P is replaced by the process ID The process ID is a unique integer assigned to the Spectre process by the operating system January 2004 270 Product Version 5 0 Spectre Circuit Simulator User Guide Managing Files oe nN S is replaced by the simulator name For example the specification S opamp1 might generate a file named spect re opamp1 If you use a different name or a symbolic link with a different name to access a copy of the executable program the new name becomes the program name oe H T is replaced by the time when the program started For example the specification T opamp1 might generate a file named 14 44 07 opampl Time is in 24 hour format and all leading zeros are included This format generates filenames that sort alphabetically into chronological order oe lt V is replaced by the simulator version string For example the specification out_ V raw might generate a file named out_1 0 2 raw oe oe This specifies the character by itself This option lets you use percent characters in filenames Two percent characters 3 in a filename specification produce a single percen
71. names for selected branches of the design hierarchy The flexibility of inherited connections allows you to use m Multiple power supplies in a design m Overridable substrate connections m Parameterized power and ground symbols You can use an inherited connection so that you can override the default connection made by a signal or terminal This method can save you valuable time You do not have to re create an entire subbranch of your design just to change one global signal For more detailed information on how to use inherited connections and net expressions with various Cadence tools in the design flow see the nherited Connections Flow Guide January 2004 78 Product Version 5 0 Spectre Circuit Simulator User Guide o Parameter Specification and Modeling Features You can use the Spectre circuit simulator models and AHDL modules in Spectre netlists This chapter describes the powerful modeling capabilities of Spectre including m Instance Component or Analysis Parameters on page 80 Parameters Statement on page 84 Expressions on page 86 Subcircuits on page 93 Inline Subcircuits on page 99 Binning on page 107 Scaling Physical Dimensions of Components on page 118 N Ports on page 120 January 2004 79 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Instance Component or Analysis Parameters In this section you will learn about the types of componen
72. no The default is no This flag applies to both scalarfile and processscalarfile 170 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Parameter Description savefamilyplots This flag specifies whether to save the multiple waveform data in parameter storage format PSF for family plotting The default is no If the flag is set to yes a separate PSF file is saved for each analysis in each Monte Carlo iteration in addition to the export scalar results that are saved to the ASCII scalar data file at the end of each iteration Saving the PSF files between runs allows you to m Cloud plot overlaid waveforms in the analog design environment m Define and evaluate new calculator measurements after the simulation has been run using the analog design environment calculator and or the Analog Waveform Display tool Note This feature can result in many very large data files You might want to monitor the disk space available after each iteration or perhaps after just the nominal simulation and extrapolate to see if sufficient disk space is available If savefamilyplots is set to no PSF files are overwritten by each Monte Carlo iteration annotate This specifies the degree of annotation such as percentage done Possible values are no title sweep Or status similar to the Spectre simulator s nested sweep analysis Use the maximum value of status to print a summary of which runs did not converge or had problems
73. of models using the altergroup statement ff 25 altergroup include models corner_ff For each model or device being altered the parameters are first defaulted and then set to the new values The parameter dependencies are updated and maintained You can include files into the alter group and can use the simulator lang spice command to switch language mode For more details on the include command see the Spectre online help spectre h include A model defined in the netlist has to have the same model name and primitive type Such as bsim2 bsim3 or bjt in the alter group For model groups you can change the number of models in the group You cannot change from a model to a model group and vice versa For details on model groups see the Spectre online help spectre h bsim3v3 Further Examples of Changing Component Parameter Values This example changes the is parameter of a model named SH3 to the value 1e 15 modify2 alter mod SH3 param is value 1e 15 The following examples show how to use the param default in an alter statement The first parameter listed for resistors in the Spectre online help is the default For resistors this is the resistance parameter r Consequently if R1 is a resistor the following two alter statements are equivalent changel alter dev R1 param r value 50 changel alter dev R1 value 50 January 2004 188 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements
74. on any one of these devices for example spectre h mos1 gives you more details For the auto model selector program to find a specific model the models to be searched need to be grouped together within braces Such a group is called a model group An opening brace is required at the end of the line defining each model group Every model in the group is given a name followed by a colon and the list of parameters Also you need to specify the device length and width using the four geometric parameters 1max 1min wmax and wmin The selection criteria to choose a model is as follows lmin lt inst length lt lmax and wmin lt inst width wmax For example model ModelName ModelType d lmin 2 lmax 4 wmin 1 wmax 2 vto 0 8 2 lmin 1 lmax 2 wmin 2 wmax 4 vto 0 7 3i lmin 2 lmax 4 wmin 4 wmax 6 vto 0 6 Then for a given instance M1 1 2 3 4 ModelName w 3 1 1 5 January 2004 108 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features the program searches all the models in the model group with the name ModelName and then picks the first model whose geometric range satisfies the selection criteria In the preceding example the auto model selector program chooses ModelName 2 Conditional Instances You can specify different conditions that determine which components the Spectre simulator instantiates for a given simulation The determining conditions are compu
75. operating point m Node Capacitance Table The node capacitance table displays the capacitance between the nodes of a circuit You can also list the minimum and maximum values for the input output and operating point parameters along with the names of the components that have those values Parameter Setting Action Taken what oppoint Prints the oppoint parameters Other possible values are none inst input output nodes all terminals oppoint models and captab January 2004 202 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Parameter Setting Action Taken where logfile Prints the parameters to the logfile Other possible values are nowhere screen file and rawfile file 2 C r info what File name when where file save all nestlvl xtremes yes tile test Saves all signals to output Other possible values are 1v1 allpub lvlpub selected and none Specifies levels of subcircuits to report The default value is infinity Prints minimum and maximum values Other possible values are no and only Prints test as the title of the analysis in the output file Specifying the Parameters You Want to Save You specify parameters you want to save with the info statement what parameter You can give this parameter the following settings Setting Action none Lists no parameters inst Lists input parameters for instances of all components models Lists input
76. parameters can be referenced by models or instances in the main netlist and can represent IC manufacturing process variation or component variations for board level designs For more information about the statistics statement see Specifying Parameter Distributions Using Statistics Blocks on page 173 January 2004 221 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options This chapter discusses the following topics Signals as Output on page 223 Saving Signals for Individual Nodes and Components on page 223 Saving Groups of Signals on page 229 Listing Parameter Values as Output on page 232 Preparing Output for Viewing on page 234 Accessing Output Files on page 235 January 2004 222 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options Signals as Output Signals are quantities that the simulator must determine to solve the network equations formulated to represent the circuit The signals must be known before other output data can be computed Signals are mainly the physically meaningful quantities of interest to the user such as the voltages on the topological nodes and naturally computed branch currents such as those for inductors and voltage sources Other examples of signals are the voltages at the internal nodes of components and the terminal currents computed by using current probes at device or subcircuit terminals Note If there are more
77. parameters for models of all components input Lists input parameters for instances and models of all components output Lists effective and temperature dependent parameter values all Lists input and output parameter values oppoint Lists operating point parameters terminals The output is a node to terminal map nodes The output is a terminal to node map captab Prints node to node capacitance The info statement gives you some additional options You can use the save parameter of the info statement to specify groups of signals whose values you want to list For more information about save parameter options consult Saving Groups of Signals on page 229 January 2004 203 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Finally you can generate a summary of maximum and minimum parameter values with the extremes option Specifying the Output Destination You can choose among several output destination options for the parameters you list with the info statement With the info statement where parameter you can m Display the parameters on a screen BH Send the parameters to a log file to the raw file or to a file you create When the info analysis is called from a transient analysis or used inside of a sweep the name of the info analysis is prepended by the parent analysis If the file option is used to save the results use the A percent code described in Description of Spectre Predefined Perc
78. protected block so that your users can create Composer symbols for simulation All flattened primitive devices expanded from a protected subcircuit are also protected January 2004 249 Product Version 5 0 Spectre Circuit Simulator User Guide Encryption Example Original Netlist Encrypted Netlist subckt name inv I O pins 2 subckt name inv I O pins 2 parameters wi le parameters wi le protect pragma protect begin_protected subckt inv out in pragma protect data method RC5 parameters wi lu le 3u pragma protect data keyowner Cadenc mpl mid in vd vd pmos w wi l le DEOZUM SYSTEMS NT Bees ews AES pragma protect data_keyname CDS KEY pragma protect data block rl mid out resistor r 2k model pmos bsim3v3 type p tnom 27 0 Fe eho weer epi eed tox 2 9e 09 OERWfdjau77r42jagadfhjkuer model nmos bsim3v3 type n tnom 27 0 jdfejwrADFASDfdhf jad Dames jdfejwrADFASDfdhfjad snes pragma protect end_protected unprotect open latch module open latch module subckt latch q qbar clk d subckt latch q qbar clk d Encrypting a Subcircuit without Interfaces To encrypt the contents of a subcircuit leaving its name and l O pins public place protect after subckt and unprotect before ends January 2004 250 Product Version 5 0 Spectre Circuit Simulator User Guide Encryption Example Original Netlist subckt inv out in protect parameters wi lu le 3u mpl mid in vd vd pmos
79. reduce reliability or accuracy such as device bypass simplified models or relaxation methods are not used in the Spectre circuit simulator User control of accuracy tolerances For some simulations you might want to sacrifice some degree of accuracy to improve the simulation speed For other simulations you might accept a slower simulation to achieve greater accuracy With the Spectre circuit simulator you can make such adjustments easily by setting a single parameter Improved Speed The Spectre circuit simulator is designed to improve simulation speed The Spectre circuit simulator improves speed by increasing the efficiency of the simulator rather than by sacrificing accuracy Faster simulation of small circuits The average Spectre simulation time for small circuits is typically two to three times faster than SPICE The Spectre circuit simulator can be over 10 times faster than SPICE when SPICE is hampered by discontinuity in the models or problems in the code Occasionally the Spectre circuit simulator is slower when it finds ringing or oscillation that goes unnoticed by SPICE This can be improved by setting the macromodels option to yes Faster simulation for large circuits January 2004 18 Product Version 5 0 Spectre Circuit Simulator User Guide Introducing the Spectre Circuit Simulator The Spectre circuit simulator is generally two to five times faster than SPICE with large circuits because it has fewer convergence d
80. section O refers to the output parameters section and OP refers to the operating point parameters section and the number refers to where the parameter is in the numbered list spectre helpsort When you type spectre helpsort name Where name is the name of a component or analysis you get the same information as you do with spectre h name but the parameters are sorted alphabetically instead of divided into related groups January 2004 82 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features spectre helpfull When you type spectre helpfull name where name is the name of a component or analysis you get related parameters grouped as you do with spectre h name and you get the following additional information m Parameter type m Parameter dimension scalar or vector B Parameter range spectre helpsortfull When you type spectre helpsortfull name where name is the name of a component or analysis you get the same information as you do with spectre helpsort name but the parameters are sorted alphabetically instead of divided into related groups Scaling Numerical Literals If a parameter value is an integer or a floating point number you can scale it in the following ways m Follow the number with an e or an E and an integer exponent for example 2 6563 5 32e 4 1E 14 3 04E6 m Use scale factors for example 5u 3 26k 4 2m Important You cannot use bo
81. step 1 probe Rload param temp freq 1kHz This statement uses a vector to specify sweep values for device vcc The values specified for the sweep are 0 2 6 7 8 and 10 SwpVccDC dc dev Vcc values 02 6 7 8 10 Monte Carlo Analysis The montecarlo analysis is a swept analysis with associated child analyses similar to the sweep analysis see spectre h sweep The Monte Carlo analysis refers to statistics blocks where statistical distributions and correlations of netlist parameters are specified Detailed information on statistics blocks is given in Specifying Parameter Distributions Using Statistics Blocks on page 173 For each iteration of the Monte Carlo analysis new pseudorandom values are generated for the specified netlist parameters according to their specified distributions and the list of child analyses are then executed The Cadence design environment Monte Carlo option allows for scalar measurements to be linked with the Monte Carlo analysis Calculator expressions are specified that can be used to measure circuit output or performance values such as the slew rate of an operational amplifier During a Monte Carlo analysis these measurement statement results vary as the netlist parameters vary for each Monte Carlo iteration and are stored in a scalar data file for postprocessing By varying netlist parameters and evaluating these measurement statements the Monte Carlo analysis becomes a tool that allows you to examine an
82. strobing This parameter is also used to skip data points m The strobedelay parameter optional which lets you set a delay between the skipstart time and the first strobe point Telling the Spectre Simulator How Many Data Points to Save By telling the Spectre simulator to save only every Nth data point you can reduce the size of the results database generated by the Spectre simulator You tell the Spectre simulator to save every Nth data point with the following parameters m With the skipcount parameter which you set to N to make the Spectre simulator save every Nth data point January 2004 146 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses B The skipstart parameter which tells the Spectre simulator when to start skipping parameters This parameter is also used in strobing m The skipstop parameter which tells the Spectre simulator when to stop skipping parameters This parameter is also used in strobing Examples of Strobing and Skipping In the following example the Spectre simulator starts skipping data points at Time 10 seconds and continues to skip points until Time 35 seconds During this 25 second period the Spectre simulator saves only every third data point ExSkipSt tran skipstart 10 skipstop 35 skipcount 3 In this example the Spectre simulator starts strobing at Time 5 seconds and continues until Time 20 seconds During this 15 second period the Spectre simulator saves data point
83. subcircuits start with x so you need to rename all instance statements to start with x if you replaced a model with a subcircuit Process Modeling Using Inline Subcircuits Another modeling technique is to specify geometrical parameters such as widths and lengths to a device such as a bipolar transistor and then to create a parameterized model based on that geometry In addition the geometry can be modified according to certain process equations allowing you to model nonideal etching effects for example You use inline subcircuits and some include files for process and geometric modeling as in the following example files The ProcessSimple h file defines the process parameters and the bipolar and resistor devices January 2004 104 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features File ProcessSimple h simulator lang spectre define process parameters including mismatch effects parameters RSHSP 200 RSHPI 5k sheet resistance pinched sheet res SPDW 0 SNDW 0 etching variation from ideal XISN 1 XBFN 1 XRSP 1 device mismatch mm parameters XISNafac 100m XISNbfac 1m IS scaling factors for mm eqns XBFNafac 100m XBFNbfac 1m BF XRSPafac 100m XRSPbfac 1m RS u n a RSHSPnom 200 RSHPInom 5k sheet resistance nom values FRSHPI RSHPI RSHPInom ratio of PI sheet res to nom define simple bipolar and resistor devices
84. supports two language modes m Spectre mode mostly discussed here mH SPICE mode You can specify the language mode for subsequent statements by specifying simulator lang mode where mode is spectre Or spice Spectre mode input is fully case sensitive In contrast except for letters in quoted strings SPICE mode converts input characters to lowercase January 2004 59 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Creating Component and Node Names When you create node and component names in the Spectre simulator follow these rules m Do not use the name of an analysis such as t ran or built in primitive such as resistor m Except for node names names must begin with a letter or underscore Node names can also be integers W iIfthe node name is an integer leading zeros are significant in the Spectre language mode m Names can contain any number of letters digits or underscores BH Names cannot contain nonalphanumeric characters blanks tabs punctuation characters or continuation characters unless they are escaped with a backslash The exception is bang for example vdd m he following reserved words case specified should not be used as node names net names instance names model names or parameter names M 1 PI M 2 PI M 2 SQRTPI M DEGPERRAD M E M LN10 M LN2 M_LOG10E M_LOG2E M_PI M_PI_2 M_PI_4 M_SQRT1_2 M_SQRT2 M_TWO_PI P_
85. syntax January 2004 302 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits Ring oscillator Spectre deck for INVERTER ring with no fanouts simulator lang spectre global 0 gnd vdd vss aliasGnd gnd 0 vsource type dc dc 0 Spectre options to be used SetOptionl options iabstol 1 00n audit full temp 25 MyAcctl info what inst extremes yes MyAcct2 info what models extremes yes MyAcct3 info what input extremes yes MyAcct5 info what terminals extremes yes MyAcct6 info what oppoint extremes yes Next section is the subckt for inv subckt inv nqa ml nq a vdd vdd p 1 0 35u w 2 60u ad 1 90p pd 6 66u as 1 90p ps 6 66u m2 vss a nq vss n 1 0 35u w 1 10u ad 0 80p pd 3 66u as 0 80p ps 3 66u Interconnect Caps for inv c0 a vdd capacitor c 1 0824323e 15 cl ang capacitor c 3 0044e 16 c2 nq vss capacitor c 5 00186e 16 cs nq vdd capacitor c 6 913993e 16 c4 a vss capacitor c 8 5372566e 16 ends Begin top level circuit definition xinvl 1 90 inv xinv2 2 1 inv xinv3 32 inv xinv4 4 3 inv xinv5 5 4 inv xinv6 6 5 inv xinvy y 6 inv xinv8 8 7 inv xinv9 9 8 inv xinv10 10 9 inv xinvll 11 10 inv xinv12 12 11 inv xinvl13 13 12 inv xinvl4 14 13 inv xinv15 15 14 inv xinvl6 1615 inv xinv17 90 16 inv Next couple of lines sets variables for vdd and vss parameters vdd S1
86. the component Q1 ol il b2 npn Note The model statement is described in Model Statements on page 70 You can specify additional parameters for an individual component in an instance statement that refers to a model statement You can find a list of available instance parameters and a list of available model parameters for a component in the Spectre online help for that component spect re h Example of Forward Referencing in Hierarchical Nodes simulator lang spectre cl xa mid 0 capacitor c 0 2p xa 1 2 buffer Example of Relative Path Referencing in Hierarchical Nodes simulator lang spectre subckt wrapper a b xlabres in series rh x1 int1 x1 int2 resistor r 1 ends x2 1 0 wrapper Basic Instance Statement Rules When you prepare netlists for the Spectre simulator remember these basic rules m You must give each instance statement a unique name B Ifthe master is a model you need to specify the model January 2004 64 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Identical Components or Subcircuits in Parallel If your circuit contains identical devices or subcircuits in parallel you can specify this condition easily with the multiplication factor m Specifying Identical Components in Parallel If you specify an m value in an instance statement it is as if m identical components are in parallel For example capacitances are multiplied by m and resistances are divid
87. the end of any SPICE statement For example Additional Spectre parameter to resistor Vin input 0 dc 1 AC 1 0 X1 mainnetlist in out Rload out 0 1k isnoisy no isnoisy is spectre parameter include main ckt ac dec 10 1k 100k noise v out end If the netlist is to be run by a SPICE simulator at a later time these Spectre parameters must be hidden or removed See the next section for information on how to hide Spectre text Hiding Spectre Text from SPICE You can create a SPICE mode input file that you can use with both a SPICE based simulator and the Spectre simulator When you run the Spectre simulator you can use Spectre features unavailable in SPICE For example if you want to specify a Spectre parameter that SPICE does not support you write the Spectre statements so they do not cause syntax errors when you run the SPICE based simulator To create such an input file follow these steps 1 Insert the special prefix spectre atthe beginning of a line in your SPICE netlist January 2004 54 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility The line should start with an asterisk optionally followed by blanks or tabs followed by the string spectre spectre Spectre text Be sure to leave a space after the colon Place Spectre specific input language statements after the Notepecial prefix The Spectre simulator recognizes the Spectre statements after the prefix as inp
88. the filenames further specify that the degradations are for circuitage 0 and January 2004 183 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses circuitage 4 0 the values requested in the t ran statements The contents of these two files are shown in the following tables Device Lifetime Years in Ascending Order Device Vin lifetime Uj lifetime Age sec x7 m1 4 5372 3 9493 6 9888e 18 x3 m1 4 563 3 9718 6 9493e 18 x9 m1 4 5865 3 9922 6 9138e 18 x2 m1 4 5935 3 9983 6 9032e 18 x11 m1 4 6045 4 0078 6 8867e 18 x5 m1 4 6269 4 0273 6 8534e 18 x2 m2 5 6758 4 9404 5 5868e 18 x3 m2 6 5803 5 7277 4 8189e 18 x6 m2 6 6639 5 8004 4 7585e 18 x1 m2 6 6998 5 8317 4 733e 18 x10 m2 6 7037 5 8351 4 7302e 18 x4 m2 6 7768 5 8986 4 6792e 18 x8 m2 6 8111 5 9285 4 6556e 18 x4 m1 7 2344 6 297 4 3832e 18 x1 m1 8 1518 7 0956 3 8899e 18 x10 m1 9 0831 7 9062 3 4911e 18 x6 m1 9 0909 7 9129 3 4881e 18 x8 m1 9 3002 8 0952 3 4096e 18 x9 m2 12 981 11 299 2 4428e 18 x5 m2 13 019 11 332 2 4356e 18 x7 m2 13 235 11 52 2 3959e 18 x11 m2 13 291 11 569 2 3858e 18 January 2004 184 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Device Degradations after Four Years in Descending Order Device DeltaVth V DeltaUo Delta Gm Delta ld Status x7 m1 0 08816 10 115 10 112 10 094 Failed x3 m1 0 087661 10 064 10 06 10 042 Failed x9 m1 0 087213 10 018 10 014 9 9962 Failed x2 m1 0 087079 10 004 10
89. the sparse matrix factorization 297 options statement settings to prevent 296 oscillators causing 297 pivotdc parameter settings to correct 297 pivrel parameter resetting to correct 297 realistic device models needed 296 reduced in Spectre 19 region parameter settings in bipolar analog circuits causing 297 region parameters of transistors and diodes 297 replacing DC analysis with transient analysis to correct 297 restarts to correct 297 rforce parameter increasing with nodesets 297 step size 296 system messages helpful 295 temperature sweeps to correct 297 topcheck parameter enabling 296 transient analysis 298 unusual parameter values checking for 296 corners example 114 correlation coefficients correlation statements CPP C preprocessor defaults 244 using the include statement with 72 178 177 crigm parameter 180 criids parameter 180 criuo parameter 180 crivth parameter 180 cshrc file and environment defaults 245 Cadence range limits 284 current probes correcting convergence problems with 296 probe statement 215 227 saving individual currents with 214 226 setting multiple 219 232 setting with the save statement 215 Product Version 5 0 Spectre Circuit Simulator User Guide 227 when to use 214 22 currents parameter example 219 231 formatting 219 231 not used in subcircuit calls 213 22 options statement 219 231 customer service contacting 20 277 customizing error a
90. the specified model are checked If the parameter to be checked is a model parameter specified using the modelparam parameter only the specified model is checked primitive primitive Primitive whose model or instance parameter is to be checked For a complete list of primitives see spectre h components January 2004 190 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements param parameter_name modelparam parameter min value max value duration independent var_limit message message level notice warning error info yes no Device instance or netlist parameter to be checked It is checked within the scope of the specified sub dev mod or primitive Model parameter to be checked Lower limit of the parameter to be checked The min and max parameters set the limits that border the expected operating region Default value co Upper limit of the parameter to be checked The min and max parameters set the limits that border the expected operating region Default value 20 Time period over which the check has to be violated before a warning is displayed Applicable to transient analyses only Message to be printed if the check fails Severity level of the message if the check fails If the severity level is notice or warning simulation continues after the message is displayed If the severity level is error the Spectre circuit simulator aborts the analysi
91. through the terminal Current Voltage January 2004 58 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Ground Ground is a common reference point in an electrical circuit The value of ground is zero Node A node is an infinitesimal connection point The voltage everywhere on a node is the same According to Kirchhoff s Current Law also known as Kirchhoff s Flow Law the algebraic sum of all the flows out of a node at any instant is zero Basic Syntax Rules The following syntax rules apply to all statements in the Spectre Netlist Language W Field separators are blanks tabs punctuation characters or continuation characters B Punctuation characters such as equal signs parentheses and colons are significant to the Spectre simulator m Youcan extend a statement onto the next line by ending the current line with a backslash You can use a plus sign to indicate line continuation at the beginning of the next line The preferred style is the at the end of the line m You can indicate a comment line by placing a double slash at the beginning of the comment The comment ends at the end of that line You can also use an asterisk to indicate a comment line The preferred style is using m You can indicate a comment for the remainder of a line by placing a space and double slash anywhere in the line Spectre Language Modes The Spectre netlist
92. tools CDS SYSNAME spectre lib cmi SM To prepend a path prepend path path 2 path N Example 1 prepend SHOME myLib cmi M Example 2 prepend SHOME myLib cmi M SHOME cds 4 4 6 tools S CDS SYSNAME spectre lib cmi SM To append a path append path path2 path N Example 1 append HOME myLib cmi M Example 2 append SHOME myLib cmi M SHOME expLib cmi M The default search path is the path to the directory that contains Spectre shared objects SCDS_ROOT tools spectre lib cmi CMIVersion January 2004 313 Product Version 5 0 Spectre Circuit Simulator User Guide Dynamic Loading To load a shared object load path soname ext Example 1 load libnortel so Example 2 load SHOME myLib cmi M libmydevice so To unload a shared object unload path soname ext version Example 1 unload libsiemens so 1 Example 2 unload HOME myLib cmi M libmydevice so The name of the shared object file includes an extension and can also have a version number The path to the shared object is optional If you do not specify the path the Spectre simulator uses the search path from the current configuration file A line that begins with a semicolon is a comment and is ignored Empty lines are allowed and are ignored Precedence for the CMI Configuration File The Spectre simulator reads configuration files in the following order The default Cadence CM
93. tox 800e 10 pb 0 605 js le 4 xj 0 5u l1d 20 1u wd 1 5u uo 167 bvj 14 model dnp diode is 3 1e 10 n 1 12 cjo 3 1e 8 pb 914 m 5 bvj 45 imax 1000 model dpn diode is 1 3e 10 n 1 05 cjo 9 8e 9 pb 605 m 5 bvj 45 imax 1000 endsection slow endlibrary Process File This example of automatic model selection with the conditional i statement is more sophisticated than the previous example in Fully Differential CMOS Operational Amplifier on page 112 With this example you ask for an nmos transistor and the Spectre simulator automatically selects the appropriate model according to the process corner the circuit temperature and the device width and length The selection is done by the parameterized inline subcircuit and the conditional i statement The paramtest statements create warnings if the model selection parameters are out of range Models are assigned to instances depending on the initial values of their parameters January 2004 115 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features when the circuit is input Note that the instances are not reassigned to new models if the selection parameters later change However the models are updated if the circuit temperature is changed Notice that even though nmos is defined as a subcircuit it is called as if itis a MOSFET primitive The MOSFET model parameters are deleted to keep this example to
94. tran stop 30n infotimes 10n 25n infoname opinfo opinfo info what oppoint where rawfile The opinfo statement is called at 10 and 25 nanoseconds The data for all devices is reported at these specified time points Pole Zero Analysis The pole zero analysis linearizes the circuit about the DC operating point and computes the poles and zeros of the linearized network The analysis generates a finite number of poles and zeroes each being a complex number If you sweep a parameter the parameter values corresponding to the current iteration are printed January 2004 148 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses The pole zero analysis works best on small to medium sized circuits circuits with less than a thousand equations If you run a pole zero analysis on a frequency dependent component element whose AC equivalent varies with frequency such as transmission line or BUT with excess phases the Spectre circuit simulator approximates the component as AC equivalent conductance and evaluates conductance at 1Hz You can set up and run a pole zero analysis through the Analog Design Environment For more information see the Analog Design Environment User Guide Syntax analysisName pz pnode nnode where analysisName Name of analysis pnode nnode Nodes in the circuit whose difference is the output of the transfer function for which zeroes are to be calculated If you do not specify the input source
95. transient analyses Unlike initial conditions their values have no effect on the final results Nodesets usually act only as aids in speeding convergence but if a circuit has more than one solution as with a latch nodesets can bias the solution to the one closest to the nodeset values Setting Initial Conditions for All Transient Analyses You can specify initial conditions that apply to all transient analyses in a simulation or to a single transient analysis The ic statement and the ic parameter described in this section set initial conditions for all transient analyses in the netlist In general you use the ic parameter of individual components to specify initial conditions for those components and you use the ic statement to specify initial conditions for nodes You can specify initial conditions for inductors with either method Specifying cmin for a transient analysis does not satisfy the condition that a node has a capacitive path to ground January 2004 197 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Note Do not confuse the ic parameter for individual components with the ic parameter of the transient analysis The latter lets you select from among different initial conditions specifications for a given transient analysis Specifying Initial Conditions for Components You can specify initial conditions in the instance statements of capacitors inductors and windings for magnetic cores The ic p
96. type p tnom 27 0 tox 2 9e 09 model nmos bsim3v3 type n tnom 27 0 tox 2 8e 09 unprotect Example 2 Encrypted Netlist The lst model name is pmos type is p The 2nd model name is nmos type is n subckt inv out in paramemters wi lu le 3u mp1 mni en QE ds inv pragma pragma pragma Design pragma pragma mid in vd vd pmos w wi l le mid in 0 0 nmos w wi l le protect begin_protected protect data_method RES protect data_keyowner Cadenc Systems protect data_keyname CDS_KEY protect data_block RWfdjau77r42jagadfhjkuer pragma protect end_protected In the following example the protect keyword is within the model card definition leaving a number of parameters outside the protection block The model name and parameters outside the protection block remain public but the whole model is protected for message and parameter output during simulation Original Netlist model pmos bsim3v3 type p tnom 27 0 tox 2 9e 09 protect Nch 2 498E 17 Tox 27 0 tox 2 9e 09 Xj 1 00000E 07 Lint 9 36e 8 Wint 1 47e 7 VthO 6322 K1 756 K2 3 83e 2 tDvt2 9 17e 2 N1x 3 52291E 08 Dwg 6 0E 09 Dwb 3 56E 09 Cit 1 622527E 04 Cdsc 2 147181E 05 unprotect January 2004 Encrypted Netlist model pmos bsim3v3 type p tnom 27 0 tox 2 9e 09 pragm pragm 253 a a Design Systems a a a
97. vg start 0 stop 2 step 0 1 analysisDCswp2 dc param dc dev vdr start 0 stop 5 step 0 1 end m Mixed language Spectre allows the use of both SPICE and Spectre syntax in the same netlist The SPICE Reader does not read the Spectre statements thus statements in the SPICE sections January 2004 47 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility that are dependent on Spectre statements might get improperly mapped Except for model and subcircuit names do not have any dependencies between these two language sections Language Differences Comparing the SPICE and Spectre Languages When you run the SPICE Reader all SPICE statements are mapped directly to Spectre input There are several important differences between these two languages that are addressed by the SPICE Reader To get a better idea at the differences between the two languages an example netlist is shown below First is the SPICE version of the netlist for an oscillator from Sample Netlist on page 28 BJT ECP Oscillator Veo 4 05 Tee 2 0 1MA Q1 1 3 2 NPN Q2 4 5 2 NPN L1 4 5 1UH C1 1 5 1PF 2 5 3 2 TARE C3 3 0 3NF C4 5 6 3NF R1 3 0 10K R2 5 6 10K ic V 3 1 model NPN NPN BF 80 RB 100 VAF 50 CJS 2PF TF 0 3NS TR 6NS CJE 3PF CJC 2PF option method trap tran lus 80us 10ns Here is the Spectre version of the same netlist BJT ECP Oscillator simulator lang spectre Vcc vcc 0 vso
98. warning is printed if region rev because the conditions 3 lt region and region lt 1 exclude only region 2 and region2is rev For more information on parameter range checking see Checking for Invalid Parameter Values on page 98 January 2004 81 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Help on Parameters There are four main ways to get online help about Spectre component or analysis parameters spectre help When you type spectre help name where name is the name of a component or analysis you get the following information B Parameter names Related parameters are grouped together m Parameter defaults B Units B Parameter description For analyses and controls parameters are listed in the Parameters section At the end of the longer parameter listings is the parameter index This index lists the parameters alphabetically and gives the number that corresponds to where the parameter is in the numbered list For components parameters are divided into up to four sections Instance Parameters Model Parameters Output Parameters and Operating Point Parameters At the end of longer parameter listings is the parameter index This index indicates where to find a parameter s description with a letter and a number The letter refers to the section for example refers to the instance parameters section M refers to the model parameters
99. x1 pwr generated by the save statement Saving Groups of Signals To save groups of signals as results you use the save and nest 1v1 parameters You specify which signals you want to save with the save parameter You use the nest 1v1 parameter when you save signals in subcircuits The nest 1v1 parameter specifies how many levels deep into the subcircuit hierarchy you want to save signals You can set these parameters as follows B In options statements or set statements If you set the save and nest 1v1 parameters with an opt ions ora set statement the setting applies to signal data from all analyses that follow that statement in the netlist B In most analysis statements If you set the save and nest1lv1 parameters with an analysis statement the setting applies to that analysis only It overrides any previous save or nest l1v1 settings Formatting the save and nestlvl Parameters The syntax for both the save and nest 1v1 parameters is illustrated by the following options statement settingl options save lvlpub nestlvl 2 The save Parameter Options The following table shows the possible settings for the save parameter Setting Action none Does not save any data currently does save one node chosen at random January 2004 229 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options Setting Action selected Saves only signals specified with save statements This is the default settin
100. 0 Spectre options SetOptionl options iabstol 1 00n audit full rforce 1 temp 25 MyAcctl info what inst extremes yes MyAcct2 info what models extremes yes MyAcct3 info what input extremes yes MyAcct5 info what terminals extremes yes MyAcct6 info what oppoint extremes yes Next section is the subckt for no3 subckt no3 nga ml vdd a 7 vdd p 1 0 35u w 3 60u ad 2 63p pd 8 66u as 0 38p ps 3 81u m2 7 vss 8 vdd p 1 0 35u w 3 60u ad 0 38p pd 23 81u as 0 38p ps 3 81u m3 nq vss 8 vdd p 1 0 35u w 3 60u ad 1 37p pd 4 36u as 0 38p ps 3 81lu m4 nq vss 9 vdd p 1 0 35u w 3 60u ad 1 37p pd 4 36u as 0 38p ps 3 81lu P p m5 9 vss 10 vdd 1 0 35u w 3 60u ad 0 38p pd 23 81u as 0 38p ps 3 81u m6 vdd a 10 vdd 1 0 35u w 3 60u ad 2 63p pd 8 66u as 0 38p ps 3 81u January 2004 308 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits m7 vss a nq vss n 1 0 35u w 1 40u ad 1 02p pd 4 26u as 0 53p ps 2 16u m8 vss vss nq vss n 1 0 35u w 1 40u ad 0 53p pd 2 16u as 0 53p ps 2 16u m9 vss vss nq vss n 1 0 35u w 1 40u ad 0 53p pd 2 16u as 1 02p ps 4 26u c1 9 nq capacitor c 3 7995e 17 ez vdd vss capacitor c 1 3996057e 15 c3 nq vss capacitor c 3 1546797e 15 c4 nq vdd capacitor c 5 5551875e 16 c5 a vss capacitor c 1 2907233e 15 c6 a vdd capacitor c 2 1779808e 15 c7 10 nq capacitor c 2 0115e 17 c8 ang capacitor c 5 233362e 16 ends
101. 1 as an abbreviation of 210g log The Spectre simulator does not create a log file You can use 1 as an abbreviation of 1og This is the default option Command Line Example The following entry on the command line runs a simulation for circuit smps circuit and sends all messages to a log file named smps logfile spectre log smps logfile smps circuit Setting Environment Variables If you specify log file options ina SPECTRE_DEFAULTS environment variable you might want to name log files according to some system that helps you keep track of log files from different simulations Spectre predefined percent codes are useful for this The following example uses the predefined percent code C to create log filenames based on the input filename If you run a simulation for smps circuit the Spectre simulator creates a log file named smps circuit logfile You place the SPECTRE_DEFAULTS environment variable in the cshrc Or profile files setenv SPECTRE_DEFAULTS log C logfile January 2004 294 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting For more information about predefined percent codes and the SPECTRE_DEFAULTS environment variable see Chapter 12 Managing Files Suppressing Messages There are also spectre command options that let you print or suppress error warning or informational messages terror Prints error me
102. 1 is substituted for o i 1 is substituted for g1 and 52 is substituted for g2 The length of transmission line TL is changed to 500 um for this subcircuit call from its 355 um default value in the subcircuit definition Q1 ol il b2 cell length 500um Subcircuit call UN subckt cell o gl g2 q Substitutions parameters length 355um TL o gnd d gnd tline len length vel 0 36 Gt d g2 S nGaAs Ctgd d S capacitor c 0 033p Cgg g2 gnd capacitor c 3p Gb S gl gnd nGaAs Cbgd s gnd capacitor c 0 033p Ro d c resistor r 10k Co ol gnd capacitor c 0 165p January 2004 97 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features ends cell Modifying Subcircuit Parameter Values The following example is a passive Bessel three pole bandpass filter with default parameter values for bandwidth termination resistance and center frequency The bw r0 and c parameters are given default values in the subcircuit but you can change these values when you call the subcircuit Changing the value of bw x0 and c in a subcircuit call changes the values of many parameters in instance statements that refer to these three parameters define passive 3 pole band filt Default specifications if T P i RURSUS pe forbw r0 andfc subckt filter nl n2 parameters bw 1 r0 1 fc 1 Bia Cl nl 0 capacitor c 0 3374 6 2832 bw ro L1 nl 0 inductor l r0 bw 0 3374 6 2832 fc fc C2
103. 16 va 59 8 model npnl10x10 bjt is 3 5e 16 va 61 5 model npn20x20 bjt is 3 77e 16 va 60 5 ends npn mod The transistors end up having the name that they were called with q1 q2 and q3 but each has the correct model chosen for its respective area Model binning can be now achieved based on any parameter and for any device such as resistor Or b jt A Warning about Conditional Instantiation If you run a sweep analysis on the previous circuit sweeping the parameter area for device instance q1 from 350 x 10 to 50 x 10 the Spectre simulator issues an error and stops once the value of area exceeds 100 x 10712 This is because the condition in i area lt 100e 12 changes from being true to being false and this can result in a topology change that is not supported In general this error is produced for any analysis that changes the value of the conditional expression Rules for General Purpose Model Binning The following set of rules exists for general purpose model binning as outlined in the preceding example Within subcircuit npn mod the inline device npn mod is referenced January 2004 111 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features three times each with a different model Allowing multiple instances or references to the same named device is possible only under the following strict topological conditions m The reference to the same n
104. 2004 55 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility Conflicts between SPICE variations Node 00 is treated as a number that is zero in SPICE2 and a string that is 00 in SPICES and thus are interpreted differently The SPICE Reader treats these like SPICES Leading spaces are ignored in SPICE2 and treated as a comment in SPICE3 The SPICE Reader treats these as SPICE2 does Lib in PSPICE provides a file to search for each instantiated model in HSPICE it acts as a section specific include statement The SPICE Reader treats these as HSPICE does alter in SPICE2 allows multiple lines to be relisted with deltas following this statement In SPICES the alter is an interactive command and only allows one parameter to be changed per alter statement The SPICE Reader treats these as SPICE2 does In some versions of SPICE global parameters values override values specified on instances of subcircuits The SPICE Reader treats all parameter values specified on any instance including subcircuits as the final value instead of allowing a global to override it For more information on specific SPICE Reader limitations please see the SPP Known Problems and Solutions on SourceL ink January 2004 56 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists This chapter discusses the following topics Netlist Statements on page 58 Instance Statements on page 62 Analysis
105. 2354 1 4426950408889634074 0 434294481 90325182765 0 69314718055994530942 2 30258509299404568402 3 14159265358979323846 6 2831853071 7958647652 1 57079632679489661923 0 78539816339744830962 0 3183098861 8379067154 0 63661977236758134308 1 12837916709551257390 1 41421356237309504880 0 707106781 18654752440 57 29577951 30823208772 1 6021918x10 9 2 997924562x108 1 3806226x10 23 6 6260755x10 34 91 e or escp 1 log2 e log10 e In 2 In 10 T Qn T 2 T 4 1 n 2 n 2 n J2 J172 Number of degrees per radian equal to 180 7 Charge of electron in coulombs Speed of light in vacuum in meters second Boltzman s constant in joules Kelvin Planck s constant in joules times seconds Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Constant Name Value Description P_EPSO 8 85418792394420013968x10 Permittivity of vacuum in farads meter P UO xX 4 0x1077 Permeability of vacuum in henrys meter P CELSIUSO 273 15 Zero Celsius in Kelvin User Defined Functions The user defined function capability allows you to build upon the provided set of built in mathematical and trigonometric functions You can write your own functions and call these functions from within any expression The Spectre function syntax resembles that of C or the SpectreHDL language Defining the Function The following is a simple example of defining a function with arg
106. 294 suppressing 295 method parameter 142 euler setting 144 gear2 setting 144 gear2only setting 144 setting to correct accuracy problems 299 trap setting 144 trapgear2 integration method parameter 145 traponly setting 144 minimum timestep used fixing warning 281 mismatch block 173 mismatch correlation statement 177 missing diode would be forward biased warning message 279 mixed signal simulation 23 MMF 76 mod parameter 161 model definition fourier 154 model binning rules 111 model scaling factor changing with alter statement 189 266 model statement 31 examples 32 71 formatting 71 January 2004 inline 103 using 70 modeling identical components in parallel 65 74 identical subcircuits in parallel 65 multidisciplinary 76 N ports 120 parasitics in inline subcircuits 100 process using inline subcircuits 104 models as info statement parameter 203 233 charge conservation of 17 formatting for multiple components 64 selecting automatically 108 use of expressions in 72 Monte Carlo analysis brief description of 134 characterization 178 examples 172 modeling 178 parameters table of 166 performing 164 specifying statistics 177 specifying the first iteration number 171 MOS models advantages of Spectre version 17 MOSO model brief description 17 multidisciplinary modeling 76 multiple analyses example in netlist 112 multiple components creating models for 70 multiplication factor 65 N n terminal
107. 2e 15 ends begin top level circuit definition xno21 1 90 no2 xno22 2 1 no2 xno23 3 2 no2 xno24 4 3 no2 xno25 5 4 no2 xno26 6 5 no2 xno27 7 6 no2 xno28 8 7 no2 xno29 9 8 no2 xno210 10 9 no2 xno211 11 10 no2 xno212 12 11 no2 xno213 13 12 no2 xno214 14 13 no2 January 2004 307 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits xno215 15 14 no2 xno216 116 15 no2 xno217 90 16 no2 Next couple of lines sets variables for vdd and vss parameters vdd S1 23 3 parameters vss S1 20 0 vdd I1 vdd gnd vsource dc vdd S1 vss Il vss gnd vsource dc vss S1 Next line initializes nodes within ring ic 2 20 4 20 6 20 8 20 10 20 include q35d4h5 modsp section tt Analysis tempOption options temp 25 tt tran tran step 0 010n stop 35n Ss alter altergroup include q35d4h5 modsp section ss parameters vdd S1 23 0 alterTempTo100 alter param temp value 100 ss tran tran step 0 010n stop 35n Ff alter altergroup include q35d4h5 modsp section ff parameters vdd S1 23 3 alterTempTo0 alter param temp value 0 Ff tran tran step 0 010n stop 35n Ring Oscillator Spectre Deck for Three Input NOR Ring with No Fanouts nor3_ring sp This example uses Spectre syntax Ring oscillator spectre deck for 3 Input NOR ring with no fanouts simulator lang spectre global 0 gnd vdd vss aliasGnd gnd 0 vsource type dc dc
108. 3 3 parameters vss S1 20 0 vdd I1 vdd gnd vsource dc vdd S1 vss Il vss gnd vsource dc vss S1 Set initial conditions ic 2 0 420 6 20 8 20 1020 Next line makes the call to the model NOTE The user may utilize the lib syntax with Spectre s spp command line option if they are using Spectre 4 43 or greater There is also a Spectre native syntax for equivalent functionality It is shown in q35d4h5 modsp include q35d4h5 modsp section tt January 2004 303 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits Analysis Statement tempOption options temp 25 typ_tran tran step 0 010n stop 35n alter_ss altergroup include q35d4h5 modsp section ss parameters vdd S1 23 0 alterTempTo100 alter param temp value 100 ss_tran tran step 0 010n stop 35n alter_ff altergroup include q35d4h5 modsp section ff parameters vdd S1 23 3 alterTempTo0O alter param temp value 0 ff_tran tran step 0 010n stop 35n Ring Oscillator Spectre Deck for Two Input NAND Ring with No Fanouts nand2_ring sp This example uses Spectre syntax Ring oscillator Spectre deck for 2 Input NAND ring with no fanouts simulator lang spectre global 0 gnd vdd vss aliasGnd gnd 0 vsource type dc dc 0 Spectre options to be used SetOptionl options iabstol 1 00n audit full MyAcctl info what inst extremes yes MyAcct2 info what models extremes yes MyAcct3
109. 40 85 Gamma real imag 0 348552 0 348552 0 348552 0 348552 0 348552 63566e 16 3 63566e 16 3 63566e 16 3 63566e 16 3 63566e 16 0 666667 0 666667 0 666667 446126 446126 4 446126 37504 37504 37504 37504 4 4 4 54 Rn 4 4 4 4 The following is an example of a noise co relation matrix noiseformat freq T 2 3 00000000e 09 00000000e 09 00000000e 09 00000000e 09 00000000e 09 CNET 0 344025 344025 344025 344025 344025 Touchstone Format A Touchstone file contains CY2 T 0 0 00632498 00632498 00632498 00632498 00632498 CYL 2 0 00632498 00632498 00632498 00632498 00632498 88929 88929 88929 88929 88929 CY2 2 0 0259336 0 0259336 0 0259336 0 0259336 0 0259336 46126 QUO Oc Qe Q 0 0 0 0466097 0466097 0466097 0466097 0922889 0922889 0922889 0922889 m A header consisting of a comment line starting with an exclamation mark m An option line Data lines January 2004 124 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features The syntax for the option line is where frequency units parameter format frequency units parameters format R n Delimiter The frequency unit Valid values GHz MHz KHz Hz Default value GHz Parameter typ
110. 454 ad EESTI EFAN LER EREERE RA 69 Mo del Stat ments 1 250 doi be EG o Io bd Oa d doe o ado dX Prag ACE ERE 70 Formatting the model Statement 0 0 eee eee 71 Examples of model Statements 3 o xe RERY Iu waded dee EXE RE 71 Basic model Statement Rules esos dcos donde roS Rs veuve Dr pix a 72 Input Data from Multiple Files lelsllllRRMVRh 72 Formatting the include Statement 0 eee 72 Rules for Using the include Statement 0 0 cc ccc eee 73 Example of include Statement Use 1 ee 74 Reading Piecewise Linear PWL Vector Values from a File 74 Using Fibra Statettietiis 45 3 52 2 t CK tees SE eae Bees EC edd 75 Multidisciplinary Modeling 153 4 242 iret te a ara cC Tc eo re Ra MD REDE Ra 76 Setting Tolerances with the quantity Statement ssun 76 Inherited Connections oie sane Roe ed te Ke ed eng ae AA ip pa e a 78 5 Parameter Specification and Modeling Features 79 Instance Component or Analysis Parameters 6 6 eee 80 Types ot Parameter Values 439 3c 4 o ee de oce d n cde e a Tc o EO 80 Parameter DIImeresloti xu 9 o Ded ua CREER IE eate dd dris Ra a d d 80 FaramelerBanges sieisen n e katie aor we ufone batis ori aae px eee ers dc eara 81 Helpon Parameters 4 ux id ig tana vec ne Me RERBA bsec edid 82 Scaling Numerical Literals 55222 124b bath de hie edad ke he ke EMG 83 Parameters Statement usto 6 ORS hosce da
111. 5 05 i5 b2 cell Q6 06 i6 b2 cell Q7 07 i7 b2 cel Transmission lines TLil 10 gnd il gnd tline len 185u 2z0 96 vel 0 36 TLi2 il gnd i2 gnd tline len2675u z0 96 vel 0 36 TLi3 12 gnd i3 gnd tline len 675u z0 96 vel 0 36 TLi4 i13 gnd i4 gnd tline len 675u z0 96 vel 0 36 TLi5 i4 gnd i5 gnd tline len 2675u z0 96 vel 0 36 TLi6 i5 gnd i6 gnd tline len 2675u z0 96 vel 0 36 TLi7 i6 gnd i7 gnd tline len 2675u z0 96 vel 0 36 TLi8 i7 gnd i8 gnd tline len 340u z0 96 vel 0 36 January 2004 95 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features TLol TLo2 TLo3 TLo4 LOS TLo6 Lo7 rLo8 1 1 1 3 o0 ol o2 03 o4 o5 o6 o7 gnd gnd gnd gnd gnd gnd gnd gnd Bias network drain bias Ldd vdd R1 00 C1 b1 gate 2 bias R2 b1 R3 b2 C2 b2 gate 1 bias R4 i8 R5 b3 c3 b3 ends stage o0 b1 gnd b2 gnd gnd b3 gnd gnd Two stage amplifier P1 in Cin in X1 inl Cmid out X2 in2 Cout out P2 out T 2 Power Supply Vpos vdd gnd vsource dc 5 Analyses OpPoint dc gnd inl outil in2 out2 out gn ol gnd tline len 360u o2 gnd tline len 750u o3 gnd tline len 750u o4 gnd tline len 750u o5 gnd tline len 750u o6 gnd tline len 750u o7 gnd tline len 750u o8 gnd tline len 220u inductor l 1u resistor r 50 capacitor c 9p re
112. 8 pch w 10u 1 10u ad 0 3n as 0 3n pd 20u ps 20u m5 3 7 9 9 nch w 38u 1 10u ad 0 3n as 0 3n pd 40u ps 40u m6 6 5 8 8 pch w 344u 1 10u ad 1 3n as 1 3n pd 350u ps 350u m7 6 7 9 9 nch w 652u 1 10u ad 2 3n as 2 3n pd 660u ps 660u m8 7 7 9 9 nch w 38u 1 10u ad 0 3n as 0 3n pd 40u ps 40u cc 5 6 4 4p ibias 8 7 8 8u ends opamp Opamp Circuit 2 opamp1 cir This example uses Spectre s SPICE syntax subckt opamp 12 6 8 9 ml 4 2 3 3 nch w 20u 1 0 5u ad 0 3n as 0 3n pd 50u ps 50u m2 5 1 3 3 nch w 20u 1 0 5u ad 0 3n as 0 3n pd 50u ps 50u m3 4 4 8 8 pch w 20u 1 0 5u ad 0 3n as 0 3n pd 20u ps 20u m4 5 4 8 8 pch w 20u 1 0 5u ad 0 3n as 0 3n pd 20u ps 20u m5 3 7 9 9 nch w 20u 1 0 5u ad 0 3n as 0 3n pd 40u ps 40u m6 6 5 8 8 pch w 20u 1 0 5u ad 1 3n as 1 3n pd 350u ps 350u m7 6 7 9 9 nch w 20u 1 0 5u ad 2 3n as 2 3n pd 660u ps 660u m8 7 7 9 9 nch w 20u 1 0 5u ad 0 3n as 0 3n pd 40u ps 40u cc 5 6 4 4p ibias 8 7 8 8u ends opamp Original Open Loop Opamp openloop sp Allen amp Holmberg p 438 Original Open Loop OpAmp Configuration vinp 10 dc 0 ac 1 0 vdd 4 0 dc 5 0 vss 0 5 dc 5 0 vinm 2 0 dc 0 cl3 0 20p x11234 5 opamp Bring in opamp subcircuit include opamp cir Bring in models here model nch bsim3v3 model pch bsim3v3 type p Op simulator lang spectre tf 3 0 xf save lvlpub nestlvl 1 start 1 stop 1K dec 20 simulator lang spice dc vinp 0 005 0 005 100u print dc v 3 January 2004
113. BEGIN SEG 1000000000 4000000000 10 SEG LIST END specifies that the frequency range is from 1000000000 to 4000000000 with intervals of 10 S Parameter File Format Translator The S parameter data file format translator spt r is a separate program from the Spectre simulator Since the Spectre circuit simulator now reads the Touchstone and CITIfile formats directly you need to use the translator only if you have it built into your design flow Note The translator does not support the MHARM HPMNS or Linear Neutral Model LNM formats any more Command Arguments The following is a synopsis of the command line and arguments used to run the translator January 2004 128 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features sptr i inputFormat o outputFormat f FreqScale V version format paramFormat inputFile outputFile Option Description i inputFormat Input file format Valid values spectre touchstone citifile Default value spectre o outputFormat Output file format Valid values spectre and touchstone Default value spectre f FreqScale If frequency scale is not explicitly given in the input file then TrueFreq GivenFreq freqscale Default value 1 0 for Spectre and CITIfile formats 1 0e09 for touchstone format V version Prints the version information format Parameter data format of the output file para
114. Begin top level circuit definition xno31 1 90 no3 xno32 2 1 no3 xno33 32 no3 xno34 14 3 no3 xno35 5 4 no3 xno36 6 5 no3 xno37 7 6 no3 xno38 8 7 no3 xno39 09 8 no3 xno310 10 9 no3 xno311 11 10 no3 xno312 12 11 no3 xno313 13 12 no3 xno314 14 13 no3 xno315 15 14 no3 xno316 16 15 no3 xno317 90 16 no3 Next couple of lines sets variables for vdd and vss parameters vdd S1 23 3 parameters vss S1 0 0 vdd I1 vdd gnd vsource dc vdd S1 vss Il vss gnd vsource dc vss S1 Next line initializes nodes within ring ic 220 420 6 20 8 20 1020 include q35d4h5 modsp section tt Analysis tempOption options temp 25 typ tran tran step 0 010n stop 35n alter ss altergroup include q35d4h5 modsp section ss parameters vdd S1 23 0 alterTempTo100 alter param temp value 100 ss_tran tran step 0 010n stop 35n alter_ff altergroup include q35d4hn5 modsp section ff parameters vdd S1 3 3 alterTempTo0 alter param temp value 0 ff_tran tran step 0 010n stop 35n January 2004 309 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits Opamp Circuit opamp cir This example uses Spectre s SPICE syntax subckt opamp 1 2 6 8 9 ml 4 2 3 3 nch w 43u 1 10u ad 0 3n as 0 3n pd 50u ps 50u m2 5 1 3 3 nch w 43u 1 10u ad 0 3n as 0 3n pd 50u ps 50u m3 4 4 8 8 pch w 10u 1 10u ad 0 3n as 0 3n pd 20u ps 20u m4 5 4 8
115. C P_CELSIUSO P_EPSOP_H P_K P_Q P_UO abs acos acosh altergroup asin asinh atan atan2 atanh ceil correlate cos cosh else end ends exp export floor for function global hypot Ie if inline int library local log log10 march max min model nodeset parameters paramset plot January 2004 60 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists pow print pwr real return save sens sin sinh sqrt statistics subckt tan tanh to truncate vary Multiple Namespace From release 5 0 32 onwards you need not have unique names for device instances models nets subcircuit parameters enumerated named values for parameters and netlist parameters that are expressions Consider the following example simulator lang spectre parameters cl 1p c2 2p cl0 cl c2 parameters res 10k res c10 0 resistor r res c10 c10 0 capacitor c c10 run dc spectre2 options currents all res is used as a parameter and instance name c10 is used as a node instance and parameter name The Spectre circuit simulator can now read this netlist The Spectre circuit simulator can resolve ambiguous statements as shown in the example below parameters xyz 1 xyz 1 0 vsource dc xyz h1 3 0 ccvs probe xyz rm xyz The Spectre circuit simulator assigns the instance xyz to probe and the parameter xyz to rm In the example below vec vec 0 vsource dc 1 Save VCC the Spectre circuit simulator saves the node vcc rather than the insta
116. I configuration file The configuration file specified by the value of the CMI The file SHOME cmiconfig if it exists _CONFIG environment variable The CMI configuration file specified in the cmiconfig argument January 2004 314 Product Version 5 0 Spectre Circuit Simulator User Guide Dynamic Loading Each configuration file modifies the previous configuration This default includes all components for backward compatibility Cadence default The user can specify site specific CMI configuration through CMI CONFIG this environment variable l The device developer can use this file for customizing the CMI cmiconfig configuration Y The user can use this command line argument to customize cmiconfig the CMI configuration Configuration File Example This section contains examples that show how configuration files can be used to customize the list of shared objects that the Spectre circuit simulator loads at run time The default configuration file includes libnortel so libstmodels so libphilips so and libsiemens so If you need only the ST models you can create a configuration file called 3ite cmi config that loads only 1ibstmodels so by unloading the other three shared objects default search path is CDS_ROOT tools spectre lib cmi M only libstmodels for this site this file is called site cmi config unload libnortel so unload libphilips so unload libsiemens so
117. P 0 5 7 7 3469e 09 0 RHP 70 5 8 7 3469e 09 0 RHP 0 5 9 1 0061e 09 0 0 5 10 1 0061e 09 0 0 5 11 1 0235e 09 0 0 5 Other Analyses sens fourier dcmatch and stb There are four analyses in this category sens fourier dcmatch and stb January 2004 150 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Sensitivity Analysis You can supplement the analysis information you automatically receive with the AC and DC analyses by placing sens statements in the netlist Output for the sens command is sent to the rawfile or to an ASCII file that you can specify with the sensdata lt filename gt option of the spect re command B If youset senstype partial Spectre calculates partial sensitivity This determines the sensitivity of output variables to input design parameters Results are expressed as a ratio of the change in an output analysis variable to the change in an input design parameter For example if V is the output value and P is the input design parameter sensitivity is computed as follows dV Sy p gp m If you set senstype normalized Spectre calculates normalized sensitivity which removes the dependence of results on the magnitude of the output variable and input design parameters Normalized sensitivity is computed as follows S PdV V P VaP AV su Sy p Pp if V 0 VP yap TS When both P and V are zero partial sensitivity is used Formatting the sens Command You format the
118. PICE Reader will treat all of these characters as literals m The Spectre simulator does not require an end statement it assumes the end of the input file is the end of the input statements The ena statement if included in a SPICE netlist is treated like the end of file and the SPICE Reader does not read beyond the end Reading SPICE and Spectre Files When the Spectre simulator opens a netlist file the simulator determines whether the file is a SPICE or Spectre netlist and interprets it accordingly This is true regardless of whether the file is the main netlist or an included netlist The Spectre simulator recognizes Spectre files because they start with the line simulator lang spectre or the filename ends in the Spectre circuit simulator extension of scs Files that do not start with this line or end in the scs extension are taken to be SPICE files Thus SPICE files do not need to be modified to work with the Spectre simulator as the SPICE Reader will automatically map them correctly to Spectre input The scs extension allows users to write netlists included files and library files using only the Spectre Netlist Language without having to switch from SPICE mode To learn more about controlling the input language see General Input Compatibility on page 51 January 2004 50 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility Scope of the Compatibility Many current variants of SPICE have
119. Process parameter correlation statements The following is the syntax of the process parameter correlation statement correlate param list of parameters cc value This allows you to specify a correlation coefficient between multiple process parameters You can specify multiple process parameter correlation statements in a statistics block to build a matrix of process parameter correlations During a Monte Carlo analysis process parameter values are randomly generated according to the specified distributions and correlations m Instance or mismatch correlation statements matched devices The following is the syntax of the instance or mismatch correlation statement correlate dev list of subckt instances param list of parameters cc value where the device or subcircuit instances to be matched are listed in 22st of subckt instances and list of parameters specifies exactly which parameters with January 2004 177 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses mismatch variations are to be correlated Use the instance mismatch correlation statement to specify correlations for particular subcircuit instances If a subcircuit contains a device you can effectively use the instance correlation statements to specify that certain devices are correlated matched and give the correlation coefficient You can optionally specify exactly which parameters are to be correlated by giving a list of parameters each of which mu
120. RAN timeSweep tran Note These names have special significance to the Cadence analog design environment If you request multiple unnamed analyses using SPICE syntax the names are constructed by appending a sequence integer to the name of the analysis type and further adding the dot extension that is appropriate for the analysis For example multiple AC analyses would generate this sequence of files frequencySweep ac ac2 ac ac3 ac ac4 ac and so on Specifying Your Own Names for Directories You might want to specify a name for an output directory that is different from the name of your netlist For example if you use the same netlist in more than one simulation you probably want different names for the output files You can specify names in two ways m You can specify your directory name from the command line or in an environment variable with the spect re command raw option For example if you want your output directory to be named test circuit raw you start your simulation as follows spectr raw test circuit inputFilename m You can set the rawfile parameter of the opt ions statement For example the following opt ions statement creates an output directory named test circuit raw Setup options rawfile test circuit Note The Spectre simulator has some additional features that help you manage data by letting you systematically specify or modify filenames For more information about these features see Chapter 12 M
121. Reference m Advanced analyses Q Sweep analysis sweep Sweeps a parameter executing a list of analyses or multiple analyses for each value of the parameter The sweeps can be linear or logarithmic Swept parameters return to their original values after the analysis Sweep statements can be nested For more information about the sweep analysis see Sweep Analysis on page 159 Q Monte Carlo analysis montecarlo Varies netlist parameters according to specified distributions and correlations runs nested child analyses and extracts specified circuit performance measurements You can apply both process and device to device mismatch variations and tag device instances as correlated or matched pairs Use the Cadence analog circuit design environment Calculator expressions to measure the circuit performance You can use the analog design environment graphics tools to plot scalar performance data such as slew rates and bandwidths as a histogram or scattergram You can also display waveform data as cloud family plots For more information about the Monte Carlo analysis see Monte Carlo Analysis on page 164 For more information about using the Monte Carlo analysis with the analog design environment see the Advanced Analysis Tools User Guide B Hot electron degradation analysis Lets you control the age of the circuit when simulating hot electron degradation For more information about the hot electron degradation a
122. S 301 Spectre BSIM Sv3 MOGdeL 51 pix esu tir rara re der pet An raa re EO ren a ER E 302 Ring Oscillator Spectre Deck for Inverter Ring with No Fanouts inverter ring sp 302 Ring Oscillator Spectre Deck for Two Input NAND Ring with No Fanouts nand2 ring sp 304 Ring Oscillator Spectre Deck for Three Input NAND Ring with No Fanouts nand3_ring sp 305 Ring Oscillator Spectre Deck for Two Input NOR Ring with No Fanouts nor2 ring sp 307 Ring Oscillator Spectre Deck for Three Input NOR Ring with No Fanouts nor3 ring sp 308 Opamp Circuit TODalTID IP 259 wp etek thet aee e e Roxette dud nay eck t ia cu 310 Opamp Circuit 2 opamp1 cir dsrnera ee enero e PLA e EDU PEE E P acess 310 Original Open Loop Opamp openloop sp 00 ce ee 310 Modified Open Loop Opamp openloop1 sp sees 311 Example Model Directory q35d4h5 modsp ssellssss 311 B Dynamic LOAGING cere EEEE 312 Contig rati on Fileas dioe re iE erg ch ole oe Per at Qo A SA ann apenas indicado 312 Configuration File Format usce esci v dla o ED eode RR a hh ee 312 Precedence for the CMI Configuration File lslslllssss 314 Configuration File Example 2 ui bs test eens eR RR A LC IEEE 315 CMILVGISIONING 2553 12 4 nE aniani aea es COEUR URL RR beeen ER ee est quu dia 316 S E TERES 317 January 2004 12 Product Version 5 0 Spectre Circuit Simulato
123. SF ASCII nutbin Nutmeg binary SPICE3 standard output nutascii Nutmeg ASCII SPICES standard output sst2 Cadence Signal Scan format January 2004 234 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options In the Nutmeg format the Spectre simulator writes output data to a raw file For further information about the Nutmeg format consult the Nutmeg Users Manual available from the University of California Berkeley In the other formats the Spectre simulator creates and writes output to a directory of files The Spectre simulator overwrites existing files and directories If the Spectre simulator cannot open files or create the necessary directories it stops Defining Output File Formats You can redefine the output file format in two ways BM With a spectre command you type from the command line or place in an environment variable m With an options statement you put in the netlist You use the opt ions statement in the netlist to override an environment default setting and you use the spect re command at run time to override any settings in the netlist The parameter values you enter are the same for either method Example Using the spectre Command The following example shows you how to set format options with the spect re command This statement which you type at the command line or place in an environment variable directs the Spectre simulator to run a simulation on a circuit named circ
124. SS VSS nmos w 122 4u 1 7 6u M10 9 12 VSS VSS nmos w 122 4u 1 7 6u common mode feedback amplifier M11 10 nout vss vss nmos w 12 4u 1 62 6u M12 10 pout vss vss nmos w 12 4u 1 62 6u M13a 11 gnd vss vss nmos w 12 4u 1 62 6u M13b 11 gnd vss vss nmos w 12 4u 1 62 6u M14 10 10 vdd vdd pmos w 52 4u 1 7 6u M15 11 10 vdd vdd pmos w 52 4u 1 7 6u Cci nout 11 capacitor c l1p Cc2 pout 11 capacitor c lp bias network M16 12 12 VSS vss nmos w 22 4u 1 11 6u M17 21 12 VSS vss nmos w 22 4u 1 11 6u M19 13 13 14 VSS nmos w 22 4u 1 21 6u M20 13 21 16 vdd pmos w 52 4u 1 7 6u M21 21 16 17 vdd pmos w 26 4u l 11 6u M22 16 16 E34 vdd pmos w 26 4u 1 11 6u D1 15 vss dnp area 400n D2 14 1 5 dnp area 400n D3 18 17 dnp area 400n D4 vdd 18 dnp area 400n Ib gnd 12 isource dc 10u ends opamp The following file cmos mod contains the models and uses the library and section statements to bin models into various process corners See Process File on page 115 for a more sophisticated example which also includes automatic model selection cmos mod Spectre MOSFET model parameters CMOS process Empirical parameters best typical and worst cases January 2004 114 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Z4 simulator lang spectre library cmos mod section fast MOSFETS and DIODES for process corner FAST model nmos mos3 t
125. Spectre Circuit Simulator User Guide Product Version 5 0 January 2004 1990 2003 Cadence Design Systems Inc All rights reserved Printed in the United States of America Cadence Design Systems Inc 555 River Oaks Parkway San Jose CA 95134 USA Trademarks Trademarks and service marks of Cadence Design Systems Inc Cadence contained in this document are attributed to Cadence with the appropriate symbol For queries regarding Cadence s trademarks contact the corporate legal department at the address shown above or call 800 862 4522 All other trademarks are the property of their respective holders Restricted Print Permission This publication is protected by copyright and any unauthorized use of this publication may violate copyright trademark and other laws Except as specified in this permission statement this publication may not be copied reproduced modified published uploaded posted transmitted or distributed in any way without prior written permission from Cadence This statement grants you permission to print one 1 hard copy of this publication subject to the following conditions 1 The publication may be used solely for personal informational and noncommercial purposes 2 The publication may not be modified in any way 3 Any copy of the publication or portion thereof must include all original copyright trademark and other proprietary notices and this permission statement and 4 Cadence reserves the righ
126. Statements on page 66 Control Statements on page 68 Model Statements on page 70 Input Data from Multiple Files on page 72 Multidisciplinary Modeling on page 76 Inherited Connections on page 78 January 2004 57 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Netlist Statements A Spectre circuit simulator netlist describes the structure of circuits and subcircuits by listing components the nodes that the components are connected to the parameter values that are used to customize the components and the analyses that you want to run on the circuit You can use SpectreHDL or Verilog A to describe the behavior of new components that you can use in a netlist like built in components You can also define new components as a collection of existing components by using subcircuits A netlist consists of four types of statements m Instance Statements on page 62 m Analysis Statements on page 66 W Control Statements on page 68 m Model Statements on page 70 Before you can create statements for a Spectre netlist you must learn some basic syntax rules of the Spectre Netlist Language Netlist Conventions These are the netlist conventions followed by the Spectre simulator Associated Reference Direction The reference direction for the voltage is positive when the voltage of the terminal is higher than the voltage of the terminal A positive current arrives through the terminal and leaves
127. The save Parameter Options 0 0 20 cee eee 229 Saving Subcircuit Signals 33 veri Yee pr pee ur oe ea ea qued EXE RE 230 Saving Groups of Currents uut cet echt ot ERU ee ea Rust ub dede S pura inda 230 Savildq b AHBEVatiables i v aerea acr rk Ea trae ead bee ef 232 Listing Parameter Values as Output n nnana eee 232 Specifying the Parameters You Want to Save 1 ees 233 Specifying the Output Destination mii been te dee ee Oh ee ees 233 Examples of the info Statement 0 2 0 2 eee 234 Preparing Output for Viewing ui voe kx ma ede x RR Rx ee hoe E RE alee ea RUN OR 234 Output Formats Supported by the Spectre Simulator 234 Defining OutputEle EOFmals gt 2 2 59 1 ceat are premo esp po erra at ea fe QE C DEA 235 ACCESSING Output Files 5 e uri b QS Ge eee Ser Pui Mh oad Re See eee d 235 How the Spectre Simulator Creates Names for Output Directories and Files 236 Filenames for SPICE Input Files 0 0 0 2 eee 238 Specifying Your Own Names for Directories 0 cee ees 238 9 Fiorbinirig d Simulation sooo oorr err DRM PI IP PVRSNEIBSUA 239 Starting Simulations 5 x9 9 259 by x d adita P LR REESE a Cx ADIRE ee Sonidos 240 Specifying Simulation Options ixi on oen ICE OR ae Ide S eredi bis 240 Using License Queuing n4 ez bbb eec ERR i Eae xd ied iu 241 Determining Whether a Simulation Was Successful 241 Checking Simulation Status 5539 ed ones ce a
128. The total node capacitance at nodes 1 2 and 3 is represented by the rows n1 n1 n2 n2 and n3 n3 respectively There is no entry for n3 n2 which means there is no capacitance between these two nodes Table 7 1 is sorted by value The rows are first grouped according to node names the rows with the same From Node are kept in a group The row depicting the total capacitance at each node is always displayed first in the group and the row displaying the node to ground capacitance is second The remaining rows within each group are sorted in descending order of the Sum value Note If the threshold is set to 2p thresh 2p the row n1 n3 will not be printed because the capacitance between the nodes is less than the threshold The row n1 0 will be printed since the node to ground capacitance is always printed The group n3 n3 n3 0 and n3 n1 will not be printed because the total node capacitance at node 3 n3 n3 is less than the threshold If you sort the table by name sort name it would look as follows January 2004 207 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Table 7 2 Node Capacitance Table Sorted by Name plimi Fixed 3 5p Variable 1p Sum 4 5p n1 0 Fixed 1p Variable 0 Sum 1p nil n2 Fixed 2p Variable 1p Sum 3p ni n3 Fixed 0 5p Variable 0 Sum 0 5p n2 n2 Fixed 2p Variable 3p Sum 5p n2 0 Fixed 0 Variable 2p Sum 2p n2 nl Fixed 2p Variable 1p Sum 3p n3 n3 Fixed 1 5p Vari
129. Warning from spectre in indab 7 during circuit read in na300 scs 27 c11 Encountered statement in Spectre format while in Spice language mode This will not be supported in a future release The Spectre parser is dual mode and accepts both the Spectre native language and documented Spice2G6 The default for the Spectre simulator is SPICE If you include a file January 2004 281 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting written in Spectre native syntax you must either specify simulator Lang spectre or name the file with a scs suffix After Spectre processes the file it reverts to the default mode It is illegal to include Spectre syntax in the SPICE mode or vice versa For the MOS instance line given below M1 12 0 0 NCH W 10u L 2u Spectre displays the following warning ml Encountered statement in Spectre format while in SPICE language mode This will not be supported in a future release Since the instance statement is valid in both languages you can ignore this warning Topology Messages Notice from spectre during topology check Only one connection to the following node 4 No DC path from node 4 to ground Gmin installed to provide path The Spectre topology checker identifies floating nodes and automatically inserts a gmin resistor 1e12 Ohms to prevent a non isolated solution The Spectre simulator then displays a message telling you what
130. You can use the default settings to specify alternative conditions for running the Spectre simulator Suppose you create the following environment variables setenv SPECTRE DEFAULTS param range lmts log C r o E setenv SPECSIM DEFAULTS param corner lmts log C r log f psfbin January 2004 245 Product Version 5 0 Spectre Circuit Simulator User Guide Running a Simulation If spectre and specsim are both links to the Spectre executable and you run the executable as spect re the Spectre simulator does the following m Reads the file cange 1mts for the parameter limits W Directs all messages to the screen and to a log file named after the circuit file with o appended see Chapter 12 Managing Files for more information about specifying filenames m Runs the C preprocessor Running the executable as specsim causes the Spectre simulator to select a different set of defaults and to do the following m Read the range limits from the file corner lmts m Direct log messages to a file named after the circuit file with log appended the log specification suppresses the log output to the screen W Format output files in binary parameter storage format PSF References for Additional Information about Specific Defaults In some cases you need to consult other sections of this book before you can set defaults B f you want to set default limits for warning messages about parameter values cons
131. a voltage source in the ciruit netlist dcmm1 is the name of the analysis dcmatch is a keyword indicating the dc mismatch analysis and the parameter settings oprobe vd and port i 1 specify that the output current is measured at the first port of vd Device mismatch contributions less than 16 396 of the maximum contribution of all mismatch devices to the output are not reported as specified by the paramter mth The mismatch that is the equivalent mismatch current sources in parallel to all the devices that use model n1 is modeled by the model parameters mvtw1 mvtwl2 mvtO0 mbewl and mbeO dcmml dcmatch mth 1e 3 oprobe vd porti 1 model nl bsim3v3 type n mvtwl 6 15e 9 mvtwl2 2 5e 12 mvt0 0 0 mbewl 16 5e 9 mbe0 0 0 The output of the analysis is displayed on the scree logfile DC Device Matching Analysis mismatchl at vd Local Variation 3 sigma random device variation sigmaOut sigmaVth sigmaBeta sigmaVg sigmalds 13 8 uA 2 21 mV 357 m 2 26 mV 1 71 mp6 6 99 uA 1 63 mV 269 m 1 68 mV 1 08 m01 2 71 uA d dsbUumv 187 m 1 16 mV 648 m m02 999 nA 769 uV 131 m 807 uV 428 m mO4x4 4 999 nA 769 uV 131 m 807 uV 428 m m04x4 3 January 2004 155 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses 999 nA 769 uV 131 m 807 uV 428 m m04x4 2 999 nA 769 uV 131 m 807 uV 428 m m04x4 1 999 nA 769 uV 131 m 807 uV 428 m m04 718 nA 1 09 mV 185 m 1 15 mV 599 m m40x04 520 nA 1 55 mV 263 m 1 63 mV 835
132. able 0 Sum 1 5p n3 n0 Fixed 1p Variable 0 Sum 1p nom Fixed 0 5p Variable 0 Sum 0 5p In this case the From Node To Node column is sorted alpha numerically However the row depicting the total capacitance at each node is always displayed first in the group and the row displaying the node to ground capacitance is second The options Statement To enter initial parameters for your simulation that you do not specify in your environment variables or on your command line you use the options statement You can control parameters in a number of areas with the opt ions statement Parameters that specify tolerances for accuracy Parameters that control temperature Parameters that select output data Parameters that help solve convergence difficulties m Parameters that control error handling and annotation For a complete list of the parameters you can set with the opt ions statement consult the Spectre online help spectre h January 2004 208 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements options Statement Format The options statement format is Name options parameter value where Name The unique name you give to the options statement The Spectre simulator uses this name to identify this statement in error or annotation messages options Primitive name for this control statement Parameter value Value you choose for the parameter You can enter any number of parameter specifications wit
133. about specific parameters available with the pa ramt est component see the parameter listings in the Spectre online help spectre h Inline Subcircuits An inline subcircuit is a special case where one of the instantiated devices or models within the subcircuit does not get its full hierarchical name but inherits the subcircuit call name The inline subcircuit is called in the same manner as a regular subcircuit You format inline subcircuit definitions as follows inline subckt SubcircuitName nodel nodeN Depending on the use model the body of the inline subcircuit typically contains one of the following m Multiple device instances one of which is the inline component m Multiple device instances one of which is the inline component and one or more parameterized models B A single inline device instance and a parameterized model to which the device instance refers January 2004 99 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features m Only asingle parameterized model The inline component is denoted by giving it the same name as the inline subcircuit itself When the subcircuit is flattened as shown in the following section the inline component does not acquire a hierarchical name such as x1 M1 but rather acquires the name of the subcircuit call itself x1 Any noninline components in the subcircuit acquire the regular hierarchical name just as if the concept o
134. adence range limits 284 shell status variable 241 sigglobal relative error parameter 144 234 142 Signal Scan output format signals defined 223 simulation checking status 241 following the progress of 33 improved accuracy 18 interrupting 242 introductory Spectre run 32 sample narration of progress 33 specifying options 240 starting 240 termination See terminations of Spectre 241 viewing output 34 simulation language use of in example netlist 30 simulator lang command default 54 singular Jacobian or matrix error message 276 skipping data points skipcount parameter 146 skipstart parameter 1 skipstop parameter 147 skipping time points example 147 explanation 146 soft limits definition 81 use of 20 source stepping 267 source as homotopy parameter option 267 span parameter 163 spalameler analysis sp brief description of 131 S parameter file format translator 128 S parameter files creating manually 121 db deg 121 db rad 121 formatting 121 generated by Spectre 121 A N N Product Version 5 0 Spectre Circuit Simulator User Guide mag deg 121 mag rad 121 reading example of nport statement 122 format of nport statement 122 real imag 121 special characters escaping 62 specify search path 313 specifying analyses 32 control statements 69 individual components 30 models for multiple components 31 percent codes 271 Spectre accuracy improvements 17 annotated netlist example 28 Capacit
135. ading SPICE Netlists on page 42 m Language Differences on page 48 W Scope of the Compatibility on page 51 January 2004 41 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility Reading SPICE Netlists Spectre provides the SPICE Reader to let you simulate existing SPICE netlists with Spectre While it is possible to gain access to many of Spectre s features with a SPICE netlist the Spectre syntax is a much more powerful language designed to give the Spectre user features beyond those provided by SPICE Whenever possible you are encouraged to take advantage of Spectre s native language When Spectre syntax is not an acceptable solution the SPICE Reader can be used to ensure access to as much of Spectre s capabilities as possible Running the SPICE Reader In order for Spectre to properly process a SPICE netlist the SPICE Reader must be enabled By default the SPICE Reader is disabled when you invoke Spectre Use the command spect respp rather than the spect re command to enable the SPICE Reader For example the following command invokes Spectre with the SPICE Reader for the input netlist amp sp spectrespp amp sp The Spice Reader runs on the top level netlist as well as on any included files that contain SPICE syntax The SPICE Reader converts the netlist to Spectre native syntax before it sends the design to the Spectre netlist reader From the 5 0 release any measure statements found in
136. alues of four parameters 1 w 1s and 1d If a parameter value satisfies a test condition one of three different warning messages is printed TooShort paramtest warnif l lt lum message Channel length for nmos must be greater than lu TooThin paramtest warnif w lum message Channel width for nmos must be greater than lu TooNarrow paramtest warnif ls lum warnif ld lt lum message Strip width for nmos must be greater than lu January 2004 293 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Controlling Program Generated Messages The Spectre simulator normally sends error warning and informational messages to the screen To prevent confusion the Spectre simulator limits the amount of material it sends to the screen You can however get a more complete printout of messages if you send the messages to a log file that you can generate with the spectre command orina SPECTRE_DEFAULTS environment variable Specifying Log File Options You can choose from among the following command line options log lt file gt The Spectre simulator sends all messages to a log file as well as printing to the screen You specify the name for the file You can use 1 as an abbreviation of 1og log file The Spectre simulator sends all messages to a log file but does not print to the screen You specify the name for the file You can use
137. alues specified For each iteration of the sweep the netlist parameters are set to the values specified by a row The values have to be numbers and the parameters names have to be defined in the input file netlist before they are used The paramset statement is allowed only in the top level of the input file The following is the syntax for the paramset statement Name paramset list of netlist parameters list of values foreach netlist parameter list of values foreach netlist parameter Here is an example of the paramset statement parameters pl 1 p2 2 p3 3 data paramset pl p2 p3 5 5 5 4 3 2 Combining the paramset statement with the sweep analysis allows you to sweep multiple parameters simultaneously for example power supply voltage and temperature January 2004 162 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Setting Sweep Limits For all analyses that support sweeping you specify the sweep limits with the parameters in the following table Parameter Value Comments Start Start of sweep value Default 0 start and stop are used stop End of sweep value together to specify sweep limits center Center value of sweep center and span are used span Span of sweep Default 0 together to specify sweep limits step Step size for linear sweeps step and lin are used to specify lin Number of steps for linear sweeps linear sweeps Default is 50 dec Number of points per decade
138. alysis pss brief description of 21 133 periodic transfer function analysis pxf brief description of 133 physical dimensions of components scaling 118 PID process identification number 241 use of 166 piecewise linear PWL vector values reading 74 piped files and percent codes 272 P N junction warnings 278 breakdown region 279 explosion region 278 missing diode would be forward biased 279 pnoise analysis brief description of 132 pointlocal relative error parameter 144 power in Watts 77 power supply rejection netlist example of measurement discussed 136 power saving 215 228 predefined netlist parameters 93 predefined percent code character 271 CMIVersion 270 N N January 2004 date 270 described 269 host name network na input circuit file name process ID 270 program starting time simulator name 271 substitution in 271 version string 271 predefined quantities 76 prepend path 313 previous solutions starting analyses from 258 prevoppoint parameter in analyses 258 printout to screen example 33 probe statement 215 227 probes setting in analyses 135 process block 173 process corners example 11 process file sample input file 115 process identification number PID 241 use of 166 process modeling using inline subcircuits 104 process parameter correlation statement 177 processparamfile parameter Monte Carlo analysis 168 processscalarfile parameter Monte Carlo analysis 168 profile file
139. alysis for future use m You can create a state file manually in a text editor Telling the Spectre Simulator to Create a State File You can instruct the Spectre simulator to create a state file from either the initial point or the final point in an analysis To write a state file from the initial point in an analysis use the write parameter To write a state file from the final point use the writefinal parameter Each of the following two examples writes a state file named ua741 dc The first example writes the state file from the initial point in the DC sweep and the second example writes the state file from the final point in the DC sweep Drift dc param temp start 0 stop 50 0 step 1 readns ua741 dc write ua741 dc January 2004 200 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Drift dc param temp start 0 stop 50 0 step 1 readns ua741 dc writefinal ua741 dc Creating a State File Manually The syntax for creating a state file in a text editor is simple Each line contains a signal name and a signal value Anything after a pound sign 4 is ignored as a comment The following is an example of a simple state file State file generated by Spectre from circuit file wilson during stepresponse at 5 39 38 PM jan 21 1992 1 588793510612534 2 1 17406247989272 3 14 9900516233357 pwr 15 Voip 9 9483766642647e 06 Reading State Files To read a state file as an i
140. amed device is possible only in a structural if statement that has both an if part and an else part m Both the if part and the else part must be either a simple one statement block or another structural i statement to which these same rules apply m Both the if part and the else part must evaluate to a single device instance whose instance name terminal list and type of primitive are identical Multiple references to the same named device are only possible if there can only ever be one single instance of this device after all expressions have been evaluated and each instance must be connected to the same nodes and represent the same device Examples of Conditional Instances The following two examples show how to use conditional instances Fully Differential CMOS Operational Amplifier This netlist describes and analyzes a CMOS operational amplifier and demonstrates several sophisticated uses of Spectre features The example includes top level netlist parameters model library section statements multiple analyses and configuring a test circuit with the alter statement The first file in the example is the main file for the circuit This file contains the test circuit and the analyses needed to measure the important characteristics of the amplifier The main file is followed by files that describe the amplifier and the various models that can be selected These additional files are placed in the netlist with include statements
141. ameter Specification and Modeling Features m You cannot leave a list of items empty m You can use expressions such as formulas to specify numbers within a vector When you use a vector of expressions each expression must be surrounded by parentheses coeff 0 A B C 0 5 m You can use subcircuit parameters within vectors Parameter Ranges Parameter ranges have hard limits and soft limits Hard limits are enforced by the Spectre simulator if you violate them the Spectre simulator issues an error and terminates You specify soft limits if you violate them the Spectre simulator issues a warning and continues Soft limits are used to define reasonable ranges for parameter values and can help find unreasonable values that are likely errors You can change soft limits which are defined in one or more files Use the param command line option to use the suggested parameter range limits You can specify limits for any scalar parameter that takes either a real number an integer or an enumeration To specify the limits of a parameter that takes enumerations use the indices or index values associated with the enumerations For example consider the region parameter of the bjt There are four possible regions see spectre h bjt BH off B fwd B rev B sat Each enumeration is assigned a number starting at 0 and counting up Thus B off 0 BH fwd 1 B rev 2 B sat 3 The specification bjt 3 lt region lt 1 indicates that a
142. ameters and their values This can be referred by a sweep analysis to sweep the set of parameters over the values specified For each iteration of the sweep the netlist parameters are set to the values specified by a row The values have to be numbers and the parameters names have to be defined in the input file netlist before they are used The paramset statement is allowed only in the top level of the input file January 2004 210 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements The syntax is Name paramset list of netlist parameters list of values foreach netlist parameter list of values foreach netlist parameter Here is an example of the paramset statement parameters pl 1 p2 2 p3 3 data paramset pl p2 p3 5 5 5 4 3 32 Combining the paramset statement with the sweep analysis allows you to sweep multiple parameters simultaneously for example power supply voltage and temperature The save Statement You can save signals for individual nodes and components or save groups of signals Saving Signals for Individual Nodes and Components You can include signals for individual nodes and components in the save list by placing save statements not to be confused with the save parameter in your netlist When you specify signals in a save statement the Spectre simulator sends these signals to the output raw file as long as the nest1v1 setting does not filter them In this sectio
143. ample 1 0M is interpreted as 10 in the SPICE mode but as 10 in the Spectre mode Parameters Statement In this section you will learn about the circuit and subcircuit parameters collectively known as netlist parameters as defined by the parameters statement January 2004 84 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Circuit and Subcircuit Parameters The Spectre Netlist Language allows real valued parameters to be defined and referenced in the netlist both at the top level scope and within subcircuit declarations run spectre h subckt for more details on parameters within subcircuits The format for defining parameters is as follows parameters param value param value Once defined you can use parameters freely in expressions The following are examples simulator lang spectre parameters pl 1 p2 2 declare some parameters rl 1 0 resistor r pl use a parameter value 1 r2 1 0 resistor r pl p2 use parameters in an expression value 3 xl sl p4 8 subckt sl is defined below pass in value 8 for p4 subckt sl parameters pl 4 p3 5 p4 6 note no p2 here pl redefined rl 1 0 resistor r pl local definition used value 4 r2 1 0 resistor r p2 inherit from parent top level value 2 r3 1 0 resistor r p3 use local definition value 5 r4 1 0 resistor r p4 use passed in value value 8 r5 1 0 resistor r pltp2 p3 use localtinhe
144. an therefore be specified in either format Below is an example of each Note that the valid parameter list does not change only the primitive name level designation and version type parameters Beginning with the 4 4 3 release the Spectre simulator is compatible with SPICE input language beyond documented SPICE2G6 Contact your local Cadence representative for more details SPICE BSIM 3v3 Model model bsim3v3 Berkeley Spice Compatibility Lmin 35 Lmax 20 Wmin 6 Wmax 20 model N1 NMOS tLevel 11 Tnom 27 0 Nch 2 498E 17 Tox 9E 09 Xj 1 00000E 07 Lint 9 36e 8 Wint 1 47e 7 VthO 6322 K1l 756 K2 3 83e 2 K3 2 612 Dvt0 2 812 Dvt1l 0 462 Dvt2 9 17e 2 N1x 3 52291E 08 WO 1 163e 6 K3b 2 233 Vsat 86301 58 Ua 6 47e 9 Ub 4 23e 18 Uc 4 706281E 11 Rdsw 650 U0 388 3203 wr 1 tA0 3496967 Ags 1 B0 0 546 Bl 1 Dwg 6 0E 09 Dwb 3 56E 09 Prwb 213 tKeta 3 605872E 02 A1 2 778747E 02 A2 9 tVoff 6 735529E 02 NFactor 1 139926 Cit 1 622527E 04 Cdsc 2 147181E 05 Cdscb 0 DvtOw 0 Dvtlw 0 Dvt2w 0 Cdscd 0 Prwg 0 Eta0 1 0281729E 02 Etab 5 042203E 03 Dsub 31871233 January 2004 301 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits Pclm 1 114846 Pdiblcl 2 45357E 03 Pdiblc2 6 406289E 03 Drout 31871233 Pscbel 5000000 Pscbe2 5E 09 Pdiblcb 234 Pvag 0 delta 0 01 W1 0 Ww 1 420242E 09 Wwl 0 Wln
145. anaging Files January 2004 238 Product Version 5 0 Spectre Circuit Simulator User Guide Running a Simulation This chapter discusses the following topics W Starting Simulations on page 240 Checking Simulation Status on page 241 Interrupting a Simulation on page 242 Recovering from Transient Analysis Terminations on page 242 Controlling Command Line Defaults on page 244 January 2004 239 Product Version 5 0 Spectre Circuit Simulator User Guide Running a Simulation Starting Simulations To start a simulation you type the spect re command at the command line with the following syntax spectre options inputfile The spectre command starts a simulation of input file The simulation includes any options you request For a given simulation the spect re command options override any settings in default environment variables or options statement specifications The simplest example is to simulate a circuit with no run options The following example starts a simulation of the input file test1 spectre testl Specifying Simulation Options Many simulation runs require more complicated instructions than the previous example Spectre circuit simulator run options can be specified in two ways Which method you use depends on the run option m You specify some Spectre options by typing a minus in front of the option The v in the following example specifies that version information be printed for the simula
146. analysis brief description of 132 param parameter 161 param spectre command option 284 parameter checking stopping 195 290 parameter range checker convergence problems 296 parameter range limits file creating 285 absolute value specifications 288 exclusive boundaries in 285 inclusive boundaries in 285 model specifications 288 entering 289 example 288 parameter storage format PSF 234 formatting output files 246 parameter sweeps dev parameter 161 162 210 examples linear sweep 163 logarithmic sweep 163 sweeping temperatur with vector of value formatting 163 freq parameter 161 162 21 mod parameter 161 162 210 param parameter 161 162 210 setting sweep limits 163 specifying 159 temp parameter 162 with vector of values 164 parameter values changing for components 187 265 changing for models 188 265 checking 195 291 all parameter values 195 291 in instance statements 195 291 in model statements 195 290 o c 3 e A in subcircuit calls 98 operating point parameters 195 291 stopping 195 290 controlling the number of checks on 290 example of altering in netlist 11 January 2004 general rules for specifying 84 in instance statements 31 invalid 275 listing 202 232 permissible types 80 scaling 83 testing 292 vector 80 with arithmetic operators 86 with Boolean operators 86 with built in constants 91 with user defined functions 92 parameterized inline subcircuits example of use in netli
147. aram parameter_name modelparam parameter min value max value duration independentvar_limit message message level notice warning error info yes no The syntax for defining a check for a netlist parameter is Name assert expr mdl expr min value max value duration independentvar limit where Name Name of the check statement sub subcircuit master Subcircuit over which the check is to be applied An assert On a subcircuit type applies the check hierarchically to the lowest leaf level instances For example If you define an assert statement with sub and mod all device instances of the specified model type over all instances of the specified subcircuit type are checked If the subcircuit type or master instantiates another subcircuit the devices and models in that instance will be checked as well dev instance Device or subcircuit instance whose instance parameter is to be checked A name is first looked up as a subcircuit instance and then as a device instance If an inline subcircuit and inline device inherits the same hierarchical name the assert is applied to the subcircuit instance If however the parameter specified is a device instance parameter the assert is applied to the device instance mod model Model type whose model or instance parameter is to be checked If the parameter to be checked is an instance parameter specified using the param parameter all instances of
148. aram type value pulse annotate no cmStepResponse tran stop 2us errpreset conservative January 2004 113 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features cmDisablePulse alter dev Vcm param type value dc annotate no loop gain Tv tl nvg open loop gain av 2 cmout pvgtnvg cmEnableTestl alter dev Vtl param mag value 1 annotate no cmEnableTest2 alter dev Vt2 param mag value 1 annotate no cmLoopGain ac start 1k stop 1G dec 10 cmDisableTestl alter dev Vtl param mag value 0 annotate no cmDisableTest2 alter dev Vt2 param mag value 0 annotate no The following file opamp ckt contains the differential amplifier opamp ckt Fully Differential CMOS Operational Amplifier This circuit requires the use of the cmos process models simulator lang spectre Folded Cascode Operational Amplifier subckt opamp pout nout pin nin input differential pair M1 4 pin 1 1 nmos w 402 4u 1 7 6u M2 5 nin 1 1 nmos w 402 4u 1 7 6u M18 1 12 VSS vss nmos w 242 4u 1 7 6u upper half of folded cascode M3 4 11 vdd vdd pmos w 402 4u 1 7 6u M4 5 13 vdd vdd pmos w 402 4u 1 7 6u M5 nout 16 4 vdd pmos w 122 4u 1 7 6u M6 pout 16 5 vdd pmos w 122 4u 1 7 6u lower half of folded cascode M7 nout 13 8 vss nmos w 72 4u 1 7 6u M8 pout 13 9 vss nmos w 72 4u 1 7 6u M9 8 1 2 V
149. arameter specifies initial voltage values for capacitors and current values for inductors and windings In the following example the initial condition voltage on capacitor Cap13 is set to two volts Cap13 11 9 capacitor c 10n ic 2 Specifying Initial Conditions for Nodes You use the ic statement to specify initial conditions for nodes or initial currents for inductors The nodes can be inside a subcircuit or internal nodes to a component The following is the format for the ic statement ic signalName value The format for specifying signals with the ic statement is similar to that used by the save statement This method is described in detail in Saving Main Circuit Signals on page 224 Consult this discussion if you need further clarification about the following example ic Voff 0 X3 7 2 5 Ml int_d 3 5 L1 1 1u This example sets the following initial conditions m The voltage of node voff is set to 0 m Node 7 of subcircuit X3 is set to 2 5 V m The internal drain node of component M1 is set to 3 5 V See the following table for more information about specifying internal nodes m The current for inductor L1 is set to 1p Specifying initial node voltages requires some additional discussion The following table tells you the internal voltages you can specify with different components Component Internal Node Specifications BJT int c int b int e BSIM int d int s January 2004 198 Product Version 5 0 Spectre Cir
150. are useful for detecting spreads in differential circuit applications It does not perform a nominal run Note No temperature sweep is performed mc2 montecarlo donominal no variations mismatch seed 1234 numruns 200 dcop2 dc tran2 tran start 0 stop lu export slewrate oceanEval slewRate v V voutV 10n t 30n t 10 90 January 2004 172 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses The following Monte Carlo analysis statement applies both process and mismatch variations mc3 montecarlo saveprocessparams yes variations all numruns 200 dcop3 dc tran3 tran start 0 stop 1lu export slewrate oceanEval slewRate v V voutV 10n t 30n t 10 90 Specifying Parameter Distributions Using Statistics Blocks The statistics blocks are used to specify the input statistical variations for a Monte Carlo analysis A statistics block can contain one or more process blocks which represent batch to batch type variations and or one or more mismatch blocks which represent on chip or device mismatch variations in which the distributions for parameters are specified Statistics blocks can also contain one or more correlation statements to specify the correlations between specified process parameters and or to specify correlated device instances such as matched pairs Statistics blocks can also contain a truncate statement that can be used for generating truncated distributions The statistics block contain
151. ary parameter values with each analysis You must give each analysis or control statement a unique name The Spectre simulator requires these unique names to identify output data and error messages Control Statements The Spectre simulator lets you place a sequence of control statements in the netlist You can use the same control statement more than once Spectre control statements are discussed throughout this manual The following are control statements alter altergroup assert check checklimit ao info nodeset options paramset January 2004 68 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists save set shell statistics Formatting the Control Statement Control statements often have the same format as analysis statements Like analysis statements many control statements must have unique names These unique names let the Spectre simulator identify the control statement if there are error messages or other output associated with the control statement You specify most control statements as follows Name Control Statement Type parameter value where Name Unique name you give to the control statement Control Statement Spectre name of the type of control statement you want such Type as alter You can find this name by referring to the topics list in the Spectre online help spectre h parameter value List of parameter values you specify for the control statement You can s
152. atch analysis to perform sweeps of temperature parameters model instance subcircuit parameters etc In the following example the device parameter w of the device x1 mp2 is swept from 15um to 20um at each increment of 1pm demm6 n3 0 dcmatch mth 0 01 dev xl mp2 param w start 15e 6 stop 20e 6 step le 6 where rawfile In the following example a set of analyses is performed on output v n3 0 by sweeping the device parameter w of the device mp6 from 80um to 90um at each increment of 2um sweepl sweep dev mp6 param w start 80e 6 stop 90e 6 step 2e 6 January 2004 156 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses dcmm5 n3 0 dcmatch mth le 3 where rawfile In the following example temperature is swept from 25 C to 100 C at increment of 25 C dcmm7 n3 0 dcmatch mth 0 01 param temp start 25 stop 100 step 25 For more information on the dcmatch parameters see the Spectre Circuit Simulator Reference If you run the dcmatch analysis in Analog Design Environment you can access the output through the Results menu and create a table of mismatch contributors Stability Analysis The loop based and device based algorithms are available in the Spectre circuit simulator for small signal stability analysis Both are based on the calculation of Bode s return ratio The analysis output are loop gain waveform gain margin and phase margin Model Definition name stb parameter value E
153. atement in the netlist until you request another parameter modification The set and options statements have many identical parameters but the set statement cannot modify all options statement parameters The parameter listings in the Spectre online help tell you which parameters you can reset with the set statement The following example demonstrates the set statement syntax This example turns off several annotation parameters Quiet set narrate no error no info no B Quiet is the unique name you give to the set statement B The keyword set is the primitive name for the set statement B narrate error and info are the parameters you are changing January 2004 220 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Note If you want to change temp or tnom use the alter statement The shell Statement The shell analysis passes a command to the operating system command interpreter given in the SHELL environment variable The command behaves as if it were typed into the Command Interpreter Window except that any sx codes in the command are expanded first The default action of the shell analysis is to terminate the simulation The following is the syntax for the shell statement Name shell parameter value The statistics Statement The statistics blocks allow you to specify batch to batch process and per instance mismatch variations for netlist parameters These statistically varying netlist
154. ating point parameters for component D9 Saves the collector current for component Q1 Example assumes Q1 is a BJT and therefore c is a terminal name Same effect as the previous statement Saves the collector current for component Q1 Identifies the terminal with its terminal index instead of its terminal name Saves capacitive current associated with the drain terminal of component M2 Example assumes v2 is a MOSFET so d is a terminal name Saves all currents for component 03 and all signals for component M1 Saves operating point parameters for terminal BJT3 BJT3 is in subcircuit S1 Subcircuit S1 is nested within subcircuit F4 Saving Individual Currents with Current Probes A current probe is a component that measures the current passing between two nodes Its effect is like placing an amp meter on two points of a circuit It creates a new branch in the circuit between the two nodes forces the voltages on the two nodes to be equal and then measures the flow of current When to Use Current Probes Use a probe instead of a save statement under the following circumstances f you want increased flexibility for giving currents descriptive names With a current probe you can name the current anything you want With a save statement the name of the current must have a name suffix B lfyouare saving measurements for current controlled components W f you are saving currents for an AC analysis B f yo
155. ation Note You can also give Spectre netlist instructions to display some status information For more information consult the Spectre online help about the sweep and steps options for the annotate parameter You can set the annotate parameter for most Spectre analyses Interrupting a Simulation If you want to stop the Spectre simulator while a simulation is running do one of the following m Send an INT signal with your interrupt character The interrupt character is usually Control c You can get information about the interrupt character for your system with the UNIX stt y utility m Send the INT signal with a kill 1 command When you use either of these commands the Spectre simulator prepares the incomplete output data file for reading by the postprocessor and then stops the simulation N Caution Do not stop the Spectre simulator with a kill 9 command This command stops the simulation before the Spectre simulator can prepare the output files for reading by the postprocessor Recovering from Transient Analysis Terminations If a transient analysis ends before a successful conclusion you can recover the work that is completed and restart the analysis The Spectre simulator needs checkpoint files to perform this recovery This section tells you about the following ways to create checkpoint files m Automatically with defaults and options statement settings m From the command line during a simulation m For specific anal
156. ator computes the response to a sine wave in order to calculate distortion ua741 operational amplifier global gnd vcc vee simulator lang spectre Spectre options audit detailed limit delta maxdeltav 0 3 save lvlpub nestlvl 1 ua741 operational amplifier model NPNdiode diode is 1f imax 5m model NPNbjt bjt type npn bf 80 vaf 50 imax 5m cje 3p cjc 22p cjs 2p tf 3n tr 6n rb 100 model PNPbjt bjt type pnp bf 10 vaf 50 imax 5m cje 6p cjc 24p tf 1n tr 20n rb 20 subckt ua741 pin nIn out Transistors Q1 1 pIn 3 vee NPNbjt Q2 1 nIn 2 vee NPNbjt Q3 5 16 3 vec PNPbjt Q4 4 16 2 vcc PNPbjt Q5 5 8 7 vee NPNbjt Q6 4 8 6 vee NPNbjt Q7 vec 5 8 vee NPNbjt Q9 16 1 vcc vee PNPbjt Q14 vcc 13 15 vee NPNbjt Q16 vcc 4 9 vee NPNbjt Q17 11 9 10 vee NPNbjt Q18 13 12 17 vee NPNbjt January 2004 136 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Q20 vee 17 14 vcc PNPbjt Q23 vee 11 17 vcc PNPbjt Diodes Q8 vcc 1 NPNdiode Q19 13 12 NPNdiode Resistors Rl 7 vee resistor r 1k R2 6 vee resistor r 1k R3 8 vee resistor r 50k R4 9 vee resistor r 50k R5 10 vee resistor r 100 R6 12 17 resistor r 40k R8 15 out resistor r 27 R9 14 out resistor r 22 Capacitors C1 4 11 capacitor c 30p Current Sources Il 16 vee isource dc 19u I2 vcc 11 isource dc 550u I3 vcc 13 isource dc 180u ends ua741 Sources Vpos vcc gnd vsource dc 15 Vneg vee gnd vsource dc 15 Vin pin gnd vso
157. awd 35 donominal parameter Monte Carlo analysis 170 double slash in Spectre syntax 59 dptran as homotopy parameter option 267 Dracula use of with Spectre 23 duoc parameter 180 181 duoe parameter 1 1 dvthc parameter ol dvthe parameter 18 E e colon modifier 273 electrical current in Amperes 76 electrical potential in Volts 76 encrypt file 249 how to 248 model card 252 overview 247 Spectre netlist 247 SPICE netlist 247 subcircuit 249 syntax 248 end 50 end 50 enumerations setting parameter limits with 81 envelope following analysis 23 132 environment variables changing defaults IO eo CO IO Product Version 5 0 Spectre Circuit Simulator User Guide in 245 environments in which Spectre can be used 23 envip 23 132 equal sign in Spectre syntax 59 error conditions terminate simulation internal errors 277 invalid parameter values 275 singular Jacobian or matrix 276 errormessages 19 caused by invalid parameters in subcircuit calls 98 customizing 284 specifying conditions for in subcircuit calls 98 error options of spectre command 295 error tolerances abstol parameter error tolerance parameter 143 errpreset parameter 142 Iteratio error tolerance parameter relref error tolerance parameter reltol parameter error tolerance parameter 143 errpreset parameter 142 143 escaping special characters 62 estimating so
158. axwarnstologfile andmaxnotestologfile parameter settings You can use the checklimitfile option to write the violations to a dedicated file A message during simulation indicates where the violations are being written For more information see Spectre h options You can enable or disable checks or groups of checks by the checklimit statement Example 1 vgs check assert primitive bsim3 param Vgs min 0 0 max 2 5 message Vgs exceeds bound level warning Checks for vgs over all device instances of the primitive type BSIM3 and prints a warning Vgs exceeds bound ifthe value of vas is less than 0 and higher than 2 5 Example 2 mlvgs check assert sub inv dev ml param Vgs min 0 0 max 2 5 message Vgs exceeds bound level notice Checks for vgs in the device m1 over all instances of the subcircuit type inv in the netlist and prints a notice Vgs exceeds bound if the value of vgs is less than 0 and higher than 2 5 January 2004 193 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Example 3 Netlist subckt mysubckt a b c parameters adNum 0 0 id es contents of the subcircuit ends mysubckt Check defined for the above netlist adNum check assert dev X1 param adNum min 0 0 max 5 0 message Drain parasitic resistor is too high level warning Checks the parameter adNum in the subcircuit instance x1 and prints a warning Drain parasitic resistor is too high ifthe value of adNum is higher t
159. bcircuit S1 Subcircuit S1 is nested within subcircuit F4 Saving Individual Currents with Current Probes A current probe is a component that measures the current passing between two nodes Its effect is like placing an amp meter on two points of a circuit It creates a new branch in the circuit between the two nodes forces the voltages on the two nodes to be equal and then measures the flow of current x Important Adding probes to circuits that are sensitive to numerical noise might affect the solution In such cases an accurate solution might be obtained by reducing reltol When to Use Current Probes Sometimes it is preferable or necessary to use a current probe rather than a save statement You use a probe instead of a save statement under the following circumstances January 2004 226 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options B f you want increased flexibility for giving currents descriptive names With a current probe you can name the current anything you want With a save statement the name of the current must have a name suffix B f you are saving measurements for current controlled components m If you are saving currents for an AC analysis B f you are saving measurements for a current that passes between two parts of a circuit but not through a terminal In the following example you insert a current probe to measure the current flowing between A and B Because th
160. bstol and 300 mV for maximum change per Newton iteration maxdelta You can change abstol to 5 uV reset maxdelta to 600 mV define the estimate of the maximum voltage to be 1000 V and set the maximum permitted voltage to be 10 with the following statement VoltQuant quantity name V abstol 5uV maxdelta 600mV huge 1000V blowup 1e9 VoltQuant is a unique name you give to the quant ity statement The keyword quantity is the primitive name for the statement The name parameter identifies the quantity you are changing v is the name for electrical potential abstol maxdelta huge and blowup are the parameters you are resetting Note The quantity statement has other uses besides setting tolerances You can use the quantity statementto create new quantities or to redefine properties of an existing quantity and you can use the node statement to set the quantities for a particular node For more information about the quantity statement see the Spectre online help spectre h quantity and the SpectreHDL Reference manual For more information on the node statement see spectre h node The following is an example of a node statement setToMagnetic tl t2 node value Wb flow MMF strength insist January 2004 77 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Inherited Connections Inherited connections is an extension to the connectivity model that allows you to create global signals and override their
161. by increasing 1teratio to 50 or more Occasionally an oscillator in the circuit causes the transient analysis to terminate or work very slowly January 2004 297 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Correcting Transient Analysis Convergence Problems You can use two approaches to eliminate transient analysis convergence problems The first strategy is to reduce the effect of discontinuities in nonlinear capacitors The second method is to eliminate discontinuous jumps in the solution Try the following suggestions if you have difficulty with transient analysis convergence m Use a complete set of parasitic capacitors on nonlinear devices to avoid jumps in the solution waveforms Specify nonzero source and drain areas on MOS models m Use the cmin parameter to install a small capacitor from every node in the circuit to ground This usually eliminates any jumps in the solution If you can identify a nonlinear capacitance that might have a discontinuity simplify the nonlinear capacitor model If you cannot actually simplify the model modifying it might help convergence B As alast resort relax the tolerance values for the lteratio or reltol parameters and widen transitions in the stimulus waveforms Correcting Accuracy Problems If you need greater accuracy from a Spectre simulation the most common solution is to tighten the reltol parameter of the options or set s
162. by the Spectre simulator itself The second option include is performed by the CPP You must use the include option when you have macro substitution in the inserted file Note CPP is not supported in Spectre Direct January 2004 72 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Rules for Using the include Statement Remember the following rules and guidelines when using the include statement You must use the include format if you want the CPP to process the inserted file Also you must specify that the CPP be run using the command line option when you start the Spectre simulator Regardless of which include format you use you can use the 1 command line option followed by a path to have the Spectre simulator look for the inserted files in a specified directory in addition to the current directory just as you would for the CPP include If filename is not an absolute path specification it is considered relative to the directory of the including file that the Spectre simulator is reading not from the directory in which the Spectre simulator was called You must surround the filename in quotation marks You can place a space and then a backslash escaped newline between include and ilename for line continuation You can place other include statements in the inserted file recursive inclusion With any of the include formats you can set the language mode for the inserted file b
163. cards that refer to encrypted parameters must be in a protected block to protect the parameter values If protected parameters are referred to by an unprotected device or model card the parameter values are printed in the info statements for this device or model card You can alter or sweep a protected subcircuit parameter All device instance and model parameters dependent on the altered parameter are updated even if the device or model is protected Protected Model Parameters For a model card inside a protected block where the protect keyword appears before the model statement the model card and all model parameters are encrypted If you place protect after the model definition and leave some parameters outside a protection block only parameters inside the protection block are encrypted During simulation all parameters inside the model card are encrypted since encryption is done on the basis of the model card not individual parameters Warning messages and nfo statements for all model parameters and values of a protected model card are suppressed January 2004 255 Product Version 5 0 Spectre Circuit Simulator User Guide Encryption Even if the model name is protected you can instantiate primitives using that model You cannot alter or sweep protected model parameters but you can replace a protected model through an altergroup statement Multiple Name Spaces Names of parameters subcicuits models and devices that appear excl
164. ce the pseudotransient method ptran and the damped pseudotransient method dpt ran You can also prevent the use of continuation methods by setting the homotopy parameter to none January 2004 267 Product Version 5 0 Spectre Circuit Simulator User Guide 12 Managing Files This chapter discusses the following topics m About Spectre Filename Specification on page 269 m Creating Filenames That Help You Manage Data on page 269 January 2004 268 Product Version 5 0 Spectre Circuit Simulator User Guide Managing Files About Spectre Filename Specification Many analysis statements require a filename as a parameter value for the input or output of data It is often easier to keep track of output files if these filename parameter values are related to some other filename typically the input filename The Spectre circuit simulator s filename specification features help you manage your data by letting you systematically specify or modify filenames With the Spectre simulator you can easily identify data from multiple simulation runs or from single runs containing repeated similar analyses You can modify input filenames so that you can easily identify the output file from a specific simulation or analysis You can also construct output filenames in ways that prevent accidental overwriting of data Creating Filenames That Help You Manage Data The Spectre simulator helps you keep track of simulation data by letting you cr
165. city The Spectre circuit simulator can simulate larger circuits than other simulators because its convergence algorithms are effective with large circuits because it is fast and because it is frugal with memory and uses dynamic memory allocation For large circuits the Spectre circuit simulator typically uses less than half as much memory as SPICE Improved Accuracy Improved component models and core simulator algorithms make the Spectre circuit simulator more accurate than other simulators These features improve Spectre accuracy m Advanced metal oxide semiconductor MOS and bipolar models Q The Spectre BSIM3v3 is a physics based metal oxide semiconductor field effect transistor MOSFET model for simulating analog circuits Q The Spectre models include the MOSO model which is even simpler and faster than MOS for simulating noncritical MOS transistors in logic circuits and behavioral models MOS 9 EKV BTA HVMOS BTA SOI VBIC95 TOM2 HBT and many more m Charge conserving models The capacitance based nonlinear MOS capacitor models used in many SPICE derivatives can create or destroy small amounts of charge on every time step The Spectre circuit simulator avoids this problem because all Spectre models are charge conserving m Improved Fourier analyzer The Spectre circuit simulator includes a two channel Fourier analyzer that is similar in application to the SPICE FOURIER statement but is more accurate The Spectre
166. colon modifier 273 H predefined percent code 270 hard limit definition 81 homotopy parameter 267 January 2004 hot electron degradation simulating 178 circuitage parameter 179 degradation parameters 179 180 example 181 failure criteria parameters 180 options and restrictions 178 results files 180 specifying the analysis 179 huge parameter 76 hyperbolic functions 88 76 iabstol parameter 210 convergence problems and 296 setting to correct accuracy problems 298 ic parameter in transient analyses 197 259 ic statement example 198 260 formatting 198 260 specifying initial conditions 197 259 if statements 109 imelt 279 include statements examples 72 74 formatting 72 include statements 72 examples 74 formatting 72 of use in netlist 112 rules for using 73 individual components specifying 30 62 info spectre command option 295 info statement 202 232 choosing the output destination 233 204 example 204 234 formatting 204 234 options 203 233 informational messages specifying conditions for in subcircuit calls 98 infotime 146 inheritance 78 inherited connections 78 initial conditions specifying 197 examples 198 259 260 individual analyses 200 262 259 Product Version 5 0 Spectre Circuit Simulator User Guide transient analyses 197 259 initial settings of the stat of the simulator modifying 189 266 inline model statements in
167. ct X1 in out INV unprotect subckt INV in out mpl vdd in vdd pmos W 1 0e 6 L 1 0e 6 mnl out in 0 0 nmos W 1 0e 6 L 1 0e 6 ends INV In the flattened netlist devices X1 mp1 and X1 mn1 are protected January 2004 254 Product Version 5 0 Spectre Circuit Simulator User Guide Encryption For a device meeting any of the above criteria its name and instance parameters are protected The instance parameters of a protected device cannot be modified through an alter statement but the protected device can be replaced through an altergroup statement Information about a protected device is filtered out in all analyses outputs Encrypted devices are not included in the circuit inventory Protected Node A node contained exclusively within a protected block is protected and its name and value is not displayed in the output file If you request an ic file or restart a simulation protected nodes are displayed in encrypted format in the ic checking point and restart output files Protected Global and Netlist Parameters Global and netlist parameters defined inside a protected block are encrypted However you can alter or sweep a protected parameter All device instance and model parameters dependent on the altered parameter are updated even if the device or model is protected Protected Subcircuit Parameters Subcircuit parameters are protected if they appear exclusively within a protected block All devices or model
168. ctre 60 restart parameter in analyses 258 results controlling destination and format of 244 displaying 34 Results Browser 35 RF capabilities 21 rforce parameter and convergence problems 297 setting to correct accuracy problems 299 run terminations See terminations of January 2004 Spectre 241 running a simulation introductory example 32 S 96S predefined percent code 271 9eS DEFAULTS 245 sample input file differential amplifier 112 GaAs traveling wave amplifier 95 process file 115 two port test circuit 120 uA741 operational amplifier 135 save parameter example 215 217 228 229 formatting 217 229 options 217 229 setting with an analysis statement 21 IN IN setting with the options statement 21 save statement 211 examples 213 225 formatting 211 224 keywords 212 213 224 225 operating point parameters of individual components saving 212 224 saving signals by keywords 212 224 by terminal index 212 224 by terminal name 212 224 of individual components 212 224 of individual nodes 212 224 of individual subcircuits 213 225 voltages of individual nodes saving 212 224 saveahdivars 232 savefamilyplots parameter Monte Carlo analysis 171 saveprocessparams parameter Monte Carlo analysis 167 saveprocessvec parameter Monte Carlo analysis 169 saving all ahdl variables 232 currents for AC analysis 214 227 groups of currents with the currents parameter 218 230
169. cuit Simulator User Guide Control Statements Component Internal Node Specifications MOSFET int d int s GaAs MESFET int d intos intg JFET int_d int_s int_g int_b Winding for Magnetic Core int_Rw Magnetic Core with Hysteresis flux Supplying Solution Estimates to Increase Speed You use the nodeset statement to supply estimates of solutions that aid convergence or bias the simulation towards a given solution You can use nodesets for all DC and initial transient analysis solutions in the netlist The nodeset statement has the following format nodeset signalName value Values you can supply with the nodeset statement include voltages on topological nodes including internal nodes and currents through voltage sources inductors switches transformers N ports and transmission lines The format for specifying signals with the nodeset statement is similar to that used by the save statement This method is described in detail in Saving Main Circuit Signals on page 224 Consult this discussion if you need further clarification about the following example nodeset Voff 0 X3 7 2 5 Ml int_d 3 5 L1 1 1u This example sets the following solution estimates m The voltage of node voff is set to 0 m Node 7 of subcircuit X3 is set to 2 5 V m The internal drain node of component M1 is set to 3 5 V See the table in the ic statements section of this chapter for more information about specifying internal nodes
170. cuit nodes Altering Sweeping Parameters Just as certain Spectre analyses such as sweep alter ac dc noise sp and xf can sweep component instance or model parameters they can also sweep netlist parameters Run spectre h analysis to see the particular details for any of these analyses where analysis is the analysis of interest Expressions An expression is a construct that combines operands with operators to produce a result that is a function of the values of the operands and the semantic meaning of the operators Any legal operand is also an expression in itself Legal operands include numeric constants and references to top level netlist parameters or subcircuit parameters Calls to algebraic and trigonometric functions are also supported The complete lists of operators algebraic and trigonometric functions are given after some examples The following are examples simulator lang spectre parameters pl 1 p2 2 declare some top level parameters January 2004 86 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features rl 1 0 resistor r pl the simplest type of expression r2 1 0 resistor r pl p2 a binary expression r3 1 0 resistor r 5 6 2 expression of constants 8 xl sl p4 8 instantiate a subcircuit defined in the following lines subckt sl parameters pl 4 p3 5 p4 p1l p3 subcircuit parameters rl 1 0 r
171. cuit s periodic operating point This operating point is used for periodic time varying small signal analyses such as pac px f and pnoise For more information about the periodic steady state analysis see SpectreHF Help Q Periodic transfer function analysis px After the periodic steady state analysis computes a periodic solution this analysis linearizes the circuit about the periodic steady state and performs a small signal analysis The small signal analysis computes the transfer function from every independent source in the circuit to a designated output The variable of interest at the output can be voltage or current The analysis is similar to the transfer function analysis except that it linearizes the circuit about a periodically varying operating point and accurately models frequency conversion effects For more information about the periodic transfer function analysis see SpectreRF Help m Other analyses Q Sensitivity analysis sens Determines the sensitivity of output variables to input design parameters The results are expressed as a ratio of the change in an output analysis variable to the change in an input design parameter The output for the sens command is sent to the rawfile or to an ASCII file For more information about sensitivity analysis see Sensitivity Analysis on page 151 Q Fourier analysis fourier Measures the Fourier coefficients of two different signals at a specified fundamental freque
172. d January 2004 145 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses m With skipping time points which lets you select how many data points the Spectre simulator saves m With data compression which eliminates repetitive recording of signal values that are unchanged m With the outputstart parameter which lets you specify the time when the Spectre simulator starts saving data points m With the infotime parameter which lets you specify specific times to save operating point data instead of for all time points Telling the Spectre Simulator to Change the Time Interval between Data Points Strobing Strobing changes the interval between data points You use strobing to eliminate some unwanted high frequency signal from the output just as a strobe light appears to freeze rapidly rotating machinery With strobing you can demodulate AM signals or hide the effect of the clock in clocked waveforms You can also dramatically improve the accuracy of external Fast Fourier Transform FFT routines To perform strobing you set the following parameters in the transient analysis m The strobeperiod parameter which sets the time interval between the data points that the Spectre simulator saves m The skipstart parameter optional which tells the Spectre simulator when to start strobing This parameter is also used to skip data points m The skipstop parameter optional which tells the Spectre simulator when to stop
173. d Syntax Conventions This list describes the syntax conventions used for the Spectre circuit simulator literal Nonitalic words indicate keywords that you must enter literally These keywords represent command function routine or option names filenames and paths and any other sort of type in commands argument Words in italics indicate user defined arguments for which you must substitute a name or a value The characters before the underscore _ in the word indicate the data types that this argument can take Names are case sensitive Vertical bars OR bars separate possible choices for a single argument They take precedence over any other character Brackets denote optional arguments When used with OR bars they enclose a list of choices You can choose one argument from the list 1 Kundert Kenneth S The Designer s Guide to SPICE amp Spectre Boston Kluwer Academic Publishers 1995 January 2004 14 Product Version 5 0 Spectre Circuit Simulator User Guide Preface Braces are used with OR bars and enclose a list of choices You must choose one argument from the list Three dots indicate that you can repeat the previous argument If you use them with brackets you can specify zero or more arguments If they are used without brackets you must specify at least one argument but you can specify more Important The language requires many characters not included in the preceding list You must ent
174. d Troubleshooting If you set save selected the Spectre simulator saves the voltages in the save statement If the save statement does not contain any voltage values Spectre issues the above warning and changes the save option default to 1vlpub This saves all node voltages Customizing Error and Warning Messages You can customize the Spectre error and warning messages to some extent to fit the needs of a simulation This section tells you about these customization options Selecting Limits for Parameter Value Warning Messages You can accept Cadence default soft limits that determine when you receive warning messages about parameter values or you can enter your own limits You can also control which parameters the Spectre simulator checks This section gives you instructions for all Accepting Cadence Range Limits Defaults The most convenient option for deciding which warning messages you receive is to accept Cadence Range Limits Defaults The Cadence defaults are located in your install dir tools dfII etc spectre range lmts and you can examine them to see if they meet your needs You can enter Cadence defaults with the SPECTRE DEFAULTS environment variable in your shell initialization file such as profile or cshrc The entry in your shell initialization file looks like the following setenv SPECTRE DEFAULTS param HOME tools dfII etc Spectre range lmts With this entry in the shell
175. d all instances oppoint Checks operating point parameters for all models and all instances Selecting Limits for Operating Region Warnings The Spectre simulator lets you specify forbidden operating regions for transistors If a transistor operates in a forbidden operating region the Spectre simulator sends you a warning message This feature is available for BJTs MOSFETs JFETs and GaAs MESFETs Specifying Forbidden Operating Regions for Transistors You specify a forbidden operating region in a transistor with the alarm parameter The alarm parameter gives you the following options Option Description none The default condition with no warnings issued off Warns if the transistor is turned off triode Warns if the transistor operates in the triode region available for MOSFETs sat Warns if the transistor operates in the saturation region subth Warns if the transistor operates in the subthreshold region available for MOSFETs fwd Warns if the transistor is forward biased available for BJTs em Warns if the transistor is reverse biased For example to be sure that a group of MOSFETs always operates in the saturation region you enter this model statement model mos example nmos alarm off alarm triode alarm subth January 2004 291 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Each of the three alarm parameters in this example identifies a forbidd
176. d are not accessible from the schematic level or netlist level to insert the probe component The supported active device and its dominant gain source are summarized in the table below Component Dominant Controlled Source Description b3soipd gm Common source transconductance bjt gm Common emitter transconductance bsim1 2 3 3v3 gm Common source transconductance btasoi gm Common source transconductance CCCS gain Current gain CCVS rm Transresistance ekv gm Common source transconductance gaas gm Common source transconductance January 2004 158 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Component Dominant Controlled Source Description hbt dice_dvbe Intrinsic dlce dVbe hvmos gm Common source transconductance jfet gm Common source transconductance mos0 1 2 3 gm Common source transconductance tom2 gm Common source transconductance vbic dic_dvbe Intrinsic dlc dVbe VCCS gm Transconductance VCVS gain Voltage gain In general the stability information produced by the device based algorithm can be used to assess the stability of that particular device Most often a feedback network consists of a global feedback loop and numerous nested local loops around individual transistors The loop based algorithm can determine the stability of the whole network as long as all nested loops are stable while the device based algorithm can be used to ensure all local loops are stable For more information on the stabilit
177. d of input or until the next simulator lang command For example you can include Spectre lines in the middle of a SPICE netlist by surrounding the Spectre lines with the simulator lang command rl L 9 lk v1 1 0 1 January 2004 53 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility simulator lang spectre r2 1 0 resistor r 1k simulator lang spice Op If you do not specify an input language the Spectre simulator uses SPICE mode by default You do not need to place simulator lang commands around include statements but you must specify simulator lang spectre in include files written in the Spectre Netlist Language Spectre allows you to specify the netlist input format to be Spectre without the simulator lang command by naming the file with the Spectre circuit simulator extension of scs Files ending in this extension are treated as Spectre syntax Appending Spectre Parameters While you can gain full access to Spectre features by switching to the Spectre syntax you can also gain access to specific parameters on the SPICE input statements The SPICE Reader maps each SPICE statement to the Spectre equivalent statement Mapping of parameters is done first for order dependent parameters and then for name value based parameters The SPICE reader tries to map parameters in the name value form if they are known otherwise they are passed directly to Spectre as is This allows you to add Spectre parameters to
178. d predict circuit performance variations that affect yield The statistics blocks allow you to specify batch to batch process and per instance mismatch variations for netlist parameters These statistically varying netlist parameters can be referenced by models or instances in the main netlist and can represent IC manufacturing process variation or component variations for board level designs The following description gives a simplified example of the Monte Carlo analysis flow perform nominal run if requested if any errors in nominal run then stop for each Monte Carlo iteration if process variations specified then apply process variation to parameters if mismatch variations specified then for each subcircuit instance apply mismatch variation to parameters January 2004 164 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses for each child analysis run child analysis evaluate any export statements and store results in a scalar data file The following is the syntax for the Monte Carlo analysis Name montecarlo parameter value analysis statements export statements The Monte Carlo analysis Refers to the statistics block s for how and which netlist parameters to vary Generates statistical variation random numbers according to the specified distributions Runs the specified child analyses similar to the Spectre nested sweep analysis where the child analys
179. d the operating point of v1 is probed the drain to source current ids is reported correctly However the reported vds is not the same as V d V s the two wires that connect the subcircuit drain and source terminals Instead vas is V dp V sp which are nodes internal to the inline subcircuit Caution Parasitic Elements in Parallel with Device Terminals If the parasitic elements are in parallel with the device terminals the reported voltages are correct but the reported currents might be incorrect For example consider the following case of a MOSFET with source to bulk and drain to bulk diodes inline subckt mos d dg s b parameters pl 1u p2 2u mos d dg s b mos mod l p1 w p2 inline component di d b diodel r 10 drain bulk diode d2 s b diodel r 10 source bulk diode ends mos d Here the operating point vas for the inline component is reported correctly because there are no extra nodes introduced by the inline subcircuit model However the reported ids for the inline device is not the same as the current flowing into terminal a because some of the current flows into the transistor and some through diode d1 Parameterized Models Inline subcircuits can be used in the same way as regular subcircuits to implement parameterized models When an inline subcircuit contains both a parameterized model and an inline device referencing that model you can create instances of the device and each instance automatically
180. d4h5 modsp section tt Next line defines transient steps and total simulation time tempOption options temp 25 tt tran tran step 0 010n stop 35n alter ss altergroup include q35d4h5 modsp section ss parameters vdd S1 3 0 alterTempTo100 alter param temp value 100 ss_tran tran step 0 010n stop 35n alter_ff altergroup include q35d4h5 modsp section ss parameters vdd_S1 3 3 alterTempTo0 alter param temp value 0 ff tran tran step 0 010n stop 35n Ring Oscillator Spectre Deck for Three Input NAND Ring with No Fanouts nand3 ring sp This example uses Spectre syntax Ring oscillator Spectre deck for 3 Input NAND ring with no fanouts simulator lang spectre global 0 gnd vdd vss aliasGnd gnd 0 vsource type dc dc 0 Simulator options to use SetOptionl options iabstol 1 00n audit full MyAcctl info what inst extremes yes MyAcct2 info what models extremes yes January 2004 305 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits MyAcct3 info what input extremes yes MyAcct5 info what terminals extremes yes MyAcct6 info what oppoint extremes yes Next section is the subckt for na3pl subckt na3pl nga ml nq a vdd vdd p 1 0 35u w 2 90u ad 1 10p pd 3 66u as 2 12p ps 7 26u m2 nq vdd vdd vdd p 1 0 35u w 2 90u ad 1 10p pd 3 66u as 1 10p ps 3 66u m3 nq vdd vdd vdd p 1 0 35u w 2 90u ad 2 12p pd 7 26u as 1 10p ps 3 66u m4 vss a 7 v
181. definition of a microstrip line The terminal names are t 1 b1 t2 and b2 Name t1 bl t2 b2 msline parameter value Q A terminal index The terminal index is a number that indicates where a terminal is in the instance definition You give the first terminal a terminal index of 1 the second a terminal index of 2 and so on In this example the terminal indexes are 7 for sink and 2for SEGi Name sink src isource parameter value Q A name of an operating point parameter from the lists of parameters for each component in the Spectre online help The name ofa SpectreHDL Verilog An internal variable Q One of the following keywords currents To save all currents of the device static To save resistive currents of the device displacement To save capacitive currents of the device dynamic To save charge or flux of the device oppoint To save the operating points of the device probe To measure current of the device with a probe January 2004 212 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements pwr To save power dissipated on a circuit subcircuit or device all To save all signals of the device B subcircuitName is the instance name of a subcircuit call Saving terminal currents for subcircuit calls is the same as saving terminal currents for other instance statements except that you must identify individual terminal currents you want to save by the terminal index Note To save all terminal currents fo
182. desets or initial conditions causes convergence difficulties try increasing rforce With the options statement B f you are simulating a bipolar analog circuit make sure the region parameters on all transistors and diodes are set correctly W If the analysis fails at an extreme temperature but succeeds at room temperature try adding a DC analysis that sweeps temperature Start at room temperature sweep to the extreme temperature and write the last solution to a nodeset file m Use numeric pivoting in the sparse matrix factorization Set pivotdc yes with the options statement Sometimes you must also increase the pivot threshold to between 0 1 to 0 5 by resetting the pivrel parameter with the opt ions statement M Divide the circuit into pieces and simulate them individually Make sure that results for a part alone are close to results for that part combined with the rest of the circuit Use the results to create nodesets for the whole circuit B Try replacing the DC analysis with a transient analysis Modify all the independent sources to start at zero and ramp to the independent source DC values Run the transient analysis well beyond the time when all the sources have reached their final values Write the final point to a nodeset file You can make this transient analysis more efficient with one of the following procedures Q Set the integration method to backward Euler method euler Q Loosen the local truncation error criteria
183. dividual components to specify initial conditions for those components and you use the ic statement to specify initial conditions for nodes You can specify initial conditions for inductors with either method Specifying cmin for a transient analysis does not satisfy the condition that a node has a capacitive path to ground Note Do not confuse the ic parameter for individual components with the ic parameter of the transient analysis The latter lets you select from among different initial conditions specifications for a given transient analysis Specifying Initial Conditions for Components You can specify initial conditions in the instance statements of capacitors inductors and windings for magnetic cores The ic parameter specifies initial voltage values for capacitors and current values for inductors and windings In the following example the initial condition voltage on capacitor Cap13 is set to two volts January 2004 259 Product Version 5 0 Spectre Circuit Simulator User Guide Time Saving Techniques Cap13 11 9 capacitor c 10n ic 2 Specifying Initial Conditions for Nodes You use the ic statement to specify initial conditions for nodes or initial currents for inductors The nodes can be inside a subcircuit or internal nodes to a component The following is the format for the ic statement ic signalName value The format for specifying signals with the ic statement is similar to that used by the save statement This me
184. duct Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Diodes length 1 or width w Resistors length 1 or width w Physical resistors phy res length 1 or width w MOSFET length or width Finding Default Measurement Units The effects of scale and scalem depend on the default measurement units of the components you scale To find the default measurement units for a component parameter look up that parameter in the parameter listings of your Spectre online help spectre h The default for measurement units is in parentheses For example the m in this entry from the mos8 parameter descriptions in the Spectre online help spectre h tells you that the default measurement unit for channel width is meters w m Channel width Effects of scale and scalem with Different Default Units scale and scalem affect only parameters whose default measurement units are in meters For example vmax is affected because its units are m sec but ucrit is not affected because its units are V cm Similarly n sub is not affected because its units are 1 cm You can check the effects of scale and scalem by adding an info statement with what output and look for the effective length 1e or width wef of a device For more information about the info statement see The info Statement on page 202 The following table shows you the effects of scale and scalem with different units
185. e Parentheses can be used to change the order of evaluation For a binary expression like a b a is the first operand and b is the second operand All operators are left associative with the exceptions of the to the power of operator and the ternary operator which are right associative For logical operands any nonzero value is considered true The relational and equality operators return a value of 1 to indicate true or 0 to indicate false There is no short circuiting of logical expressions involving amp amp and Operator Symbol s Value Unary Unary Value of the operand negative of the operand January 2004 87 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Operator Symbol s Value To the power of First operand to be raised to the power of the second operand Multiply Divide Product quotient of the operands Binary Plus Minus Sum difference of the operands Shift lt lt gt gt First operand shifted left by the number of bits specified by the second operand first operand shifted right by the number of bits specified by the second operand Relational lt lt gt gt Less than less than or equal greater than greater than or equal respectively Equality True if the operands are equal true if the operands are not equal Bitwise AND amp Bitwise AND of integer operands Bitwise Exclusive or
186. e Valid values S Y Z Default value s Format of the complex number Valid values DB for db and angle MA for magnitude and angle RI for real and imaginary Default value MA Reference resistance Number of ohms the real impedance to which the parameters are normalized Default value 50 0 The syntax for data lines in MA is as follows One port Freq Mag f ISl Two ports Freq Mag f IX11 January 2004 Ang Ang Mag Ang Mag Ang Mag Ang Zx11 x21 Zxii1 x12 zx12 x22 Zx22 125 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Three ports Freq Mag f S11 f S241 f S311 Four ports Freq Mag f S77l f S271 f S371 f S4 Ang ZS ZS3 Ang Z3 Z521 2831 54 Mag S12 So S39 Mag S121 S99 S39 S42 Ang Mag Ang 812 S873 4873 33 S231 S23 532 15331 Z533 Ang Mag Ang Mag Ang ZS12 ISl S13 Sy4l ZS Z8 15231 Z523 S2ql 45824 532 Ss3 533 S34 534 LS42 S43 Z343 S44 Z344 and so on where the complex number format is specified as MA on the line The frequency entry must be first and can include a scale factor The data entries need to be separated with at least a space The data entries at the first frequency point specify the number of ports Adding Noise Parameters You can add two port noise parameters to a Touchstone data file after the S
187. e statements with the output file name in the converted netlist Do not put around the input file name if you use this option inputFile The SPICE netlist to be converted Put around the input file name only if you do not use the iofile option outputFil The file name for the converted netlist If you do not specify this the converted netlist is displayed at standard output i e in the terminal window Examples The following command converts the SPICE netlist amp sp to an equivalent Spectre netlist and displays the result in the terminal window Spp convert amp sp The following command converts the SPICE netlist amp sp to an equivalent Spectre netlist with the name amp scs Spp convert amp sp gt amp scs The following command converts the SPICE netlist amp sp to an equivalent Spectre netlist with the name test scs All references to amp sp in the input file are replaced by test scs in the output file Spp convert iofile amp sp test scs Converting Hierarchically Arranged Netlists Great care must be taken when converting hierarchically arranged netlists Some of the possible issues include the following m Distinguishing instance models from instance parameters For some devices such as resistors SPICE instance statements can use an order dependent mechanism to define the values of parameters An example could be rl 1 0 myres The field myres could be either a model name or a parameter
188. e 3 sigma variance of dc voltages or currents at the specified outputs due to device mismatches You need to specify the mismatch parameters in the model cards for each device that contributes to the deviation The analysis uses the device January 2004 154 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses mismatch models to evaluate an equivalent mismatch current source that is placed in parallel to the device These current sources have zero mean and some variance The simulation results are displayed in descending order For MOSFET devices bsim3v3 the analysis displays threshold voltage mismatch current factor mismatch gate voltage mismatch and drain current mismatch For bipolar devices vbic it displays base emitter junction voltage mismatch For resistors limited to two terminal resistance it displays resistor mismatches The analysis replaces multiple simulation runs and tedious calculations in the estimation of mismatch performance It automatically identifies the set of critical matched components during circuit design For example when there are matched differential pairs in the circuit the contribution of two matched transistors will be equal in magnitude and opposite in sign Model Definition name pnode nnode dcmatch parameter value Examples of the dcmatch command The following example investigates the 3 sigma dc variation at the output of the current flowing through the device vd which is
189. e Circuit Simulator User Guide Time Saving Techniques If you set this parameter to prevoppoint yes in an analysis statement the Spectre simulator does not compute or recompute the operating point Instead it uses the operating point computed by the previous analysis Saving Time by Specifying State Information The Spectre simulator lets you provide state information the current or last known status or condition of a process transaction or setting to the DC and transient analyses You can specify two kinds of state information B Initial conditions The ic statement lets you specify values for the starting point of a transient analysis The values you can specify are voltages on nodes and capacitors and currents on inductors m Nodesets Nodesets are estimates of the solution you provide for the DC or transient analyses Unlike initial conditions their values have no effect on the final results Nodesets usually act only as aids in speeding convergence but if a circuit has more than one solution as with a latch nodesets can bias the solution to the one closest to the nodeset values Setting Initial Conditions for All Transient Analyses You can specify initial conditions that apply to all transient analyses in a simulation or to a single transient analysis The ic statement and the ic parameter described in this section set initial conditions for all transient analyses in the netlist In general you use the ic parameter of in
190. e Internet You can also get information about the performance of several simulators with these circuits The Spectre circuit simulator has successfully simulated all of these circuits Sometimes the netlists required minor syntax corrections such as inserting balancing parentheses but circuits were never altered and options were never changed to affect convergence January 2004 19 Product Version 5 0 Spectre Circuit Simulator User Guide Introducing the Spectre Circuit Simulator Improved Models The Spectre circuit simulator has MOSFET Level 0 3 BSIM1 BSIM2 BSIM3 BSIM3v3 EKV MOSS JFET TOM2 GaAs MESFET BJT VBIC HBT diode and many other models It also includes the temperature effects noise and MOSFET intrinsic capacitance models The Spectre Compiled Model Interface CMI option lets you integrate new devices into the Spectre simulator using a very powerful efficient and flexible C language interface This CMI option the same one used by Spectre developers lets you install proprietary models Spectre Usability Features and Customer Service The following features and services help you use the Spectre circuit simulator easily and efficiently m You can use Spectre soft limits to catch errors created by typing mistakes B Spectre diagnosis mode available as an options statement parameter gives you information to help diagnose convergence problems m You can run the Spectre circuit simulator standalone or run i
191. e convergence criteria are applied to all nodes in the circuit The output of the gain block meets Kirchhoff s Current Law and delta reltol V about 1 part in 10 by default Because of the gain the input must move by this value divided by the gain If the gain is high for example 109 the input must move less than 1 part in 1011 This is an extremely small motion from iteration to iteration that might not be achievable If the gain is even higher the numerical resolution of the machine might be approached About 15 digits of resolution is available in a 64 bit floating point number In this case the gain needs to be reduced Note In this case one node the output controls convergence and all the other nodes are more accurate than the convergence criteria by itself would predict This is typical for most circuits Enable the topology checker set topcheck fu11 onthe opt ions statement and pay attention to any warnings Increase maxiters for the DC analysis If you have convergence problems during a DC sweep reduce the step size Check for unusual parameter values using the parameter range checker add param param limits filetothe spectre command line arguments and pay attention to any warnings Print out the minimum and maximum parameter values by placing an info statement in the netlist Make sure that the values for the instance model output temperature dependent and if possible operating point parameters are reasonable
192. e simulator includes the instance statement for capacitor c 1 lf rseries is zero and gparallel is nonzero the Spectre simulator includes the instance statements for capacitor c1 and resistor gp1 If rseries is nonzero and gparallel is zero the Spectre simulator includes the instance statements for resistor r2 and capacitor c2 If neither rseries norgparallel is zero the Spectre simulator includes the instance statements for resistor r2 capacitor c2 and resistor gp2 Rules to Remember When you use the if statement If the statement1 or statement 2 fields contain multiple statements place these fields within braces End the statement 1 and statement 2 fields with newlines Use a continuation character if you want to place a newline between the i f and condition statements When the statement1 or statement 2 field is a single instance or i statement an else statement is associated with the closest previous i f statement Binning by Conditional Instantiation You can use conditional instantiation to select an appropriate model based on certain ranges of specified parameters model binning This technique lets you decide and implement which parameters to bin on and is valid for any device that supports a model The Spectre Netlist Language has conditional instantiation For example subckt sl dg s b parameters l 1u w 1u if 1 lt 0 5u ml dg s b shortmod 1 1 w w short channel model else 4
193. easure In the above example this would be opamp measure Notice that when specifying the measure option you must also specify the design option to identify the netlist All other command line options are passed to Spectre Type spectrespp usage for online help Using the SPICE Reader to Convert Netlists In many cases the SPICE data to be used with Spectre is a library of models or reusable blocks that is subcircuits Rather than using the SPICE Reader to interpret these files each time they are used you can convert the netlist to Spectre s native syntax This is done by running the SPICE Reader alone spp and using the convert option The convert option removes special embedded codes for tracking the line numbers of the original netlist returning a cleanly converted netlist spp convert iofile inputFile outputFile or Spp convert lt inputFile gt outputFile where spp Runs the SPICE reader convert Converts the SPICE netlist to an equivalent Spectre netlist This option does not descend into included files to convert them but only converts the include statement Included files must be converted independently In this case the SPICE Reader cannot always resolve conflicts and ambiguities and you must verify the resulting netlist files January 2004 44 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility iofile Replaces all instances of the input file name in includ
194. eate filenames that are variants of input filenames For example with Spectre you can m Identify simulation data by date time process ID or other defining characteristics in the results filenames B Keep multiple circuits in a single directory without having subsequent simulations overwrite previous results To do this you set environment variables so that output filenames are automatically different variants of input filenames m Construct filenames at run time This is convenient if your input data comes from several files For example you can use an include statement to insert several different circuit files into main input files that each contain analyses Each circuit file can also be used with several stimulus files To prevent confusion you can create filenames at run time for the stimulus files that associate them with the appropriate main input files In this section you will learn how to use the various Spectre features for creating filenames Creating Filenames by Modifying Input Filenames The Spectre simulator gives you predefined percent codes you can put in your filenames These predefined codes let you construct filenames that add defining characteristics such as date or time to input filenames You specify predefined percent codes with a percent character followed by an uppercase letter The uppercase letter tells the Spectre simulator January 2004 269 Product Version 5 0 Spectre Circuit Simulator User Guide
195. ecify single components within a circuit you must provide the following information m A unique component name for the component m The names of nodes to which the component is connected B The master name of the component identifies the type of component B The parameter values associated with the component A typical Spectre instance statement looks like this Component name gt R16 4 0 resistor r 100 Parameter value Node names u t Master name Note You can use balanced parentheses to distinguish the various parts of the instance statement although they are optional R1 1 2 resistor r 1 Q1 c b e s npn area 10 Gm 1 2 3 4 vccs gm 01 R7 x y rmod r 1k w 2u Component Names Unlike SPICE the first character of the component name has no special meaning You can use any character to start the component name For example January 2004 30 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre Load out o resistor r 50 Balun in o pout nout transformer Note You can find the exact format for any component in the parameter listings for that component in the Spectre online help Master Names The type of a component depends on the name of the master not on the first letter of the component name as in SPICE this feature gives you more flexibility in naming components The master can be a built in primitive a model a
196. ecifying Output Options Output parameters are those the simulator computes such as temperature dependent parameters and the effective length of a MOSFET after scaling B Operating point parameters Operating point parameters are those that depend on the operating point You can also list the minimum and maximum values for the input output and operating point parameters along with the names of the components that have those values Specifying the Parameters You Want to Save You specify parameters you want to save with the info statement what parameter You can give this parameter the following settings Setting Action none Lists no parameters inst Lists input parameters for instances of all components models Lists input parameters for models of all components input Lists input parameters for instances and models of all components output Lists effective and temperature dependent parameter values all Lists input and output parameter values oppoint Lists operating point parameters terminals The output is a node to terminal map nodes The output is a terminal to node map The info statement gives you some additional options You can use the save parameter of the info statement to specify groups of signals whose values you want to list For more information about save parameter options consult Saving Groups of Signals on page 229 Finally you can generate a summary of maximum and minimum parameter values with the
197. ed it is set to the default for the parameter Changing Parameter Values for Models To change a parameter value for model files with the altergroup statement you list the device model and circuit parameter statements as you do in the main netlist Within an alter group each model is first defaulted and then the model parameters are updated You cannot nest alter groups You cannot change from a model to a model group and vice versa The following example demonstrates altergroup statement syntax agl altergroup parameters pl 1 model myres resistor rl le3 af pl model mybsim bsim3v3 lmax pl lmin 3 5e 7 January 2004 265 Product Version 5 0 Spectre Circuit Simulator User Guide Time Saving Techniques Further Examples of Changing Component Parameter Values This example changes the is parameter of a model named SH3 to the value 1e 15 modify2 alter mod SH3 param is value 1e 15 The following examples show how to use the param default in an alter statement The first parameter listed for resistors in the Spectre online help spectre h is the default For resistors this is the resistance parameter r Consequently if R1 is a resistor the following two alter statements are equivalent changel alter dev R1 param r value 50 changel alter dev R1 value 50 Changing Parameter Values for Circuits When you change a circuit parameter you use the same syntax as when you change a device or model parameter except that you do n
198. ed by m Remember the following rules when you use the multiplication factor m You can use m only as an instance parameter not as a model parameter m Them value need not be an integer The m value can be any positive real number B The multiplication factor does not affect short channel or narrow gate effects in MOSFETSs B Ifyou use the m factor with components that naturally compute branch currents such as voltage sources and current probes the computed current is divided by m Terminal currents are unaffected m You can set the built in m factor property on a subcircuit to a parameter and then alter it Example of Using m to Specify Parallel Components In the following example a single instance statement specifies four 4000 Ohm resistors in parallel Ro d c resistor r 4k m 4 The preceding statement is equivalent to Ro d c resistor r l1k Specifying Subcircuits in Parallel If you place a multiplication factor parameter in a subcircuit call you model m copies of the subcircuit in parallel For example suppose you define the following subcircuit subckt LoadOutput a b rl a b resistor r 50k cl a b capacitor c 2pF ends LoadOutput If you place the following subcircuit call in your netlist the Spectre simulator models five LoadOutput cells in parallel January 2004 65 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists x1 out 0 LoadOutput m 5 Analysis Statements In th
199. els frequency conversion effects For more information about the periodic AC analysis see SpectreRF Help Q Periodic distortion analysis pdisto Models periodic distortion and includes harmonic effects pdisto computes both a large signal the periodic steady state response of the circuit and also the distortion effects of a specified number of moderate signals including the distortion effects of the number of harmonics that you choose For more information about the periodic distortion analysis see SpectreRF Help Q Periodic noise analysis pnoise After the periodic steady state analysis computes a periodic solution this analysis linearizes the circuit about the periodic steady state and performs a small signal analysis The small signal analysis January 2004 132 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses computes the total noise spectral density at the output If you specify an input probe the transfer function and the input noise for an equivalent noise free network are computed pnoise is like noise except it models frequency conversion effects and the effect of time varying bias on noise sources For more information about the periodic noise analysis see SpectreRF Help Q Periodic steady state analysis p s s Computes the periodic steady state response of a circuit at either a given fundamental frequency or the corresponding steady state analysis period The pss analysis also determines the cir
200. ements in SPICE are mapped into multiple statements in Spectre Things like temp sweeps analysis sweeps and alter sections all get converted into multiline statements If temp statements analysis statements or alter statements are not in the same file they might not get properly unfolded Here is an example of a Mos characterization deck written in SPICE MI 12 0 0 NCH VDR 102 VG 20 1 OP MODEL NCH NMOS LEVEL 49 TOX 1e 9 VTHO 0 5 VBOX 5 TEMP 25 75 100 INCLUDE dcAnalysis inc END where dcAnalysis inc Is DC VDR 0 5 0 1 VG 02 0 1 The netlist produced with spp convert does not include the sweep statement within the temperature sweep Mos characterization deck Simulator lang spectre insensitive yes ml 1200 nch vdr 10 vsource dc 2 vg 20 vsource dc 1 model nch bsim3v3 type n tox le 9 vth0 20 5 vbox 5 include dcAnalysis inc swp tmpl sweep param temp values 25 75 100 sppSaveOptions options save allpub analysisOP1 dc oppoint logfile end You need to edit the netlist to insert the included analysis into the temperature sweep Mos characterization deck simulator lang spectre insensitive yes ml 1200 nch vdr 10 vsource dc 2 vg 20 vsource dc 1 model nch bsim3v3 type n tox 1e 9 vth020 5 vbox 5 swp tmpl sweep param temp values 25 75 100 SppSaveOptions options save allpub analysisOP1 dc oppoint logfile analysisDCswpl sweep param dc dev
201. emp gt 27 C 0 99 0 84 I xJetco Slow models model slow 1x1 mos3 type n vto temp gt 27 C 0 92 0 76 etc model slow 1x3 mos3 type n vto temp gt 27 C 0 93 0 74 etc model slow 3x1 mos3 type n vto temp gt 27 C 0 98 0 718 77 22 eke model slow 3x3 mos3 type n vto temp 27 C 0 98 0 89 etc The following file select models scs uses the structural if statement to select models based on parameters 1 and w Note that for MOS devices this could also be achieved by using auto model selection see spectre h mos3 but this example illustrates model binning and model selection based on the structural i statement which can be used to bin based on any combination of parameters not necessarily predefined device geometry models and for any device type that is not limited to MOS devices only library select models section fast select models for fast device based on subckt parameters l w if 1 lt 3um if w lt 3um nmos dg s b fast 1xl l l1 w w ls l1s ld ld else nmos dg s b fast 1x3 l 1 w w ls ls ld ld January 2004 117 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features else if w lt 3um nmos dg s b fast_3x1l 1 1 w w ls ls ld ld else nmos dg s b fast 3x3 l 1 w w ls ls ld 1d endsection fast section typica
202. en any parameters accessible within the scope of s1 are also accessible from within s2 Also any parameters declared within the top level circuit description are also accessible within both s1 and s2 However any subcircuit definition can redefine a parameter that it inherited In this case if no value is specified for the redefined parameter when the subcircuit is instantiated then the redefined parameter uses the locally defined default value rather than inheriting the actual parameter value from the parent See how the r2 resistor is used in the examples in Circuit and Subcircuit Parameters on page 85 Parameter Referencing Spectre netlist parameters can be referenced anywhere that a numeric value is normally specified on the right hand side of an sign or within a vector where the vector itself is on the right hand side of an sign This includes referencing of parameters in expressions run spectre h expressions for more details on netlist expression handling as indicated in the preceding examples You can use expressions containing parameter references when specifying component or analysis parameter values for example specifying the resistance of a resistor or the stop time of a transient analysis as outlined in the preceding example when specifying model parameter values in model statements for example specifying bf p1 0 8 for a bipolar model parameter bf or when specifying initial conditions and nodesets for individual cir
203. en operating condition Operating the device anywhere except in the saturation region triggers a warning The warning looks like the following Warning detected by spectre during transient analysis timesweep M1 Device operated in the triode region Defining BJT Operating Regions The Spectre simulator provides two parameters vbe fwd and vbc fwa that let you specify the boundaries between BJT operating regions The default value for each parameter is 0 2 volts The following table shows you the criteria the Spectre simulator uses to determine BJT operating regions Region Bias Conditions off Vbe lt vbefwd and V5 lt vbcfwd saturation Vbe gt vbe wd and Vp gt vbcfwd forward Vbe gt vbefwd and Vp lt vbcfwd reverse Vbe lt vbe fwd and Vp gt vbcfwd Range Checking on Subcircuit Parameters You can test the value of subcircuit parameters with the paramtest component If the parameters meet your testing criteria you can print an informational message print a warning or print an error message and terminate the program Formatting the paramtest Component The paramtest component has the following format Name paramtest parameter value B Name is your unique name for this paramtest component m The keyword paramtest is the component keyword for the component B The parameters specify the tests that are applied to the parameters the action taken if parameters satisfy the test conditions and the text o
204. ench design system You can also use the Spectre circuit simulator by itself with several different output format options Assura interactive verification Dracula distributed multi CPU option and Assura hierarchical physical verification produce a netlist that can be read into the Spectre circuit January 2004 23 Product Version 5 0 Spectre Circuit Simulator User Guide Introducing the Spectre Circuit Simulator simulator However only interactive verification when used with the Cadence analog design environment automatically attaches the stimulus file All other situations require a stimulus file as well as device models January 2004 24 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre This chapter discusses the following topics Using the Example and Displaying Results on page 26 Sample Schematic on page 26 Sample Netlist on page 28 Instructions for a Spectre Simulation Run on page 32 Viewing Your Output on page 34 January 2004 25 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre Using the Example and Displaying Results In this chapter you examine a schematic and its Spectre circuit simulator netlist to get an overview of Spectre syntax You also follow a sample circuit simulation The best way to use this chapter depends on your past experience with simulators Carefully examine the schematic Sample Schematic on page
205. end January 2004 181 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses The save statement in the previous netlist saves the waveforms of the substrate current the stress and the effective device age for transistor m1 in the x1 subcircuit These waveforms are shown in Figure 6 1 on page 182 Figure 6 2 on page 182 and Figure 6 3 on page 183 The ring oscillator output waveform is shown before and after degradation in Figure 6 4 on page 183 Figure 6 1 Transistor m1 Substrate Current 0 20 0 15 1 Substrate Current 0 10 uA 0 05 0 0 0 0 0 002 0 004 0 006 0 008 0 010 Time usec Figure 6 2 Transistor m1 Stress 0 025 0 020 Stress 0 015 0 010 0 005 f 0 0 0 002 0 004 0 006 0 008 0 010 Time usec January 2004 182 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Figure 6 3 Transistor m1 Effective Device Age 4 00e 18 3 00e 18 Age Sec 2 00e 18r 1 00e 18 t 0 00e 00 0 0 0 002 0 004 0 006 0 008 0 010 Time usec Figure 6 4 Oscillator Output at Two Different Ages 6 0 4 0 Vout 2 0 0 0 2 0 i i i 0 0 0 002 0 004 0 006 0 008 0 010 Time usec The Spectre simulator also creates two files called moslev3_dgt_0 and moslev3_dgt_4 0 These files are the sorted tables that contain the results of hot electron analysis The filenames show that the outputs are for level 3 MOSFETs The numbers 0 and 4 0 in
206. ent Codes on page 270 in the filename to prevent the file from being overwritten For example the following info statement tempSweep sweep param temp start 27 stop 127 step 10 dcl dc dcInfo info what oppoint where file file infodata A produces infodata tempSweep 000 dcInfo infodata tempSweep 001 dcInfo infodata tempSweep 002 dcInfo infodata tempSweep 003 dcInfo and so on Examples of the info Statement You format the info statement as follows StatementName info parameter value The following example tells the Spectre simulator to send the maximum and minimum input parameters for all models to a log file Inparams info what models where logfile extremes only For a complete description of the parameters available with the info statement consult the lists of analysis and control statement parameters in the Spectre online help spectre h January 2004 204 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Printing the Node Capacitance Table The Spectre simulator allows you to print node capacitance to an output file This can help you in identifying possible causes of circuit performance problems due to capacitive loading The capacitance between nodes x and y is defined as where q is the sum of all charges in the terminal connected to node x and vy is the voltage at node y The total capacitance at node X is defined as where charge q and voltage vy are at the
207. ent exceeds imelt The results computed by Spectre are now incorrect because the junction current model has been linearized Or xram d3247 The junction is melting increase imax The Spectre simulator provides two parameters imax and imelt that limit the current across a PN junction These parameters aid convergence and prevent numerical overflow January 2004 278 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting The junction characteristics of the device are assumed to be accurately modeled for current up to imax If imax is exceeded during iterations the linear model is substituted until the current drops below imax or until convergence is achieved If convergence is achieved with the current exceeding imax the results are inaccurate and Spectre prints a warning similar to the first one above The imelt parameter is used as a limit warning for the junction current This parameter can be set to the maximum current rating of the device By default it is set to the value of imax When any component of the junction current exceeds imelt Spectre issues a warning and again the results become inaccurate The junction current is linearized above the value of imelt to prevent arithmetic exceptions Both these parameters have current density counterparts jmax and jme1t that you can specify if you want the absolute current values to depend on the device area For more info
208. ent simulation the results output is written to a file named Netlist measure For example say that you have an SPICE netlist named amp sp In order to convert this netlist without executing the simulation use spp with the convert option Spp convert amp sp gt amp scs Upon completion of this command the Spectre equivalent for amp sp is in the amp scs file In addition a file called Net 1ist mdl is created This additional file contains the MDL expressions that correspond to any measure statements in the original netlist In order to run the Spectre simulation using the new netlist and control file use the following command spectremdl batch Netlist mdl design amp scs Upon completion of the simulation you ll find a file named Net list measure which contains the values calculated for each of the MDL expressions For more information on the expression evaluation capabilities in Spectre see the SpectreMDL User Guide and Reference W Netlist parameters In Spectre parameters are order dependent that is they must be defined before being used When the SPICE Reader is run on the entire design parameters are moved to the top of the netlist but in convert mode they are moved to the top of each file If a parameter is accessed before inclusion it will fail until it is fixed m Order dependent statements January 2004 46 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility Some stat
209. eplace Location Wscrm e 7 exportihome shikha testiosc raw H OscResp tran Filter a m January 2004 34 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre Plotting Signals 1 In the Results Browser window double click on osc raw The data directory moves to the left panel and the associated signals are displayed in the right panel Results Browser Jo File Settings Tools Help ge iE D AE Location osc raw Ci exportihorne shikhartestiosc raw C OscResp tran Filter m B J January 2004 35 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre 2 Right click on the signal you want to plot for example out and choose New Win from the pop up menu The Graph Display window appears eB Aug 20 2003 out Graph Display Bi File Edit Graph Axis Trace Marker Zoom Tools Help Transient Analysis OscResp time 0 s 80 us v Labet 12 10 8 0 6 0 yow 4 0 2 0 0 0 0 0 o 10 rr 30 40 50 60 70 80 time us IF traceD out 3 Choose Zoom X Zoom The e cursor is displayed on the Graph Display window 4 Left click at around 70us and drag and release the mouse button at around 80us January 2004 36 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started
210. equest that mismatch variations be applied unless you have specified mismatch statistics in the statistics block mismatch variations work only on components inside of subcircuits You cannot request that process variations be applied unless you have specified process statistics in the statistics block More details on statistics blocks are given in Specifying Parameter Distributions Using Statistics Blocks on page 173 169 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Parameter Description donominal appendsd January 2004 This flag determines whether a nominal run of all child analyses is performed yes or no before starting the Monte Carlo runs The default is yes If the flag is set to yes and the Spectre simulator cannot calculate an output expression during the nominal run for example convergence problems or incorrect export expressions the Spectre simulator issues an error message and immediately exits the Monte Carlo analysis If donominal is set to no the Spectre simulator runs the Monte Carlo iterations without performing a nominal analysis If there are convergence problems or the output expressions cannot be successfully calculated for the first or any iteration the Spectre simulator issues a warning and continues with the next iteration of the Monte Carlo loop This specifies whether to append scalar data to the existing scalarfile yes or to overwrite the existing file
211. er Guide Analyses You cannot apply data compression to operating point parameters including terminal currents that are calculated internally rather than with current probes If you want data compression for terminal currents you must specify that these currents be calculated with current probes You can specify that all currents be calculated with current probes by placing useprobes yes in an options statement d Important Adding probes to circuits that are sensitive to numerical noise might affect the solution In such cases an accurate solution might be obtained by reducing reltol Telling Spectre to Save Operating Point Data at Specific Times In addition to saving operating point data in a ac analysis Spectre allows this data to be saved during a transient analysis This data is saved as a waveform and can be plotted along with node voltages and other output data See Chapter 8 Specifying Output Options to learn how to select and save this data Often all that is needed is the operating data at specific times which can be achieved by linking an info analysis with the tran analysis To control the amount of data produced for operating point parameters use the following two transient analysis parameters to specify at which time points you would like to save operating point output for all devices infotimes vector of numbers infoname analysis name where analysis name points to an info analysis For example mytran
212. er required characters exactly as shown References Text within brackets is a reference See Appendix A References of the Spectre Circuit Simulator Reference manual for more detailed information January 2004 15 Product Version 5 0 Spectre Circuit Simulator User Guide 1 Introducing the Spectre Circuit Simulator This chapter discusses the following Improvements over SPICE on page 17 Analog HDLs on page 21 RF Capabilities on page 21 Mixed Signal Simulation on page 23 Environments on page 23 The Spectre circuit simulator is a modern circuit simulator that uses direct methods to simulate analog and digital circuits at the differential equation level The basic capabilities of the Spectre circuit simulator are similar in function and application to SPICE but the Spectre circuit simulator is not descended from SPICE The Spectre and SPICE simulators use the same basic algorithms such as implicit integration methods Newton Raphson and direct matrix solution but every algorithm is newly implemented Spectre algorithms the best currently available give you an improved simulator that is faster more accurate more reliable and more flexible than previous SPICE like simulators January 2004 16 Product Version 5 0 Spectre Circuit Simulator User Guide Introducing the Spectre Circuit Simulator Improvements over SPICE The Spectre circuit simulator has many improvements over SPICE Improved Capa
213. ere is no component between A and B there is no other way to measure this current except to insert a current probe that has an identical current to the one you want to measure A B Current probe inserted to measure current from A to B Probe Statement Example To specify a current probe place a statement with the following syntax in your netlist Name in out iprobe B Name isthe unique netlist name for the current probe component The measured current also receives this name WB inisthe name you choose for the input node of the probe B out isthe name you choose for the output node of the probe B The keyword iprobe is the primitive name of the component In the following example the current probe measures the current between nodes src and in names the measured current Iin and saves Iin to the raw file Iin src in iprobe Note You can also direct the Spectre simulator to save currents with probes with a save statement option For further information see the description of save statement keywords in this chapter January 2004 227 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options Saving Power To save power dissipated on a circuit subcircuit or device you use the pwr parameter Power is calculated only during DC and transient analyses The results are saved as a waveform representing the instantaneous
214. erence manual parameteri valuel XparameterN valueN This is an optional field you can repeat any number of times in a model statement Each parameter specification is a model parameter followed by an equal sign followed by the value of the parameter You can find a list of the available model parameters for each component in the parameter listings of Spectre online help spectre h Examples of model Statements The following examples give parameters for a t 1 ine model named tuner and ab jt model named NPNbjt model tuner tline f 1MHz alphac 9 102m dcr 105m model NPNbjt bjt type npn bf 100 js 0 1fA Note The backslash is used as a continuation character in this lengthy mode1 statement model NPNbjt2 bjt type npn is 3 38e 17 bf 205 nf 0 978 vaf 22 ikf 2 05e 2 ise 0 ne 1 5 br 62 nr 1 var 2 2 isc 0 nc 1 5 rb 115 re 1 rc 30 5 cje 1 08e 13 vje 0 995 mje 0 46 tf 1le 11 xtf 1 itf 1 5e 2 cjc 2 2e 13 vjc 0 42 mjc 0 22 xcjc 0 1 tr 4e 10 cjs 1 29e 13 vjs 0 65 mjs 0 31 xtb 1 5 eg 1 232 xti 2 148 fc 0 875 The following example creates two instances of a bjt transistor model al C Bl E S NPNbjt a2 C B2 E S NPNbjt2 January 2004 71 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Basic model Statement Rules When you use the model statement m You can have several model statements for a particular component type but each instance
215. ersion 5 0 Spectre Circuit Simulator User Guide Example Circuits alterTempTol00 alter param temp value 100 ss_tran tran step 0 010n stop 35n myAlter2 altergroup include q35d4h5 modsp section ff parameters vdd_S1 3 3 alterTempTo0 alter param temp value 0 ff tran tran step 0 010n stop 35n Ring Oscillator Spectre Deck for Two Input NOR Ring with No Fanouts nor2 ring sp This example uses Spectre syntax Ring oscillator Spectre deck for 2 Input NOR ring with no fanouts simulator lang spectre global 0 gnd vdd vss aliasGnd gnd 0 vsource type dc dc 0 Spectre options SetOptionl options iabstol 1 00n audit full MyAcctl info what inst extremes yes MyAcct2 info what models extremes yes MyAcct3 info what input extremes yes MyAcct5 info what terminals extremes yes yAcct6 info what oppoint extremes yes Next section is the subckt for no2 subckt no2 nga ml vdd a 6 vdd p 1 0 35u w 4 80u ad 3 50p pd 11 06u as 0 50p ps 5 01u m2 nq vss 6 vdd p 1 0 35u w 4 80u ad 3 50p pd 11 06u as 0 50p ps 5 01u m3 vss a nq vss n 1 0 35u w 1 20u ad 0 88p pd 3 86u as 0 46p ps 1 96u m4 vss vss nq vss n 120 35u w 1 20u ad 0 88p pd 3 86u as 0 46p ps 1 96u cO a vdd capacitor c 6 3676066e 16 cl ang capacitor c 5 3592e 17 c2 vdd vss capacitor c 5 39538e 16 c3 nq vss capacitor c 8 780327e 16 c4 nq vdd capacitor c 5 577428e 16 c5 a vss capacitor c 1 110039
216. es Messages i es REIR Sed we eee aa ts POR SESE 283 Initial Condition Messages 9 va este edge RETE E MS he NE eee o odi eie 283 O tp t Messages svarar osea he eto teen e e pt oe i ed f 283 Customizing Error and Warning Messages lssseells 284 Selecting Limits for Parameter Value Warning Messages 284 Selecting Limits for Operating Region Warnings sss 291 Range Checking on Subcircuit Parameters 00 cee 292 Formatting the paramtest Component 00 eee 292 Controlling Program Generated Messages lsseeelss 294 Specifying Log File Options 2529 DELE e dex eR RR on koe oe 294 Correcting Convergence Problems 1 cece eee 295 Correcting DC Convergence Problems 0 0 ees 295 January 2004 11 Product Version 5 0 Spectre Circuit Simulator User Guide Correcting Transient Analysis Convergence Problems 298 Correcting Accuracy Problems decer rec arr EE ciii o E ag aig vea e ED ee oD 298 Suggestions for Improving DC Analysis Accuracy 0000 cena 298 Suggestions for Improving Transient Analysis Accuracy LL 299 A Example CIrGUIIS odor eese Rr dee und IV Debe 300 Notes on the BSIM3v3 Model e 301 Spectre Syak pee doeduck uua ane E ES Bears en hace I uA LP Ir EIA E MR pL Ras 301 SPIGE Boll 3V9S MOGBL s uui ruta ERES PS RUD I SCENE
217. es are either Q Multiple data producing child analyses such as DC or AC analyses Q A single sweep child analysis which itself has child analyses Calculates the export quantities Each Monte Carlo run processes export statements that implicitly refer to the result of the child analyses These statements calculate scalar circuit output values for performance characteristics such as slew rate Organizes the export data appropriately Scalar data such as bandwidth or slew rate is calculated from an export statement and saved to an ASCII file which can be used later for plotting a histogram or scattergram After the Monte Carlo analysis is complete all parameters are returned to their original values January 2004 165 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Monte Carlo Analysis Parameters You use the following parameters for your Monte Carlo analysis Parameter Description numruns This is the number of Monte Carlo runs to perform not including the nominal run The default is 100 runs The Spectre simulator performs a loop running the specified child analyses numruns times or numruns 1 times if the donominal parameter is set to yes and evaluating any export statements numruns times seed This is the optional starting seed for the random number generator By always specifying the same seed you can reproduce a previous experiment If you do not specify a seed then each time that you
218. esistor r pl another simple expression r2 0 resistor r p2 p2 a binary multiply expression r3 1 0 resistor r pl p2 p3 a more complex expression r4 1 0 resistor r sqrt pl p2 an algebraic function call r5 0 resistor r 3 atan pl p2 a trigonometric function call r6 0 RESMOD r pl p441 p3 the ternary operator ends a model statement containing expressions model RESMOD resistor tcl pl p2 tc2 sqrt pl p2 some expressions used with analysis parameters time sweep tran start 0 stop pl p2 50e 6 use 5 50e 6 150 us a vector of expressions see notes on vectors below dc sweep dc param pl values 0 5 1 p2 sqrt p2 p2 sweep pl Where Expressions Can Be Used The Spectre Netlist Language allows expressions to be used where numeric values are expected on the right hand side of an sign or within a vector where the vector itself is on the right hand side of an sign Expressions can be used when specifying component or analysis instance parameter values for example specifying the resistance of a resistor or the stop time of a transient analysis as outlined in the preceding example when specifying model parameter values in model statements for example specifying bf p1 0 8 fora bipolar model parameter b or when specifying initial conditions and nodesets for individual circuit nodes Operators The operators in the following table are supported listed in order of decreasing precedenc
219. eter name with no dev mod Or sub parameter You can sweep a subcircuit parameter for a particular subcircuit instance by specifying the subcircuit instance name with the sub parameter and the subcircuit parameter name with the param parameter After the analysis has completed the modified parameter returns to its original value The syntax is as follows Name dc parameter value You can specify sweep limits by giving the end points or by providing the center value and the span of the sweep Steps can be linear or logarithmic and you can specify the number of steps or the size of each step You can give a step size parameter step lin log dec and determine whether the sweep is linear or logarithmic If you do not give a step size parameter the sweep is linear when the ratio of stop to start values is less than 10 and logarithmic when this ratio is 10 or greater If you specify the oppoint parameter Spectre computes and outputs the linearized model for each nonlinear component Nodesets help find the DC or initial transient solution You can supply them in the circuit description file with nodeset statements or in a separate file using the readns parameter January 2004 139 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses When nodesets are given Spectre computes an initial guess of the solution by performing a DC analysis while forcing the specified values onto nodes by using a voltage source in series with a
220. f 0 3ns tr 6ns cje 3pf cjc 2pf OscResp tran stop 80us maxstep 10ns 24 Analysis statement Elements of a Spectre Netlist This section briefly explains the components models analyses and control statements in a Spectre netlist All topics discussed here such as model statements or the simulator lang command are presented in greater depth in later chapters If you want more complete reference information about a topic consult these discussions Title Line The first line is taken to be the title It is used verbatim when labeling output Any statement you place in the first line is ignored as a comment For more information about comment lines see Basic Syntax Rules on page 59 January 2004 29 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre Simulation Language The second line of the sample netlist indicates that the netlist is in the Spectre Netlist Language instead of SPICE For more information about the simulator lang command see Spectre Language Modes on page 59 Instance Statements The next section in the sample netlist consists of instance statements To specify a single component in a Spectre netlist you place all the necessary information for the component in a netlist statement Netlist statements that specify single components are called instance statements The instance statement also has other uses that are described in Chapter 4 Spectre Netlists To sp
221. f inline subcircuits never existed Typically a modeling engineer writes inline subcircuit definitions for a circuit design engineer to use Modeling Parasitics You can model parasitics by adding parasitics components to a base component using inline subcircuits The body of the inline subcircuit contains one inline component the base component and several regular components which are taken to represent parasitics The following example of an inline subcircuit contains a MOSFET instance and two parasitic capacitances inline subckt sl a b si is name of subcircuit parameters l 1u w 2u sl ab 0 0 mos mod 1 1 w w s1 is inline component capl a 0 capacitor c 1n cap2 b 0 capacitor c 1n ends sl The following circuit creates a simple MOS device instance M1 and calls the inline subcircuit sl twice M2 and M3 M1 210 0 mos mod 2 5 6 sl 1 6u w 7u M3 6 7 sl This circuit flattens to the following equivalent circuit 1 2 1 0 0 mos mod 2 5 6 0 0 mos_mod 1 6u w 7u the inline component inherits call name 2 capl 5 0 capacitor c 1n a regular hierarchical name 2 cap2 6 0 capacitor c 1n 3 6 7 0 0 mos mod 1 1u w 2u the inline component inherits call name capl 6 0 capacitor c 1n cap2 7 0 capacitor c 1n 3 3 The final flattened names of each of the three MOSFET instances are M1 M2 and v3 If s1 was a regular subcircuit the final flattened names wou
222. f the message that is printed when parameters satisfy the test conditions January 2004 292 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Rules and Guidelines to Remember B f you specify more than one test the conditional action is taken if any test passes B If you use the paramtest component without specifying test conditions the specified actions are taken and the message is printed unconditionally This option is useful for using the paramtest component with the i statement The paramtest instruction can be followed whenever a given if statement option is executed The paramtest Options The following table explains the possible paramtest options Parameter Instruction printif Informational message is printed if test condition is satisfied warnif Warning is printed if test condition is satisfied errorif Program quits and error message is printed if testing condition is satisfied message Parameter value is the message text severity You set this parameter when you use paramtest without a test condition It specifies the type of message printed and the action to be taken if any The possible values are debug status warning error and fatal If you specify error the current analysis quits with an error message If you specify fatal the whole simulation stops A paramtest Example This example uses three consecutive paramtest statements to check the v
223. fied to those parameters for each subcircuit instance If the export statements are specified the corresponding performance measurements are saved as a new file or appended to an existing file The following Monte Carlo analysis statement specifies using the default that a nominal analysis is performed first The sweep analysis and all child analyses are performed and export statements are evaluated If the nominal analysis fails the Spectre simulator gives an error message and will not perform the Monte Carlo analysis If the nominal analysis succeeds the Spectre simulator immediately starts the Monte Carlo analysis The variations parameter specifies that only process variations variations process are applied this is useful for looking at absolute performance spreads There is a single child sweep analysis sw1 so that for each Monte Carlo run the Spectre simulator sweeps the temperature performs the dc and transient analyses and calculates the slew rate The output of the slew rate calculation is saved in the scalar data file mcl montecarlo variations process seed 1234 numruns 200 swl sweep param temp values 50 27 100 dcopl dc a child analysis tranl tran start 0 stop 1u another child analysis export calculations are sent to the scalardata file export slewrate oceanEval SslewRate v vout 10n t 30n t 10 90 The following Monte Carlo analysis statement applies only mismatch variations which
224. fields are limited to a maximum of 8 characters The Spectre netlister allows each of these fields to be greater than 200 characters In the SPICE language instance statements often have their parameter values listed in a particular order In the Spectre language you can specify parameter values in any order using parameter name This allows for a more readable netlist Spectre netlists are case sensitive and use lower case for all keywords SPICE netlists are case insensitive This means that you can name one model myMode1 and another mymodel and Spectre treats them as two distinct models In SPICE they would be considered to be the same model Spectre always tries to match the case of a model subcircuit s name when there is a call to a model subcircuit from an instance line an alter statement or other part of the netlist During the netlist conversion process the SPICE Reader converts included models subcircuits to lower case which can prevent Spectre from identifying the right model subcircuit for a given device For this reason the SPICE Reader will insert the flag insensitive yes at the beginning of each converted netlist on the simulator command statement that is simulator lang spectre insensitive yes The insensitive yes language directive marks the models subcircuits that were converted so that Spectre can perform a lower case compare Because the SPICE language is case insensitive the scale factors are different from the
225. filenames you can generate from an input filename C of users maxwell circuits opamp ckt Colon Modifier Comments Output Filename Result amp C Input filename users maxwell circuits opamp ckt Sor Root of the input filename users maxwell circuits opamp C e Extension of the input ckt filename C h Head of the input filename users maxwell circuits SC t Tail of the input filename opamp ckt C Second colon is appended users maxwell circuits to the input filename and opamp ckt the end of the modification C h h The head of C h sucha users maxwell recursive use of h might be useful if you want to direct your output to a different directory from that of the input file SOHEPE The root of C t opamp SC r t The tail of C r opamp tmp C t r raw The suffix raw is tmp opamp raw appended to the root of C t and the full path is altered to put opamp raw in the tmp file C e C r t Extension of C followed by ckt opamp the tail of C r January 2004 274 Product Version 5 0 Spectre Circuit Simulator User Guide 13 Identifying Problems and Troubleshooting This chapter discusses the following topics Error Conditions on page 275 Spectre Warning Messages on page 278 Customizing Error and Warning Messages on page 284 Controlling Program Generated Messages on page 294 Correcting Convergence Problems on page 295 Correcting Accuracy Problems on page 298 Error Conditions
226. for dec and log are used to specify log sweeps logarithmic sweeps log Number of steps for logarithmic sweeps default is 50 values Array of sweep values values specifies each sweep value with a vector of values If you do not specify the step size the sweep is linear when the ratio of the stop to the start values is less than 10 and logarithmic when this ratio is 10 or greater If you specify sweep limits and a values array the points for both are merged and sorted Examples of Parameter Sweep Requests This sweep statement uses braces to bound the child analyses statements swp sweep param temp values 50 0 50 100 125 oppoint dc oppoint logfile This statement specifies a linear sweep of frequencies from 0 to 0 3 MHz with 100 steps Sparams sp stop 0 3MHz lin 100 The previous statement could be written like this and achieve the same result Sparams sp center 0 15MHz span 0 3MHz lin 100 This statement specifies a logarithmic sweep of frequencies from 1 kHz through 1 GHz with 10 steps per decade January 2004 163 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses cmLoopGain ac start 1k stop 1G dec 10 This statement is identical to the previous one except that the number of steps is set to 55 cmLoopGain ac start 1k stop 1G log 55 This statement specifies a linear sweep of temperatures from 0 to 50 degrees in 1 degree steps The frequency for the analysis is 1 kHz XferVsTemp xf start 0 stop 50
227. framework II To see how the Spectre circuit simulator is run under the analog circuit design environment read the Cadence Analog Design Environment User Guide m Tlolearn more about specific parameters of components and analyses consult the Spectre online help spectre h orthe Spectre Circuit Simulator Reference manual B Tlolearn more about the equations used in the Spectre circuit simulator consult the Spectre Circuit Simulator Device Model Equations manual January 2004 13 Product Version 5 0 Spectre Circuit Simulator User Guide Preface B The Spectre circuit simulator also includes a waveform display tool Analog Waveform Display AWD to use to display simulation results For more information about AWD see the Analog Waveform User Guide B For more information about using the Spectre circuit simulator with SpectreHDL see the SpectreHDL Reference manual W For more information about using the Spectre circuit simulator with Verilog A see the Verilog A Language Reference manual B f you want to see how SpectreHF is run under the analog circuit design environment read SpectreRF Help m For more information about RF theory see SpectreRF Theory m For more information about how you work with the design framework II interface see Cadence Design Framework II Help B For more information about specific applications of Spectre analyses see The Designer s Guide to SPICE amp Spectre Typographic an
228. g lvlpub Saves all signals that are normally useful up to nest 1v1 deep in the subcircuit hierarchy This option is equivalent to allpub for subcircuits Normally useful signals include shared node voltages and currents through voltage sources and iprobes lvl Saves all signals up to nest 1v1 deep in the subcircuit hierarchy This option is relevant for subcircuits allpub Saves only signals that are normally useful Normally useful signals include shared node voltages and currents through voltage sources and iprobes all Saves all signals Use 1v1 or all instead of 1v1pub or allpub to include internal node voltages and currents through other components that compute current Use 1v1pub orallpub to exclude signals at internal nodes on devices the internal collector base emitter on a BJT the internal drain and source on a FET etc Ivlpub and allpub also exclude the currents through inductors controlled sources transmission lines transformers etc Note Setting the save parameter value to selected without any save statements in the netlist is not equivalent to specifying no output Currently the Spectre simulator saves all circuit nodes and branch currents with this combination of settings This might change in future releases of the Spectre simulator Saving Subcircuit Signals To save groups of signals for subcircuits you must adjust two parameter settings m Setthe save parameter to either 1v1 or 1v1pub
229. gets an appropriately scaled model assigned to it January 2004 102 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features For example the instance parameters of an inline subcircuit can represent emitter width and length of a BUT device Within that subcircuit a model statement can be created that is parameterized for emitter width and length and scales accordingly When you instantiate the subcircuit you supply the values for the emitter width and length and the device is instantiated with an appropriate geometrically scaled model Again the inline device does not get a hierarchical name and can be probed in the same manner as if it were a simple device and not actually embedded in a subcircuit In the following example a parameterized model is declared within an inline subcircuit for a bipolar transistor The model parameters are the emitter width emitter length emitter area and the temperature delta t rise of the device above nominal Ninety nine instances of a 4x4 transistor are then placed and one instance of a transistor with area 50 is placed Each transistor gets an appropriately scaled model declare a subcircuit which instantiates a transistor with a parameterized model The parameters ar mitter width and length inline subckt bjtmod c b e s parameters le lu we 2u area le we trise 0 model modl bjt type npn bf 100 letwe 2 area le 12 is 1e 12
230. h a single options statement options Statement Example Examp options rawfmt psfbin audit brief temp 30 save lvlpub nestlvl 3 rawfile C r raw useprobes no The example sets the rawfmt audit temp save nestlvl rawfile and useprobes parameters for an opt ions statement named Examp The backslash at the end of the first line is a line continuation character Nonnumerical parameter values are chosen from the possible values listed in the Spectre online help spectre h Setting Tolerances You need to set tolerances if the Spectre simulator s default settings do not suit your needs This section tells you how to make the needed adjustments If you need to examine default tolerances for any Spectre parameters you can find them in the Spectre online help spectre h Setting Tolerances with the options Statement The following opt ions statement parameters control error tolerances reltol One of the Spectre simulator s convergence criteria is that the difference between solutions in the last two iterations for a given time must be sufficiently small With reltol you set the maximum relative tolerance for values computed in the last two iterations The default for reltol is 0 001 January 2004 209 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements iabstol andvabstol These parameters set absolute as opposed to relative tolerances for differences in the computed values of voltages and currents in
231. h one call to the subcircuit The Spectre simulator performs the analyses in the order you specify them in the subcircuit definition Generally you do not mix components and analyses in the same subcircuit definition For more information about formats for subcircuit definitions and subcircuit calls see Chapter 6 Analyses Example The following example illustrates how to create and call subcircuits that contain analyses Creating Analysis Subcircuits subckt sweepVcc parameters start 0 stop 10 Ib 0 omega 1G steps 100 setIbb alter dev Ibb param dc value Ib SwpVccDC dc start start stop stop dev Vcc lin steps 2SwpVccAC ac dev Vcc start start stop stop lin steps freq omega 6 283185 ends sweepVcc This example defines a subcircuit called sweepVcc that contains the following B A list of parameters with default values for start stop Ib omega and steps This list of defaults is optional These defaults are for the subcircuit call For example if you call sweepvcc and do not specify values for the start and stop parameters in the subcircuit call the sweeps for analyses SwpVccDC and SwpVccAc start at 0 and end at 10 the values specified as defaults If however you specify start 1 and stop 5 as parameter values in the subcircuit call the start and stop parameters in SwpVccDC and SwpVccAC take the values 1 and 5 respectively B A control statement set Ibb which alters the dc parameter of the component named
232. han 5 0 Example 4 M1 powercheck assert expr max ml ids ml vds max max vin dc I r1 message power of M1 exceeds expected load power Checks that max m1 ids ml vds is less than max vin dc I r1 otherwise prints the warning power of M1 exceeds expected load power The check Statement You can perform a check analysis at any point in a simulation to be sure that the values of component parameters are reasonable You can perform checks on input output or operating point parameters The Spectre simulator checks parameter values against parameter soft limits To use the check analysis you must also enter the param command line argument with the spect re command to specify a file that contains the soft limits The following example illustrates the syntax of the check statement It tells the Spectre simulator to check the parameter values for instance statements ParamChk check what inst B ParamChk is your unique name for this check statement m The keyword check is the component keyword for the statement B The what parameter tells the Spectre simulator which parameters to check January 2004 194 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements The what parameter of the check statement gives you the following options Option Action none Disables parameter checking models Checks input parameters for all models only inst Checks input parameters for all instances only
233. hange the DC solution must be recomputed Without the use of state files this computation might slow the simulation because the only available estimate of the DC solution would be that computed at T 50C the final point in the DC sweep However by using a state file to preserve the initial DC solution at T 0C you can enable the Spectre simulator to compute the new DC solution quickly The computation is fast because the Spectre simulator can use the DC solution computed at T 0C to estimate the new solution You can also make future simulations of this circuit start quickly by using the state file to estimate the DC solution Even if you have altered a circuit it is usually faster to start the DC analysis from a previous solution than to start from the beginning The info Statement You can generate lists of component parameter values with the info statement With this statement you can access the values of input output and operating point parameters and print the node capacitance table These parameter types are defined as follows B input parameters Input parameters are those you specify in the netlist such as the given length of a MOSFET or the saturation current of a bipolar resistor W Output parameters Output parameters are those the simulator computes such as temperature dependent parameters and the effective length of a MOSFET after scaling B Operating point parameters Operating point parameters are those that depend on the
234. have numeric values specified in their declaration can be subjected to statistical variation Parameters that are specified as correlated must have had an appropriate variation specified for them in the statistics block For example if you have the parameters XISN XIS XIB you cannot specify distribution for XISN or a correlation of this parameter with another The percent flag indicates whether the standard deviation sta or uniform range N are specified in absolute terms percent no or as a percentage of the mean value percent yes For parameter uuu in the example in Specifying Parameter Distributions Using Statistics Blocks the mean value is 200 and the variation is 200 10 200 that is 200 20 For parameter rshsp the process variation is given by Normal 200 12 200 that is Normal 200 24 Cadence recommends that you do not use the percent yes with the log normal distribution Truncation Factor The default truncation factor for Gaussian distributions and for the Gaussian distribution underlying the log normal distribution is 4 0 sigma Randomly generated values that are outside the range of mean 4 0 sigma are automatically rejected and regenerated until they fall inside the range You can change the truncation factor using the truncate statement The following is the syntax truncate tr value Note The value of the truncation factor can be a constant or an expression Note Parameter correlatio
235. he altergroup statement is restrictive in what can be specified The optional names are allowed at the end of the section and library These names must match the names of the section or library The following is the syntax for library definition library libraryName section sectionName statements endsection sectionName section anotherName statements endsection anotherName library libraryName One common use of library references is within altergroup statements For example January 2004 75 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists al altergroup change models to FAST process corner include MOSLIB section FAST Multidisciplinary Modeling Multidisciplinary modeling involves setting tolerances and using predefined quantities Setting Tolerances with the quantity Statement Quantities are used to hold convergence related information about particular types of signals such as their units absolute tolerances and maximum allowed change per Newton iteration With the quantity statement you can create quantities and change the values of their parameters You set these tolerances with the abstol and maxdelta parameters respectively You can set the huge parameter which is an estimate of the probable maximum value of any signal for that quantity You can also set the blowup parameter to define an upward bound for signals of that quantity If a signal exceeds the blowup parameter value t
236. he analysis in a later simulation by using the state file as the starting point for another transient analysis m You can use state files to create automatic updates of initial conditions and nodesets The following example demonstrates the usefulness of state files altTemp alter param temp value 0 Drift dc param temp start 0 stop 50 0 step 1 readns ua741 dc0 write ua741 dc XferVsTemp xf param temp start 0 stop 50 step 1 probe Rload freq 1kHz readns ua741 dc0 The first analysis computes the DC solution at T20C saves it to a file called ua741 dc0 and then sweeps the temperature to T 50C The transfer function analysis x resets the temperature to zero Because of the temperature change the DC solution must be recomputed Without the use of state files this computation might slow the simulation because the only available estimate of the DC solution would be that computed at T 50C the January 2004 263 Product Version 5 0 Spectre Circuit Simulator User Guide Time Saving Techniques final point in the DC sweep However by using a state file to preserve the initial DC solution at T 0C you can enable the Spectre simulator to compute the new DC solution quickly The computation is fast because the Spectre simulator can use the DC solution computed at T 0C to estimate the new solution You can also make future simulations of this circuit start quickly by using the state file to estimate the DC solution Even if you have altered a
237. he analysis stops with an error message Generally a reasonable value for the absolute tolerance of a quantity is 10 times smaller than its greatest anticipated value A reasonable definition for the huge value of a quantity is 10 to 10 times its greatest expected value A reasonable definition of the blowup value for a quantity is 108 to 10 times its greatest expected value Predefined Quantities The Spectre Netlist Language has seven predefined quantities that are relevant for circuit simulation and you can set tolerance values for any of them These seven predefined quantities are B Electrical current in Amperes named I Default absolute tolerance 1 pA m Magnetomotive force in Amperes named MMF Default absolute tolerance 1 pA turn W Electrical potential in Volts named v Default absolute tolerance 1 uV Default maximum allowable change per iteration 300mV January 2004 76 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists m Magnetic flux in Webers named wb Default absolute tolerance 1 nWb B Temperature in Celsius named Temp Default absolute tolerance 100 uC m Power in Watts named Pwr Default absolute tolerance 1 nW m Unitless named U Default absolute tolerance 1 x 10 For more information see spectre h quantity quantity Statement Example The electrical potential quantity has a normal default setting of 1 uV for absolute tolerance a
238. he first lifetime is based on the threshold voltage and the second lifetime is based on the low mobility shift For each transient analysis in which circuitage is greater than 0 the Spectre simulator generates a second sorted table This table lists all the degradations of the threshold voltage V 4 the mobility factor U the transconductance g and the drain current I 4 of each device for the period specified in the circuitage parameter The degradation of Vj is given in absolute values The degradations of U 9m and lgs are expressed as a percentage of their original values All four degradations are compared to failure criteria that you can specify with the model statement parameters crivth criuo crigm and criids If any degradation is greater than its corresponding failure criterion the device is listed as having failed In the transient analysis you can also save waveforms of the following quantities for any device B Voltage M Any operating point parameter BH Stress January 2004 180 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses B Effective device age m Substrate current You create these output files with the save statement You use a waveform display tool such as the Cadence Analog Waveform Display AWD tool to view the waveforms Example of Hot Electron Degradation This netlist of an 11 stage ring oscillator demonstrates the statements required to simulate hot electron deg
239. he instantaneous power dissipated in the circuit subcircuit or device Formatting the pwr Parameter The syntax for the pwr parameter is illustrated by the following examples January 2004 215 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements To save the power dissipated on a device or instance of a subcircuit the syntax is save instance_name pwr To save the total power the syntax is save pwr You can explicitly save particular power variables For example save pwr xl pwr xl x2 ml pwr This statement saves three power signals B total power dissipated pwr B power dissipated in the x1 subcircuit instance x1 pwr B power dissipated in the x1 x2 m1 MOSFET Power Options The pwr parameter in the options statement can also be used to save power The following table shows the five possible settings for the pwr option Setting Action all The total power the power dissipated in each subcircuit and the power dissipated in each device is saved subckts The total power and the power dissipated in each subcircuit is saved devices The total power and the power dissipated in each device is saved total The total power dissipated in the circuit is calculated and saved none No power variable is calculated or saved This is the default setting For example opts options pwr total save xl pwr This creates two power signals pwr generated by the options statement and
240. he ports parameter defines the ports of the circuit ports are numbered in the order given The following example statement demonstrates the proper format to specify optional output nodes p n FindNoise out gnd noise start 1 stop 1MHz Example of Forward Referencing in Hierarchical Nodes simulator lang spectre cl xa mid 0 capacitor c 0 2p xa 1 2 buffer Example of Path Referencing in Hierarchical Nodes xfl I3 0p3 I3 0n3 xf start 1k stop 10G dec 20 annotate status January 2004 67 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Basic Analysis Rules When you prepare netlists for the Spectre simulator remember these basic analysis rules The Spectre simulator has no default analysis If you do not put any analysis statements into a netlist the Spectre simulator issues a warning and exits For most analyses if you specify an analysis that has a prerequisite analysis the Spectre simulator performs the prerequisite analysis automatically For example if you specify an AC analysis the Spectre simulator automatically performs the prerequisite DC analysis However if you want to run a pac pxf Of pnoise analysis you must specify the prerequisite pss analysis You specify analyses in the order you want the Spectre simulator to perform them You can perform more than one of the same type of analysis in a single Spectre run Consequently you can perform several analyses of the same type and v
241. hooting If channel length is more than or equal to 0 5 um or less than or equal to 100 um m If channel width is greater than or equal to 0 5 um m Ifthe area of source diffusion is greater than 0 or less or equal to 1e 8m m iif the area of drain diffusion is greater than 0 or less or equal to 1e 8 m B If the mos3 model parameter vto the threshold voltage at zero body bias has an absolute value less than or equal to 3 Entering a Parameter Range Limits File You can enter a parameter range limits file in two ways B Type the param filename option of the spectre command from the command line or place it in an environment variable i 1ename is the name of the parameter range limits file In the following example 1imits3 is the range limits file for this simulation of test circuit Spectre param limits3 test circuit m Read the parameter limits file from within another file by putting an include statement with a syntax like the following example in your netlist include filename filename is the name you give to the range limits file You can nest include statements The only limit on depth is that imposed by the operating system on the number of files that can be open simultaneously in the Spectre simulator Paths you specify in filenames refer to the directory that contains the current file not to the directory in which the Spectre simulator was started For example suppose your directory tree is se
242. ide Control Statements Setting multiple current probes can greatly increase the DC and transient analysis simulation times Consequently this method is typically used only for small circuits and AC analysis Important Adding probes to circuits that are sensitive to numerical noise might affect the solution In such cases an accurate solution might be obtained by reducing reltol Saving Subcircuit Terminal Currents You use the subcktprobelvl parameter to control the calculation of terminal currents for subcircuits Current probes are added to the terminals of each subcircuit up to subcktprobelvl deep You can then save these terminal currents by setting the save parameter The nest 1v1 parameter controls how many levels are returned The set Statement Except for temperature parameters and scaling factors you use the set statement to modify any options statement parameters you set at the beginning of the netlist The new settings apply to all analyses that follow the set statement in the netlist You can change the initial settings for the state of the simulator by placing a set statement in the netlist The set statement is similar to the opt ions statement that sets the state of the simulator but it is queued with the analysis statements in the order you place them in the netlist You use the set statement to change previous options or set statement specifications The modifications apply to all analyses that follow the set st
243. ide Parameter Specification and Modeling Features named models that can be accessed one level outside of the subcircuit Regular device instances one level outside of the subcircuit can then refer to the generated model Because these are now instances of a model rather than of a subcircuit you can specify device instance parameters with enumerated types such as region fwd This technique is shown in the following example declare an inline subcircuit that exports a parameterized model inline subckt bjtmod parameters le lu we 2u area le w model bjtmod bjt type npn bf 100 letwe 2 area le 12 is 1e 12 le we area 1e 12 ends bjtmod now create two instances of the inline subcircuit that is create two actual models called modl mod2 modl bjtmod le 4u we 4u mod2 bjtmod le 1u area 50e 12 99 instances of mod1 all share modl1 and 1 instance of mod2 ql 23 1 0 modl region fwd q2 23 2 0 modl trise 2 q99 2 3 99 0 modl q100 2 3 100 0 mod2 Because the syntax of creating an instance of a model is the same as the syntax of creating an instance of a subcircuit in the Spectre netlist you can easily replace model instances with more detailed subcircuit instances To do this replace the model statement itself with a subcircuit definition of the same name When you do this in the Spectre Netlist Language you do not have to change the instance statements In SPICE inline
244. ier Definitions of Colon Modifiers The Spectre simulator recognizes the following colon modifiers Modifier Description a Signifies the root base name of the given path for the file e Signifies the extension for the given path of the file sh Signifies the head of the given path for any portion of the file before the last Vis Signifies the tail of the given path for any portion of the file after the last Signifies the character itself use two consecutive colons to place a single colon in an output filename that is not read as a percent code modifier Any character except a modifier after a colon signals the end of modifications The Spectre simulator appends both the character and the colon to the filename The Spectre simulator applies a chain of colon modifiers in the sequence you specify them For example if you apply C e C r t to the input filename circuits opamp ckt C e is the extension ckt of the input filename C risthe root opamp ckt of the input filename t is the tail of the input filename after the last opamp The result is the output filename ckt opamp Note If the input filename does not contain a slash and a period the modifiers t and r return the whole filename and the modifier n returns a period January 2004 273 Product Version 5 0 Spectre Circuit Simulator User Guide Managing Files Examples of Colon Modifier Use The following table shows the various
245. ifficulties and because it rapidly factors and solves large sparse matrices Improved Reliability The Spectre circuit simulator offers you the following improvements in reliability Improved convergence Spectre proprietary algorithms ensure convergence of the Newton Raphson algorithm in the DC analysis The Spectre circuit simulator virtually eliminates the convergence problems that earlier simulators had with transient simulation Helpful error and warning messages The Spectre circuit simulator detects and notifies you of many conditions that are likely to be errors For example the Spectre circuit simulator warns of models used in forbidden operating regions of incorrectly wired circuits and of erroneous component parameter values By identifying such common errors the Spectre circuit simulator saves you the time required to find these errors with other simulators The Spectre circuit simulator lets you define soft parameter limits and sends you warnings if parameters exceed these limits Thorough testing Automated tests which include over 1 000 test circuits are constantly run on all hardware platforms to ensure that the Spectre circuit simulator is consistently reliable and accurate Benchmark suite There is an independent collection of SPICE netlists that are difficult to simulate You can obtain these circuits from the Microelectronics Center of North Carolina MCNC if you have File Transfer Protocol FTP access on th
246. ill insert the flag insensitive yes atthe beginning of each converted netlist on the simulator command statement that is simulator lang spectre insensitive yes The insensitive yes language directive marks the models subcircuits that were converted so that Spectre can perform a lower case compare m The SPICE Reader treats the character as a math function if found inside of an expression and as a comment if found outside of an expression m Lines beginning with CPP keywords are not treated as comments by the SPICE Reader but will result in an syntax error unless you run CPP on the netlist m You can force the SPICE Reader to treat all bjt devices as having four terminals with the q4term command line option to spp By default the fourth field after the device name of an instance statement is treated as a terminal unless one of the following occurs a There is a model name within the netlist that is named the same as the fourth field Q Itis the last item on the instance line For example ql 12 3 4 mybjt The 4 is treated as a device terminal ql 1 2 3 nch mybjt The nch is treated as a device terminal unless January 2004 52 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility Q mybjt is defined as a parameter in the netlist nchis defined as a model in the netlist In the second case the g4term option can be used to override the default behavior of the converter You can gai
247. imits operating region warnings 291 parameter values 284 specifying conditions for in subcircuit calls 98 tolerances might be set too tight 280 warnings melting current 279 waveform display 35 VOIR storage format WSF 234 what parameter of check statement 195 290 write parameter and creating state files 200 262 writefinal parameter and creating state files 200 262 WSF waveform storage format 234 wsfascii output format 234 wsfbin output format 234 X xf analysis brief description of 131 January 2004 333 Product Version 5 0 Spectre Circuit Simulator User Guide January 2004 334 Product Version 5 0
248. imulator displays the following message Error found in spectre during initial setup vlO time is not strictly increasing in waveform Check the PWL component to fix this error Spectre Warning Messages Warning messages tell you about conditions that might cause invalid results Unlike error messages warnings do not stop a simulation When you receive a warning message you must decide whether the particular condition creates a problem for your simulation This section describes some common Spectre warning messages It also tells you how to modify parameters to correct conditions that might produce invalid simulation results The Spectre simulator often prints warnings and notices that are eventually determined to be uninteresting and there is a natural tendency after a while to ignore them We recommend that you carefully study them the first few times you simulate a particular circuit and whenever the simulator gives you unexpected results P N Junction Warning Messages Almost every semiconductor device includes at least one p n junction Normally these p n junctions are biased in a particular operating region Three types of warning messages are available for each p n junction one for exceeding a maximum current one for exceeding a melting current and one for exceeding a breakdown voltage Explosion Region Warnings Warning from spectre at dc 191 mA during DC analysis srcSweep mos mod The bulk drain junction curr
249. in a directory named test raw In the output directory results from each analysis you specify are stored in separate files The root of each filename is the name you gave the analysis in the netlist and the suffix for each filename is the type of analysis you specified For example if you run the following analysis the Spectre simulator stores the results in a file named Sparams sp Sparams sp start 100M stop 100G dec 100 For the sweep and montecarlo analyses the names of the filenames are a concatenation of the parent analysis name the iteration number and the child analysis name For example sweepl sweep param temp values 25 50 dcOp dc creates sweepl1 000 dcOp dc and sweep1_001_dcOp dc The following example contains a number of analysis statements from a netlist It shows the name of the output file the Spectre simulator creates for each analysis In some cases the Spectre simulator creates more than one output file for an analysis This is because the January 2004 236 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options analysis statement contains a parameter that specifies that certain output information be sent to a file ANALYSES i OpPoint op DC operating point P 2 SPESE OpPoint dc print yes oppoint file readns ua741 dc write ua741 dc Drift dc p Drift dc start 0 stop 50 0 step 1 param temp nestlv1l 0 XferVsTemp xf p Xfe
250. in the filename Example of include Statement Use In the following include statement example the Spectre simulator reads initial program options and then inserts two files cmos mod and opamp ckt After reading these files it returns to the original file and reads further data about power supplies example of using include statement global gnd vdd vss simulator lang spectre parameters VDD 5 include cmos mod include opamp ckt power supplies Vdd vdd gnd vsource dc VDD Vss vss gnd vsource dc VDD Reading Piecewise Linear PWL Vector Values from a File You could type the following component description into a netlist v4 in 0 vsource type pwl wave 0 0 1n 0 2n 5 10n 5 11n O 12n 0 You could also enter the vector values from a file in which case the component description might look like this v4 in 0 vsource type pwl file test in You can use the 1 command line option followed by a path to have the Spectre simulator look for the inserted files in a specified directory if they cannot be found in the current directory If you place PWL vector values in an input file that is read by the component do not specify scale factors in your parameter values If you use an input file the values in the file must look like this without scale factors 0 le 9 2e 9 10e 9 11e 9 12e 9 OOOO January 2004 74 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Using Library Sta
251. info what input extremes yes MyAcct5 info what terminals extremes yes yAcct6 info what oppoint extremes yes Next section is the subckt for na2 9 subckt na2 nga ml nq a vdd vdd p 1 0 35u w 2 70u ad 1 03p pd 3 46u as 1 98p ps 6 86u m2 nq vdd vdd vdd p 1 0 35u w 2 70u ad 1 03p pd 3 46u as 1 98p ps 6 86u m3 vss a 6 vss n 1 0 35u w 1 70u ad 1 25p pd 4 86u as 0 18p ps 1 91u m4 nq vdd 6 vss n 1 0 35u w 1 70u ad 1 25p pd 4 86u as 0 18p ps 1 91u cO a vdd capacitor c 1 0512057e 15 cl ang capacitor c 7 308e 17 GZ vdd vss capacitor c 6 12359e 16 e3 nq vss capacitor c 5 175377e 16 c4 nq vdd capacitor c 1 1668172e 15 c5 a vss capacitor c 29 530671e 16 ends Begin top level circuit definition xna21 1 90 na2 xna22 2 1 na2 xna23 3 2 na2 xna24 14 3 na2 xna25 5 4 na2 January 2004 304 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits xna26 6 5 na2 xna27 7 6 na2 xna28 8 7 na2 xna29 9 8 na2 xna210 10 9 na2 xna211 11 10 na2 xna212 12 11 na2 xna213 13 12 na2 xna214 14 13 na2 xna215 115 14 na2 xna216 116 15 na2 xna217 90 16 na2 Next couple of lines sets variables for vdd and vss parameters vdd S1 23 3 parameters vss S1 20 0 vdd Il vdd gnd vsource dc vdd S1 vss Il vss gnd vsource dc vss S1 Next line initializes nodes within ring ic 220 420 6 20 8 20 1020 include q35
252. ing Analysis env1p Computes the envelope response of a circuit The simulator automatically determines the clock period by looking through all the sources with the specified name Envelope following analysis is most efficient for circuits where the modulation bandwidth is orders of magnitude lower than the clock frequency This is typically the case for example in circuits where the clock is the only fast varying signal and other input signals have a spectrum whose frequency range is orders of magnitude lower than the clock frequency For another example the down conversion of two closely placed frequencies can also generate a slow varying modulation envelope The analysis generates two types of output files a voltage versus time td file and an amplitude phase versus time fd file for each of specified harmonic of the clock fundamental For more information about the envelope following analysis see SpectreRF Help Q Periodic AC analysis pac After the periodic steady state analysis computes a periodic solution this analysis computes the response of a circuit in periodic steady state to a small sinusoidal stimulus The frequency of the sinusoidal stimulus is not constrained by the period of the large periodic solution The periodic AC analysis lets you sweep the frequency over a range of values This analysis is similar to the AC analysis except that it linearizes the circuit about a periodically varying operating point and accurately mod
253. ing arguments You can specify more than one argument with a single save statement and you can mix the types of arguments in a single statement Save Save Save Save signalName compName compName modifier subcircuitName terminallndex signalName is generally the netlist name of a node whose voltage you want to save compName is the netlist name of a component whose signals you want to save modifier specifies signals you want to save for a particular component It can have the following types of values Q A terminal name Terminal names for components are the names for nodes in component instance definitions You can find instance definitions for each component in the component parameter listings in the Spectre online help spectre h For example the following is the instance definition of a microstrip line The terminal names are t 1 b1 t2 and b2 Name t1 bl t2 b2 msline parameter value A terminal index The terminal index is a number that indicates where a terminal is in the instance definition You give the first terminal a terminal index of 1 the second a terminal index of 2 and so on In this example the terminal indexes are 7 for sink and 2for Src Name sink src isource parameter value A name of an operating point parameter from the lists of parameters for each component in the Spectre online help The name of a SpectreHDL Verilog A internal variable One of the following keyw
254. ing for BJTs 292 selecting limits for warnings about 291 specifying forbidden regions for January 2004 transistors 291 operating point parameters listing 202 233 saving with save statement 212 224 operational amplifier example of characterization in one simulation run 135 oppoint as DC analysis parameter 161 as info statement parameter 203 233 options statement ckptclock option example 243 correcting convergence problems 296 defining output file formats 235 example 209 formatting 209 generating output directory names 238 overriding environment defaults 246 parameters compatible 210 iabstol 210 rawfile 238 rawfmt 235 reltol 209 tempeffects 210 topcheck 276 296 vabstol 210 resetting options 267 setting tolerances with 209 OR bars in syntax 14 order of analyses netlist example of effective use 135 output as info statement parameter 203 233 data controlling the amount of outputstart parameter 145 skipping 145 strobing 145 directory names how Spectre generates 236 specifying your own 238 file format options 234 235 filenames how Spectre generates 236 parameters listing 202 232 viewing 34 output resistance netlist example of measurement discussed 136 outputstart parameter 146 overriding defaults 246 Product Version 5 0 Spectre Circuit Simulator User Guide P P predefined percent code 270 p terminals formatting in analysis statements 67 pac
255. ing models if you are not already doing so Then tighten reltol to increase accuracy With the Spectre simulator only customer installed models might not be charge conserving B Be sure that gmin is not influencing the solution If possible set gmin to 0 in an options Or set statement m f a solution exhibits point to point ringing set the integration method in the transient analysis to Gear s second order backward difference formula method gear2only B Ifa low loss resonator exhibits too much loss set the integration method in the transient analysis to the trapezoidal rule method t raponly W Ifthe initial conditions used by the Spectre simulator are not the same as the ones you specified decrease the rforce parameter in the options or set statements until the initial conditions are correct m I the Spectre simulator does not accurately follow the turn on transient of an oscillator set the maxstep parameter of the transient analysis to one tenth the size of the expected period of oscillation or less January 2004 299 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits This appendix contains example netlists for testing the BSIM3v3 standard model Notes on the BSIM3v3 Model on page 301 Spectre Syntax on page 301 SPICE BSIM 3v3 Model on page 301 Spectre BSIM 3v3 Model on page 302 Ring Oscillator Spectre Deck for Inverter Ring with No Fanouts inverter_ring sp on page 302 Ring O
256. input Checks input parameters for all models and all instances output Checks output parameters for all models and all instances all Checks input and output parameters for all models and all instances oppoint Checks operating point parameters for all models and all instances The checklimit Statement You can enable or disable an assert or a group of asserts with the checklimit statement You can define one or more checklimit statements in the netlist each enabling or disabling individual asserts The statement is applied to subsequent transient DC and DC sweep analyses until the next checklimit statement appears By default all asserts are enabled The first checklimit statement that specifically enables asserts also disables the remaining asserts The checklimit statements are cumulative in effect except when the checkallasserts parameter is specified When the checkallasserts parameter is specified all asserts in the netlist are enabled When multiple checklimit statements refer to the same assert the last checklimit statement overrides the previous statements The syntax for a checklimit statement is Name checklimit enable checki1 check2 checkn disable checki1 check2 checkn start value stop value severity non notice warning error checkallasserts yes no January 2004 195 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements where Na
257. instance model ic or nodeset statements or further subcircuit definitions ends SubcircuitName subckt The keyword subckt subckt is used in SPICE mode SubcircuitName The unique name you give to the subcircuit nodel nodeN The external or connecting nodes of the subcircuit to the main circuit parameters namel valuel nameN This is an optional parameter specification field You can specify default values for subcircuit calls that refer to this subcircuit The field contains the keyword parameters followed by the names and values of the parameters you want to specify component instance statement The instance statements of your subcircuit other subcircuit definitions component statements analysis statements or model statements ends SubcircuitName The keyword ends or ends in SPICE mode optionally followed by the subcircuit name A Subcircuit Definition Example The following subcircuit named twi sted models a twisted pair It has four terminals p 1 n1 p2 and n2 The parameter specification field for the subcircuit sets subcircuit call default values for parameters zodd zeven veven vodd and 1en Remember that the specified parameters are defaults for subcircuit calls not for the instance statements in the subcircuit For example if the subcircuit call leaves the zodd parameter unspecified the value of zodd January 2004 94 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification
258. instance statements and or model statements and or parameter statements The following is an example of the altergroup statement vl 1 0 vsource dc 1 R1 1 0 Resistor R 1k dcl dc this analysis uses a 1k resistance value al altergroup R1 1 0 Resistor R 5k dc2 dc this analysis uses a 5k value Model Statements model statements are designed to allow certain parameters which are expected to be shared over many instances to be given once However for any given component it is predetermined which parameters can be given on model statements for that component This section gives a brief overview of the Spectre model statement For a more detailed discussion on modeling issues including parameterized models expressions subcircuits and model binning see Chapter 5 Parameter Specification and Modeling Features January 2004 70 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Formatting the model Statement You format the model statement as follows model name master paraml valuel param2 value2 The fields have the following values model The keyword model model is used for SPICE mode name The name you give to the model master The master name of the component such as resistor bjt Or tline This field can also contain the name of an AHDL module For more information about using the Spectre simulator with SpectreHDL see the SpectreHDL Ref
259. is section you will learn to place analyses into your netlist and to assign parameter values for them For more information on analyses see Chapter 6 Analyses and the Spectre online help spectre h Basic Formatting of Analysis Statements You format analysis statements in the same way you format component instance statements except that you usually do not put a list of nodes in analysis statements You specify most analysis statements as follows Name nodel nodeN Analysis Type parameter value where Name The name you give to the analysis 1nodei nodeN Names you give to the nodes that connect to the analysis You have the option of putting the node names in parentheses to improve the clarity of the netlist See the examples later in this chapter For most analyses you do not need to specify any nodes You can use the hierarchical operator to represent nodes inside a subcircuit hierarchy in your netlist The Spectre circuit simulator supports forward referencing retaining information about a node that is not defined yet and mapping it when the node is defined and relative path referencing accessing a node with reference to the current scope Look for examples in the section below The simulator does not support hierarchical terminals in netlists Analysis Type Spectre name of the type of analysis you want such as ac tran or xf You can find this name by referring to the topics list in the Spectre online he
260. it did Model Parameter Values Clamped Warning from spectre during initial setup The value of vj pb at T 25 C is 50e 03 V which is too small Clamped to 0 1 V n The value of vj pb at T 27 C is 41 7617e 03 V which is too small Clamped to 0 1 V The Spectre simulator clamps model parameter values to prevent numerical difficulties during simulation When clamping is completed Spectre displays a message indicating that it is using clamped values There is no way to disable these clamps Invalid Parameter Warnings Warning from spectre during circuit read in pchmod tox is not a valid parameter for bsim4 models pchmod nch is not a valid parameter for bsim4 models January 2004 282 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting This type of warning is issued any time you specify an invalid parameter in a model definition The models included with Spectre have predefined model parameters For more information See spectre h Only these predefined parameters can be used within a model definition The Spectre circuit simulator issues similar warnings for invalid instance and subcircuit parameters Redefine Primitives Messages Warning from spectre in g2 during circuit read in redefPrim scs 6 q2 resistor redefines the primitive named resistor Spectre displays this message if you define a model or subcircuit with
261. ks like one of the following NPNbjt rb has the unusually small value of 1mOhms PNPbjt tf has the unusually large value of 1Gs OA1 Q16 of ua741 region has the unusual value of rev If you receive such a message check the parameter If the unusual parameter value is correct you can ignore this message The limits settings that generate these warning messages are soft limits as opposed to hard limits settings Hard limits stop a simulation if they are violated the Spectre simulator has automatic soft limits on a few parameter values However you can override these limits or specify your own limits for parameters that do not have automatic limits For more information see Customizing Error and Warning Messages on page 284 gmin Is Large Enough to Noticeably Affect the DC Solution Warning detected by spectre during DC analysis oppoint January 2004 280 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Gmin 1pS is large enough to noticeably affect the DC solution By default the Spectre simulator and SPICE adds a very small conductance of 107 siemens called gmin across nonlinear devices This conductance prevents nodes from floating if the nonlinear devices are turned off By default GMIN 1e 12 Siemens The gmin parameter usually has a minimal effect on circuit behavior However some circuits such as charge storage circuits are very sensitive to the small
262. l dot cards as well as the Spectre native input language m Reads in the first line as the title card January 2004 51 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility m Generally ignores the case of alphabetic characters in the input The program internally converts them to lowercase Quoted strings are exceptions to this rule M Interprets scale factors following numerical values according to SPICE conventions B Accepts the SPICE comment and continuation conventions B Accepts the and characters as valid parts of a node or an instance or parameter name You can also use the Escape backslash convention to include otherwise illegal characters in the names m Spectre statements are not allowed in the SPICE mode and SPICE statements are not allowed in the Spectre mode BH In simulator lang spectre mode you can refer to model names and subcircuit names defined with the simulator lang spice mode model and subckt statements even though they are in another portion of the netlist Spectre always tries to match the case of a model subcircuit s name when there is a call to a model subcircuit from an instance line an alter statement or other part of the netlist During the netlist conversion process the SPICE Reader converts included models subcircuits to lower case which can prevent Spectre from identifying the right model subcircuit for a given device For this reason the SPICE Reader w
263. l if 1 lt 3um if w lt 3um nmos dg s b typ 1x1 1 1 w w ls ls ld ld else nmos dg s b typ 1x3 1 1 w w ls ls ld 1d else if w lt 3um nmos dg s b typ 3x1 1 1 w w ls ls ld ld else nmos dg s b typ 3x3 1 1 w w ls ls ld 1d endsection typical section slow if l1 lt 3um 1 if w lt 3um nmos dg s b slow 1xl l 1 w w ls l1s ld ld else nmos dg s b slow 1x3 l 1 w w ls ls ld 1d else if w lt 3um nmos dg s b slow 3x1 1 1 w w ls ls ld ld else nmos dg s b slow 3x3 l 1 w w ls ls ld ld endsection slow endlibrary Scaling Physical Dimensions of Components Selected components allow their physical dimensions to be scaled with global scale factors When you want to scale the physical dimensions of these instances and models you use the scale and scalem parameters in the options statement Use scale for instances and scalem for models The default value for both scale and scalem is 1 0 For more information about the opt ions statement see options Statement Format on page 209 and the documentation for the opt ions statement in Spectre online help spectre h options You can scale the following devices with scale and scalem m Capacitors length 1 or width w January 2004 118 Pro
264. ld be M1 M2 s1 and M3 s1 However the parasitic capacitors have full hierarchical names January 2004 100 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features You can create an instance of the inline subcircuit cell in the same way as creating an instance of the specially tagged inline device You can use save statements to probe this instance in the same way as a regular device without having to W Realize that the instance is actually embedded in a subcircuit m Know that there are possible additional parasitic devices present m Figure out the hierarchical name of the device of interest A modeling engineer can create several of these inline subcircuits and place them in a library for the design engineer to use The library then includes a symbol cell view for each inline subcircuit The design engineer then places a symbol cell view on a design which behaves just as if a primitive were being used The design engineer can then probe the device for terminal currents and operating point information Probing the Device The Spectre simulator allows the following list of items to be saved or probed for primitive devices including devices modeled as the inline components of inline subcircuits B All terminal currents save ml currents B Specific index terminal current save ml 1 1 drain B Specific named terminal current save ml s s source M Save all operating poin
265. le we area 1e 12 bjtmod c b e s modl trise trise inline component ends bjtmod some instances of this subck ql 23 1 0 bjtmod le 4u we 4u trise defaults to zero q2 23 2 0 bjtmod le 4u we 4u trise 2 q3 23 3 0 bjtmod le 4u we 4u q99 2 3 99 0 bjtmod le 4u we 4u q100 23 100 0 bjtmod le 1u area 50e 12 Since each device instance now gets its own unique model this approach lends itself to statistical modeling of on chip mismatch distributions in which each device is taken to be slightly different than all the others on the same chip The value of bf is the same for the first 99 transistors For more details see Monte Carlo Analysis on page 164 Inline Subcircuits Containing Only Inline model Statements You can create an inline subcircuit that contains only a single model statement and nothing else where the model name is identical to the subcircuit name This syntax is used to generate a parameterized model statement for a given set of parameters where the model is then exported and can be referenced from one level outside the subcircuit Instantiating the inline subcircuit in this case merely creates a model statement with the same name as the subcircuit call The Spectre simulator knows that because the subcircuit definition contains only a model statement and no other instances the definition is to be used to generate January 2004 103 Product Version 5 0 Spectre Circuit Simulator User Gu
266. level constructs make it easier for designers to use a high level description language for the first time RF Capabilities SpectreRF adds several new analyses that support the efficient calculation of the operating point transfer function noise and distortion of common analog and RF communication circuits such as mixers oscillators sample and holds and switched capacitor filters SpectreRF adds four types of analyses to the Spectre simulator The first is periodic steady state PSS analysis a large signal analysis that directly computes the periodic steady state response of a circuit With PSS simulation times are independent of the time constants of the circuit so PSS can quickly compute the steady state response of circuits with long time constants such as high Q filters and oscillators You can also embed a PSS analysis in a sweep loop referred to as an SPSS analysis in the Cadence analog design environment which allows you to easily determine harmonic levels January 2004 21 Product Version 5 0 Spectre Circuit Simulator User Guide Introducing the Spectre Circuit Simulator as a function of input level or frequency making it easy to measure compression points intercept points and voltage controlled oscillator VCO linearity The second new type of analysis is the periodic small signal analysis After completing a PSS analysis SpectreRF can predict the small signal transfer functions and noise of frequency translatio
267. lp spectre h parameter value List of parameter values you specify for the analysis You can specify values for any number of parameters You can find parameter listings for an analysis by referring to the Spectre online help spectre h January 2004 66 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Note The noise xf pnoise and pxf analyses let you specify nodes p and n which identify the output of the circuit When you use this option you should use the full analysis syntax as follows Name gt p n Analysis Type parameter value If you do not specify the p and n terminals you must specify the output with a probe component Examples of Analysis Statements The following examples illustrate analysis statement syntax XferVsTemp xf start 0 stop 50 step 1 probe Rload param temp freq 1kHz This statement specifies a transfer function analysis xf with the user supplied name XferVsTemp With all transfer functions computed to a probe component named R1oad it sweeps temperature from 0 to 50 degrees in 1 degree steps at frequency 1 kHz For long statements you must place a backslash at the end of the first line to let the statement continue on the second line Sparams sp stop 0 3MHz lin 100 ports Pin Pout This statement requests an S parameter analysis sp with the user supplied name Sparams A linear sweep starts at zero the default and continues to 3 MHz in 100 linear steps T
268. ltages on topological nodes including internal nodes and currents through voltage sources inductors switches transformers N ports and transmission lines The format for specifying signals with the nodeset statement is similar to that used by the save statement This method is described in detail in Saving Main Circuit Signals on page 224 Consult this discussion if you need further clarification about the following example nodeset Voff 0 X3 7 2 5 Ml int_d 3 5 L1 1 1u This example sets the following solution estimates m The voltage of node voff is set to 0 m Node 7 of subcircuit X3 is set to 2 5 V m The internal drain node of component M1 is set to 3 5 V See the table in the ic statements section of this chapter for more information about specifying internal nodes WB The current for inductor L1 is set to 1p Specifying State Information for Individual Analyses You can specify state information for individual analyses in two ways m You can use the ic parameter of the transient analysis to choose which previous specifications are used m You can create a state file that is read by an individual analysis January 2004 261 Product Version 5 0 Spectre Circuit Simulator User Guide Time Saving Techniques Choosing Which Initial Conditions Specifications Are Used for a Transient Analysis The ic parameter in the transient analysis lets you select among several options for which initial conditions to use You can
269. ltiple sets of defaults which you identify with different s substitutions Initially the Spectre simulator looks for defaults settings in lt S_ DEFAULTS If this variable does not exist it looks for default settings in SPECTRE_DEFAULTS To set these environment variables use the following procedure gt In an appropriate file such as cshrc or login use the appropriate UNIX command to create settings for the environment variables 8 DEFAULTS Or SPECTRE DEFAULTS Format the new default settings like spect xe command line arguments and place them in quotation marks The following example changes the default output format from ps fbin to wsfbin It also sets an option that is normally deactivated It sends all messages from the Spectre simulator to a C r 1og file For csh c setenv SPECTRE DEFAULTS format wsfbin log C r log For sh or ksh SPECTRE DEFAULTS format wsfbin tlog C r log EXPORT SPECTRE DEFAULTS This second example a typical use of the SPECTRE_DEFAULTS environment variable tells the Spectre simulator to do the following m Write a log file named ckt file out where ckt file is the name of the input file minus any dot extension m Use the parameter soft limits file in the Cadence software hierarchy setenv SPECTRE DEFAULTS log C r out param cds etc spectre range lmts
270. lutions with the nodeset statement 199 261 euler integration method parameter example in netlist conditional if statement 115 parameterized inline subcircuit paramtest statement 115 specifying N ports 120 exit codes Spectre 241 explosion region warnings 278 expressions 86 as model parameters 72 in subcircuit parameters 97 extending statements beyond a single line formatting for 59 143 14 144 115 F failure criteria parameters for hot electron degradation simulation 180 field separators input language syntax file formats defining output 235 filenames creating by modifying input filenames 59 January 2004 321 percent codes 269 creating from parts of input filenames colon modifiers 272 generation 236 files state reading 201 263 firstrun parameter Monte Carlo analysis 169 using 171 floating resistors and convergence problems 296 forbidden operating regions for transistors specifying 291 formatting alarm parameter 291 analyses composed of subcircuits analysis parameters 134 analysis statements 66 check statement 194 290 colon modifiers 274 commentlines 59 conditional if statement 109 control statements 69 currents parameter 219 231 customized percent codes 271 ic statement 198 260 identical components in parallel identical subcircuits in parallel include statements 72 info statement 204 234 instance statements 62 line extension 59 model statements 71 models for multiple
271. m m20x04 378 nA 2 21 mV 376 m 2 34 mV 1 16 m10x04 363 nA 539 uV 92 m 567 uV 293 m m08 131 nA 379 uV 64 9 m 400 uV 203 m m16 46 7 nA 267 uV 45 9 m 283 uV 142 m m32 vd 3 477 mA 15 91 uA 3 sigma variation This says that the 3 sigma variation at i vd due to the mismatch models is 3 477 mA 15 91 uA The 3 477 mA is the dc operating value of i vdd and 15 91 uA is the 3 sigma variation due to the device mismatches The device mp6 contributes the most to the output variation at 13 8 uA followed by m01 which contributes 6 99 uA The equivalent 3 sigma Vth variation of mp6 is 2 21 mV The relative 3 sigma beta current factor variation of mp6 is 0 35796 The equivalent 3 sigma gate voltage variation is 2 26 mV The relative 3 sigma lds variation of mp6 is 1 7196 The output can also be written in psf and you can view the table using Analog Design Environment The following statement investigates the 3 sigma dc variation on output v n1 n2 The result of the analysis is printed in a psf file and the cpu statistics of the analysis are generated dcmm2 n1 n2 dcmatch mth 1e 3 where rawfile In the following example the output is the voltage drop across the 1st port of r3 demm3 dcmatch mth 1e 3 oprobe r3 portv 1 For the following statement the output of the analysis is printed to a file circuitName info what dcmm4 n3 0 dcmatch mth le 3 where file file C r info what You can use sweep parameters on the dcm
272. m2 d g s b longmod 1 1 w w long channel model model shortmod vto 0 6 gamma 2 etc model longmod vto 0 8 gamma 66 etc ends sl Based on the value of parameter 1 one of the following is chosen A short channel model A long channel model January 2004 110 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Previously the transistor instances had to have unique names such as m1 and m2 in the preceding example even though only one of them could actually be chosen Now you can use the same name for both instances provided certain conditions are met The following example shows a powerful modeling approach that combines model binning based on area with inline subcircuits for a bipolar device general purpose binning and inline models simulator lang spectre parameters VDD 5 vec 2 0 vsource dc VDD vin 1 0 vsource dc VDD ql 1 2 0 0 npn_mod area 350e 12 gets 20x20 scaled model q2 1 3 0 0 npn_mod area 25e 12 gets 10x10 scaled model q3 13 0 0 npn mod area 1000e 12 gets default model inline subckt npn mod cbe s generalized binning based on area parameters area 5e 12 ab area lt 100e 12 npn mod cbe s npn10x10 10u 10u inline device else if area 400e 12 npn mod cbe s npn20x20 20u 20u inline device else npn mod cbe s npn default 5u 5u inline device model npn default bjt is 3 2e
273. mFormat Valid values RI MA and DB Default value RI inputFile Input file name outputtFile Output file name January 2004 129 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses This chapter discusses the following topics Types of Analyses on page 131 Analysis Parameters on page 134 Probes in Analyses on page 135 Multiple Analyses on page 135 Multiple Analyses in a Subcircuit on page 138 DC Analysis on page 139 AC Analysis on page 140 Transient Analysis on page 141 Pole Zero Analysis on page 148 Other Analyses sens fourier dcmatch and stb on page 150 Advanced Analyses sweep and montecarlo on page 159 Special Analysis Hot Electron Degradation on page 178 January 2004 130 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Types of Analyses This section gives a brief description of the Spectre circuit simulator analyses you can specify Spectre analyses frequently let you sweep parameters estimate or specify the DC solution specify options that promote convergence and select annotation options You can specify sequences of analyses any number in any order For a more detailed description of each analysis and its parameters consult the Spectre online help spectre h DC analysis dc Finds the DC operating point or DC transfer curves of the circuit AC small signal analyses ua AC analysis ac Linearizes the circuit about the DC operating
274. me Name of the checklimit statement nable check1 check2 checkn Specifies the checks to be enabled disable check1 check2 checkn Specifies the checks to be disabled start value The beginning time at which the specified check is to be enabled or disabled for transient analyses stop value The end time at which the specified check is to be enabled or disabled for transient analyses severity none notice warning error Severity level of the message if the check fails This overrides the error levels specified for individual checks If you set the severity to none the severity level depends on the assert settings Default none checkallasserts yes no Enables or disables all the checks in the netlist For information on defining checks see The assert Statement on page 189 Examples This section displays the cumulative effect of the checklimit statements By default all asserts are enabled assertl assert2 assert3 assert4 and Mychecklimitl appear in include file modell assert5 assert6 and assert7 and Mychecklimit2 appear in include file model2 Mychecklimit3 and Mychecklimit4 appear in the netlist containing include files modell and model2 Mychecklimitl checklimit disable assert2 assert5 disables assert2 and assert5 and keeps assert1 assert3 assert4 assert 6 and assert7 enabled This condition remains in effect until the ne
275. me The name you give to the statement Unlike SPICE instance names the first character in Spectre instance names is not significant January 2004 62 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists nodel nodeN The names you give to the nodes that connect to the component You have the option of putting the node names in parentheses to improve the clarity of the netlist See the examples later in this chapter You can use the hierarchical operator to represent nodes inside a subcircuit hierarchy in your netlist The Spectre circuit simulator supports forward referencing retaining information about a node that is not defined yet and mapping it when the node is defined and relative path referencing accessing a node with reference to the current scope Look for examples in the section below The simulator does not support hierarchical terminals in netlists master This is the name of one of the following A built in primitive Such as resistor A model A subcircuit An AHDL module SpectreHDL or Verilog A language Note The instance statement is used to call subcircuits and refer to AHDL modules as well as to specify individual components For more information about subcircuit calls see Subcircuits on page 93 For more information about the SpectreHDL product see the SpectreHDL Reference manual For more information about Verilog A see the Verilog A Language Reference manual para
276. meteri valuel This is an optional field you can repeat any number of times in parameterN valueN an instance statement You use it to specify parameter values for a component Each parameter specification is an instance parameter followed by an equal sign followed by your value for the parameter You can find a list of the available instance parameters for each component in the Spectre online help spectre h As with node names you can place optional parentheses around parameter specifications to improve the clarity of the netlist For example c 10E 12 For subcircuits and ahdl modules the available instance parameters are defined in the definition of the subcircuit or AHDL module In addition all subcircuits have an implicit instance parameter m for defining multiplicity For more details about m see Identical Components or Subcircuits in Parallel on page 65 January 2004 63 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Examples of Instance Statements In this example a capacitor named c1 connects to nodes 2 and 3 in the netlist Its capacitance is 10E 12 Farads C1 2 3 capacitor c 10E 12F The following example specifies a component whose parameters are defined in a model statement In this statement npn is the name of the model defined in a model statement that contains the model parameter definitions Q1 is the name of the component and o1 i1 and 52 are the connecting nodes of
277. mplifier or a narrow band filter In this analysis the tones can be large enough to create significant distortion but not so large as to cause the circuit to switch or clip The frequencies of the tones need not be periodically related to each other or to the large signal LO or clock Thus you can make the tone frequencies very close to each other without penalty which allows efficient computation of intermodulation distortion of even very narrow band circuits January 2004 22 Product Version 5 0 Spectre Circuit Simulator User Guide Introducing the Spectre Circuit Simulator The fourth analysis that SpectreRF adds to the Spectre circuit simulator is the envelope following analysis This analysis computes the envelope response of a circuit The simulator automatically determines the clock period by looking through all the sources with the specified name Envelope following analysis is most efficient for circuits where the modulation bandwidth is orders of magnitude lower than the clock frequency This is typically the case for example in circuits where the clock is the only fast varying signal and other input signals have a spectrum whose frequency range is orders of magnitude lower than the clock frequency For another example the down conversion of two closely placed frequencies can also generate a slow varying modulation envelope The analysis generates two types of output files a voltage versus time td file and an amplitude phase vers
278. mulator User Guide Index Symbols codes 244 predefined 269 predefined percent code 271 in syntax 15 in Spectre syntax 59 colon modifier 273 in syntax 14 in vectors 80 in Spectre syntax 59 in syntax 15 in syntax 14 A A predefined percent code 270 absolute error tolerance 143 abstol parameter 76 143 AC analysis 140 AC analysis brief description of 131 accuracy correcting problems 298 improving 18 user control of tolerances 18 AHDL variables saving 232 AHDL definition 21 alarm parameter 291 Tapora functions 88 all as homotopy parameter option 267 as info statement parameter 203 233 as pwr option 216 228 as save parameter option 218 230 allglobal relative error parameter 142 144 alllocal relative error parameter 142 144 allpub as save parameter option 218 23 alter statement 69 189 266 changing parameter values with example 187 265 formatting 187 265 use with circuit parameters 189 266 e example of use in netlist 11 January 2004 altergroup statement changing parameter values with 188 265 using 70 Analog Artist case sensitivity of scale factors 84 use in mixed signal simulation 23 use of with Spectre 20 Analog Waveform Display AWD brief description of 14 20 using 34 analog workbench design system use of with Spectre 23 analyses AC 140 basic rules 68 brief description of types 131 DC 139 envelope following 23 132
279. n However if you do not specify points you can increase accuracy by requesting more harmonics which creates more points The large number of points required for accurate results is not a result of aliasing Many points are needed because a quadratic polynomial interpolates the waveform between the time points If you use too few time points the polynomials deviate slightly from the true waveform between time points and all of the computed Fourier coefficients are slightly in error The algorithm that computes the Fourier integral does accept unevenly spaced time points but because it uses quadratic interpolation it is usually more accurate using time steps that are small and nearly evenly spaced This device is not supported within altergroup Instance Definition Name p n pr nr ModelName parameter value Name p n pr nr fourier parameter value The signal between terminals p and n is the test or numerator signal The signal between terminals pr and nr is the reference or denominator signal Fourier analysis is performed on terminal currents by specifying the term or refterm parameters If both term and p or n are specified then the terminal current becomes the numerator and the node voltages become the denominator By mixing voltages and currents it is possible to compute large signal immittances Model Definition model modelName fourier parameter value DC Match Analysis This analysis computes th
280. n you will learn the following m How to save voltages for individual nodes m How to save all signals for an individual component m How to save selected signals for an individual component The syntax for the save statement varies slightly depending on whether the requested data is from the main circuit or a subcircuit Saving Main Circuit Signals The save statement general syntax has the following arguments You can specify more than one argument with a single save statement and you can mix the types of arguments in a single statement January 2004 211 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Save Save Save Save signalName compName compName modifier subcircuitName terminallndex signalName is generally the netlist name of a node whose voltage you want to save If the specified node name is not unique an instance in the netlist has the same name the Spectre circuit simulator saves the node compName is the netlist name of a component whose signals you want to save modifier specifies signals you want to save for a particular component It can have the following types of values Q A terminal name Terminal names for components are the names for nodes in component instance definitions You can find instance definitions for each component in the component parameter listings in the Spectre online help spectre h For example the following is the instance
281. n also specify device instances or models as design parameters without further specifying parameters but this approach might result in a number of error messages The Spectre simulator attempts sensitivity analysis for every device parameter and sends an error message for each parameter that cannot be varied The Spectre simulator does however perform the requested sensitivity analysis for appropriate parameters The ana are the analyses for which sensitivities are calculated These can be analysis instance names for example opBegin and ac2 or analysis type names for example DC and AC Examples of the sens Command The following examples illustrate sens command format sens qi betadc 2 Out to vcc dc nbjtl rb for analDC This command computes DC sensitivities of the bet adc operating point parameter of transistor q1 and of nodes 2 and Out to the dc voltage level of voltage source vcc and to the January 2004 152 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses model parameter rb of nbjt1 The values are computed for DC analysis analDc The results are stored in the files analDC vcc dc and analDC nbjt1 rb sens 1 n2 7 to ql area nbjtl rb for analAC This command computes AC sensitivities of nodes 1 n2 and 7 to the area parameter of transistor q1 and to the model parameter rb of nb jt1 The values are computed for each frequency of the AC analysis analAc The results are stored in the file
282. n circuits such as mixers or periodically driven circuits such as oscillators or switched capacitor or switched current filters The periodic small signal analyses periodic AC PAC analysis periodic transfer function PXF analysis and periodic noise Pnoise analysis are similar to Spectre s AC XF and Noise analyses but the traditional small signal analyses are limited to circuits with DC operating points The periodic small signal analyses can be applied to circuits with periodic operating points such as the following Mixers VCOs Switched current filters Phase frequency detectors Frequency multipliers Chopper stabilized amplifiers Oscillators Switched capacitor filters Sample and holds Frequency dividers Narrow band active circuits The third SpectreRF addition to Spectre functionality is periodic distortion PDISTO analysis PDISTO analysis directly computes the steady state response of a circuit driven with a large periodic signal such as an LO local oscillation or a clock and one or more tones with moderate level With PDISTO you can model periodic distortion and include harmonic effects PDISTO computes both a large signal the periodic steady state response of the circuit and also the distortion effects of a specified number of moderate signals including the distortion effects of the number of harmonics that you choose This is a common scenario when trying to predict the intermodulation distortion of a mixer a
283. n full access to Spectre and its features with a SPICE netlist by controlling the input language Spectre provides three ways to gain access to its language in a SPICE netlist 1 Change the input language to Spectre using the simulator lang command 2 Append Spectre parameters to a SPICE statement 3 Hide Spectre text from SPICE Each of these methods is discussed in the following sections Spectre s simulator lang Command You can use the Spectre Netlist Language or an extended form of the SPICE2 3 input language for your simulation You specify which language with a simulator lang command You can change the input processing mode with the simulator lang command A simulator lang spice command causes subsequent input to be processed in the SPICE extension mode a simulator lang spectre command causes the input processing to conform to the Spectre Netlist Language Remember that you can give the simulator lang command anywhere that you can enter an instance statement and it affects all subsequent input regardless of whether the command is part of an if statement Use of Spectre syntax in the SPICE mode or SPICE syntax in the Spectre mode results in an error The fomat of the simulator lang command is as follows simulator lang spice simulator lang spectre Although the simulator lang command is expected to be the first line in the netlist it does not have to be The commands take effect immediately and remain in effect until the en
284. n mos f you specify more than one parameter limit for a component you need to specify the component keyword only once The Spectre simulator assumes the keyword is unchanged from the previous parameter unless you specify a new component keyword M f you give a parameter limit more than once your last instructions override previous limits B f you mention a parameter but give it no limits all limits are disabled for that parameter m You can specify limits for integer real or enumerated parameters Enumerated parameters are those that take only predefined values such as yes or no and a11 or none To specify limits on enumerated parameters use the index of the enumeration in the limits declaration for that parameter To find the index of a parameter of component name see the parameter listings for the component name in the Spectre online help spect re h and count the enumerations in the limits declaration starting from zero For example to specify that the BJT operating point parameter region should not be rev reversed look for the region parameter in the parameter listings for the BUT component The region parameter is described as follows January 2004 287 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting region fwd Estimated operating region Possible values are off fwd rev Or sat For this parameter off has index 0 fwd has index 1 rev has index 2 and sa
285. n special situations to improve performance This section also tells you about parameters you can set that improve transient analysis convergence January 2004 141 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Trading Off Speed and Accuracy with a Single Parameter Setting You can set transient analysis speed and accuracy parameters individually or you can set a group of parameters that control transient analysis accuracy with the errpreset parameter You can set errpreset to three different values E liberal M moderate M conservative At liberal the simulation is fast but less accurate The liberal setting is suitable for digital circuits or analog circuits that have only short time constants At moderate the default setting simulation accuracy approximates a SPICE2 style simulator At conservative the simulation is the most accurate but also slowest The conservative setting is appropriate for sensitive analog circuits If you still require more accuracy than that provided by conservative tighten error tolerance by setting reltol to a smaller value Description of errpreset Parameter Settings The effect of errpreset on other parameters is shown in the following table In this table T stop start errpreset reltol relref method maxstep lteratio liberal x10 0 allglobal gear2 lt 7 10 3 5 moderate x1 0 sigglobal traponly lt 17 50 3 5 conservative x0 1 alllocal gear2only T 100
286. n time all Saves all terminal currents and currents available from selected settings to the raw file Can significantly increase simulation time Note Currently if you set the currents parameter value to nonlinear orall and do not specify a save parameter value in an options statement the Spectre simulator saves circuit nodes as well as the currents you requested This might change in future releases of the Spectre simulator Examples of the currents Parameter You use the following syntax for the currents parameter in the opt ions statement For more information about the opt ions statement see the parameter listings in the Spectre online help spectre h B The Spectre simulator saves all terminal currents for nonlinear components currents specified with the save statement and routinely computed currents optl options currents nonlinear B The Spectre simulator saves all terminal currents opt2 options currents all January 2004 231 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options Setting Multiple Current Probes Sometimes you might need to set a large number of current probes This could happen for example if you need to save a number of ACs Current probes can find such small signal currents when they are not normally computed You can specify that all currents be calculated with current probes by placing useprobes yes in an options statement Setting multiple current
287. nalysis see Special Analysis Hot Electron Degradation on page 178 Analysis Parameters You specify parameter values for analysis and control statements just as you specify those for component and model statements but many analysis parameters have no assigned default values You must assign values to these parameters if you want to use them To assign values to these parameters simply follow the parameter keyword with an equal sign and your selected value For example to set the points per decade dec value to 10 you enter dec 10 Note Some parameters require text strings usually filenames as values You must enclose these text strings in quotation marks to use them as parameter values January 2004 134 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses When analysis parameters do have default values these values are given in the parameter listings for that analysis in the Spectre online help spectre h A listing like the following tells you that the default value for parameter 1in is 50 steps lin 50 Emission coefficient parameters Probes in Analyses Some Spectre analyses require that you set probes Remember the following guidelines when you set probes m Youcan name any component instance as a probe m Ifthe probe component measures a branch current you can use it as either a current probe or a voltage probe Component instances that do not calculate branch currents can be used only a
288. name is t ran stepResponse tran stop 100ns Instructions for a Spectre Simulation Run When you complete a netlist you can run the simulation with the spect re command gt Torun a simulation for the sample circuit type the following at the command line Spectre osc scs January 2004 32 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre Note osc scs is the file that contains the netlist Following Simulation Progress As the simulation runs the Spectre simulator sends messages to your screen that show the progress of the simulation and provide statistical information In the simulation of osc scs the Spectre simulator prints some warnings and notifications The Spectre simulator tells you about conditions that might reduce simulation accuracy When you see a Spectre warning or notification you must decide whether the information is significant for your particular simulation Screen Printout The printout for the osc scs simulation looks like this spectre ver 5 0 0 052603 27 May 2003 Simulating osc scs on cds11047 at 1 21 54 PM Wed Aug 20 2003 Circuit inventory nodes equations bjt capacitor inductor isource resistor vsource PNHRRABANWOU CKCkckCck ck kCck ck kck ck kck ck kCck ck ck ck ck kk ck k ck k ck ck k ck ck kck ck k ck ck kk k kk kk kkkkk k Transient Analysis OscResp time 0 s gt 80 us KKKKKK KKK KKK Ck CK CI CC Ck CK CK CI CCS Ck CK Ck CK
289. nce vcc If you want to save the instance vcc you must assign a different name to it January 2004 61 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Escaping Special Characters in Names If you have old netlists that contain names that do not follow Spectre syntax rules you might still be able to run these netlists with the Spectre simulator The Spectre Netlist Language permits the following exceptions to its normal syntax rules to accommodate old netlists Use these features only when necessary If you place a backslash before any printable ASCII character including spaces and tabs you can include the character in a name You can create a name from the following elements in the order given A string of digits followed by Q Letters underscores or backslash escaped characters followed by Q A digit followed by Q Underscores digits or backslash escaped characters This accommodates model or subcircuit libraries that use names like 2N2222 Instance Statements In this section you will learn to place individual components into your netlist and to assign parameter values for them Formatting the Instance Statement To specify components you use the instance statement You format the instance statement as follows name nodel nodeN master parami valuel paramN valueN When you specify components with the instance statement the fields have the following values na
290. ncy without loading the circuit The algorithm used is based on the Fourier integral rather than the discrete Fourier transform and therefore is not subject to aliasing Even on broad band signals it computes a small number of Fourier coefficients accurately and efficiently Therefore this Fourier analysis is suitable on clocked sinusoids generated by sigma delta converters pulse width modulators digital to analog converters sample and holds and switched capacitor filters as well as on the traditional low distortion sinusoids produced by amplifiers or filters For more information about the Fourier analysis see Chapter 4 Analysis Statements of the Spectre Circuit Simulator Reference Q DC Match Analysis dcmat ch Computes the statistical deviation in the DC operating point of the circuit caused by device mismatch For more information about the dcmatch analysis see DC Match Analysis on page 154 January 2004 133 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Q Stability Analysis stb Linearizes the circuit about the DC operating point and computes loop gain gain margin and phase margin for a specific feedback loop or an active device The stability of the circuit can be determined from the loop gain waveform The probe parameter must be specified to perform stability analysis For more information about the stability analysis see Chapter 4 Analysis Statements of the Spectre Circuit Simulator
291. nd warning messages 284 percent codes 271 D D predefined percent code 270 damped pseudotransient method 267 data compression 147 dataDir command line option 34 DC analysis 139 brief description of 131 correcting accuracy problems 298 maxiters parameter and convergence problems 296 oppoint parameter 161 transfer curves 161 DC convergence problems correcting 295 dec parameter 163 defaults analyses 68 analysis parameters 135 C preprocessor CPP 244 Cadence range limits for warnings 284 checkpoint spectre command option 242 commandline 244 controlling destination and format of Spectre results 244 controlling system generated messages 244 creating checkpoints and initiating recovery 244 measurement units of parameters 119 name of the simulator 244 overriding in UNIX environment variables 246 percent codes 244 screen display 244 setting for environment with SPECTRE_DEFAULTS simulation environment 244 January 2004 spectre command 244 changing 245 examining 244 defining a library 75 degradation parameters for hot electron degradation simulation 180 181 Design Framework ll use of with Spectre 23 Designer s Guide to SPICE and Spectre 14 dev parameter 161 devices as pwr option 216 228 diagnosis mode use of 20 differential amplifier example of input file 112 direction associated reference 58 directory names generating 236 specifying yourown 238 displaying a waveform with
292. nitial condition use the read transient analysis parameter To read a state file as a nodeset use the readns parameter This example reads the file int Cond as initial conditions DoTran z12 tran start 0 stop 0 003 step 0 00015 maxstep 6e 06 read intCond This second example reads the file soluEst as a nodeset DoTran z12 tran start 0 stop 0 003 step 0 00015 maxstep 6e 06 readns soluEst Special Uses for State Files State files can be useful for the following reasons M You can save state files and use them in later simulations For example you can save the solution at the final point of a transient analysis and then continue the analysis in a later simulation by using the state file as the starting point for another transient analysis m You can use state files to create automatic updates of initial conditions and nodesets The following example demonstrates the usefulness of state files altTemp alter param temp value 0 Drift dc param temp start 0 stop 50 0 step 1 readns ua741 dc0O0 write ua741 dc0 XferVsTemp xf param temp start 0 stop 50pso bp Rlhad freq 1kHz readns ua741 dcO The first analysis computes the DC solution at T20C saves it to a file called ua741 dc0 and then sweeps the temperature to T 50C The transfer function analysis x resets the January 2004 201 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements temperature to zero Because of the temperature c
293. nom Rnom WB WB MULT MULT dR dR call RPLR PR ends RPLR The following example is a differential amplifier netlist showing how a design can combine process modeling with process and geometry effects a differential amplifier biased with a 1mA current source simulator lang spectre include ProcessSimple n include Process h El 1 0 vsource dc 12 pullup resistors 4k ohms nominal R1 12 RPLR Rnom 4k WB 5 5 units wide model will calc length R2 1 3 RPLR Rnom 4k WB 10 10 units wide model will calc length the input pair January 2004 106 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features TNSA1 2 4 5 0 TNSA WE 10 LE 10 TNSA2 3 4 5 0 TNSA WE 10 LE 10 no differential input voltage both inputs tied to same source E4 4 0 vsource dc 5 current source biasing J5 5 0 isource dc 1m dcop dc Binning Binning is the process of partitioning a device with different sizes into different models Before BSIM 3v3 it was very difficult to fit all the devices with a single model statement over very wide ranges of device sizes To improve fitting accuracy you might characterize devices into several models with each model valid only for a limited range of device sizes For example suppose you have a device with a length L from 0 25 um to 100 um and a width W from 0 25 um to 100 jum You migh
294. ns can be affected by using small truncation factors January 2004 176 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Multiple Statistics Blocks You can use multiple statistics blocks which accumulate or overlay each other Typically process variations mismatch variations and correlations between process parameters are specified in a single statistics block This statistics block can be included in a process include file such as the ones shown in the example in Process Modeling Using Inline Subcircuits on page 104 A second statistics block can be specified in the main netlist where actual device instance correlations are specified as matched pairs The following statistics block can be used to specify the correlations between matched pairs of devices and probably is placed or included into the main netlist by the designer These statistics are used in addition to those specified in the statistics block in the preceding section so that the statistics blocks overlay or accumulate define correlations for matched devices ql and q2 Statistics correlate dev ql q2 param XISN cc 0 75 Note You can use a single statistics block containing both sets of statements however it is often more convenient to keep the topology specific information separate from the process specific information Correlation Statements There are two types of correlation statements that you can use m
295. ns on each port sequentially and performs a linear small signal analysis The Spectre simulator converts the response of the circuit at each port into S parameters For more information about the S parameter analysis see Chapter 4 Analysis Statements of the Spectre Circuit Simulator Reference Transient analyses Q Transient analysis t ran Computes the transient response of the circuit over a specified time interval You can specify initial conditions for this analysis If you do not specify initial conditions the analysis starts from the DC steady state solution You can influence the speed of the simulation by setting parameters that control January 2004 131 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses accuracy requirements and the number of data points saved For more information about the transient analysis see Transient Analysis on page 141 Q Time domain reflectometer analysis t dr Linearizes the circuit about the DC operating point and computes the reflection and transmission coefficients versus time This is the time domain equivalent of the S parameter analysis For more information about time domain reflectometer analysis see Chapter 4 Analysis Statements of the Spectre Circuit Simulator Reference m Pole Zero analysis pz Linearizes the circuit about the DC operating point and computes the poles and zeros of the linearized network m RF analyses Q Envelope Follow
296. nsient analysis supports hot electron calculations January 2004 178 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses m Hotelectron calculations are available with the following components Q MOS levels 1 2 and 3 Q BSIM levels 1 and 2 m You can choose between the following substrate current models for the simulation Q The Toshiba model Q The BERT model To simulate the hot electron degradation of a circuit you need to run at least two transient analyses In the first analysis you establish baseline values for a new circuit To create this baseline you set the ci rcuitage parameter to zero ci rcuitage 0 circuitage 0 is also the default value if you leave this parameter unspecified For each subsequent transient analysis you reset the age of the circuit by changing the value of the circuitage parameter You specify circuitage values in years For example circuitage 4 0 specifies a circuit that is 4 years old Hot Electron Degradation Analysis To specify an analysis of hot electron degradation you need to provide appropriate parameter settings m You must be sure the degradation parameter is set to degradation yes for the instance statement of each component you want to analyze This parameter takes its default value from the setting in the model statement All MOS and BSIM components require model statements as well as instance statements B You must set all necessary parameters in the m
297. nt continues on the next line The backslash must be the last character in the line because it escapes the carriage return model npn bjt type npn bf 80 rb 100 vaf 50 cjs 2pf tf 0 3ns tr 6ns cje 3pf cjc 2pf When you create an instance statement that refers to a model statement for its parameter values you must specify the model name as the master name For example an instance statement that receives its parameter values from the previous model statement might look like this Q1 vcc bl e vcc npn Check documentation for components to determine which parameters are expected to be provided on the instance statement and which are expected on the model statement Analysis Statements The last section of the sample netlist has the analysis statement An analysis statement has the same syntax as an instance statement except that the analysis type name replaces the master name To specify an analysis you must include the following information in a netlist statement m A unique name for the analysis statement W Possibly a set of node names m The name of the type of analysis you want m Any additional parameter values associated with the analysis To find the analysis type name and the parameters you can specify for an analysis consult the parameter listing for that analysis in the Spectre online help spectre h The following analysis statement specifies a transient analysis The analysis name is stepResponse and the analysis type
298. nvergence criteria also diminishes the allowable local truncation error Tolerance rg You might not want the truncation error tolerance tightened because this adjustment can increase simulation time You can prevent the decrease in the time step by increasing the 1teratio parameter to compensate for the tightening of reltol January 2004 143 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Adjusting Relative Error Parameters You determine the treatment of the relative error with the relref parameter The relref parameter determines which values the Spectre simulator uses to compute whether the relative error tolerance reltol requirements are satisfied You can set relref to the following options B The relref pointlocal setting compares the relative errors in quantities at each node relative to the current value of that node m The relref alllocal setting compares the relative errors in quantities at each node to the largest value of that node for all past time points m The relref sigglobal or relref allglobal settings compare relative errors in each of the circuit signals to the maximum of all the signals in the circuit m In addition the relref allglobal setting compares equation residues the amount by which Kirchhoff s Current Law also known as Kirchhoff s Flow Law is not satisfied for each node to the maximum current floating onto the node at any time in that node s past history Set
299. o log xxx Normal log 20000 12 The nominal value for the log normal distribution is the natural log of the value of the parameter before the Monte Carlo analysis is run If you specify a normal distribution for a parameter P1 whose value is 5000 and you specify a standard deviation of 100 the actual distribution is produced such that log P N log 5000 100 Uniform This distribution is specified using dist unif The uniform distribution for parameter x is generated according to x unif mean N mean N January 2004 175 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses such that the mean value is the nominal value of the parameter x and the parameter is varied about the mean with a range of N The standard deviation is not specified for the uniform distribution but its value can be calculated from the formula std N sqrt 3 The nominal value for the uniform distribution is the value of the parameter before the Monte Carlo analysis is run The uniform interval is specified using the parameter N For example specifying dist unif N 5 fora parameter whose value is 200 results is a uniform distribution in the range 200 N that is from 195 to 205 You can also specify percent yes in which case the range is 200 N that is from 190 to 210 Derived parameters that have their default values specified as expressions of other parameters cannot have distributions specified for them Only parameters that
300. o e ae RE RSV NN UD Ok i ea Sa ah Ard ape AD UTRAM 193 Example in a a hdi iab cn dtd ty we tus ear ad Dad 8d wd EVE Tera is 193 Example Ge te We feodo Ot ear ear eV nen eae ie Sah Ae Re O i eta dd 194 Ihe check Statement 5 inik etait eal ad E ECC oe EO SIE aes 194 The checklimit Statement 524222 sace Ab QR Glad ba hala Sars ad ue eate ERE 195 Examples arces eet tas den d eats Eb A e a a nates stein CL US eu ae Pee nee 196 The ic and nodeset Statements qs ist eet eae Sei oe Hele este wc y ex OE eS EGG 197 Setting Initial Conditions for All Transient Analyses 197 Supplying Solution Estimates to Increase Speed 199 Specifying State Information for Individual Analyses 199 Jibient Sstatemelbil 2353 3 o tok ee aed yeti CL di e ER Eee MEE EE DEL ES 202 Specifying the Parameters You Want to Save lllllllllsun 203 Specifying the Output Destination llle 204 Examples of the info Statement saciid x RR E Ea atat d C EORR Ded 204 Printing the Node Capacitance Table 0 ccc eee 205 The options Statement uuo t ror we Mae Ie Bs Be es Epio S0 ee d 208 options Statement Format 2 se hs3 eee METER EE EE A wee Rx 209 options Statement Example 0 2002 eee 209 SENG Tolerances cue es ards dog EE SEo gs Rigel oS race Oo Cems Ed E Oe 209 Additional options Statement Settings You Might Need to Adjust 210 TE pararmiset
301. od Sip o tbe p aca dae aa ed 241 Interrupting a Simulation Aarsessext pereo RE RM EP EPIS PAR ERU 242 Recovering from Transient Analysis Terminations esses 242 Creating Recovery Files from the Command Line 243 Setting Recovery File Specifications for a Single Analysis 243 Restarting a Transient Analysis ios sene eui See he See bebe wee dads 244 Controlling Command Line Defaults i555 5 229 deeb deca hr E emm edo 244 Examining the Spectre Simulator Defaults 0 cee eee 244 January 2004 9 Product Version 5 0 Spectre Circuit Simulator User Guide Setting Your Owr Defaults 3 x4 rec ri aen RERO S ANUS Dat Ca SUR lem B d t Beles 245 References for Additional Information about Specific Defaults 246 Overriding DeldulllS 2 67 20 Ade Dees Bars sc aree serie dh ith GEO ae A ACER eae a 246 10 E NOY UO ETE TE OE E TT 247 Encrypting a Netlist 25 ud uie Eu Meese Ayden i etipr era eR She ls olea Pravni di codon d foit 248 What You can BEnGypl ee pree wa 4 rec d ec a or por prt as de EC RR vas oes 249 Encrypted Information During Simulation liliis 254 Protected Device ccce rA 254 Protected Node lll elle ln 255 Protected Global and Netlist Parameters eene 255 Protected Subcircuit Parameters eene 255 Protected M
302. odel Parameters ee 255 Multiple Name Sp dc6s esis 92224 seed paneer iod re Puce RU quU SUP E Ren 256 11 Time Saving Techniques 0000 0000 eee 257 Specifying Efficient Starting Points auae c urere ro ERO ia C o eA aes 258 Reducing the Number of Simulation Runs 0 cee ee 258 Adjusting Speed and Accuracy is er peer REESE ack aap lad edis 258 Saving Time by Starting Analyses from Previous Solutions 258 Saving Time by Specifying State Information 0 0 0 cee eee 259 Setting Initial Conditions for All Transient Analyses Lille 259 Supplying Solution Estimates to Increase Speed 261 Specifying State Information for Individual Analyses 261 Saving Time by Modifying Parameters during a Simulation 264 Changing Circuit or Component Parameter Values 265 Modifying Initial Settings of the State of the Simulator 266 Saving Time by Selecting a Continuation Method lullsn 267 12 Managho FES TC OUTLET 268 About Spectre Filename Specification 9 Ies Meee ae he bee eee ees 269 January 2004 10 Product Version 5 0 Spectre Circuit Simulator User Guide Creating Filenames That Help You Manage Data 0 aee 269 Creating Filenames by Modifying Input Filenames
303. odel statements of the components you want to analyze To determine which model parameters you must specify look at the parameter listings for each component in the Spectre online help spectre h Examine the following subsections Q Degradation related parameters Q The Spectre simulator stress parameters for Toshiba analysis Q BERT stress parameters for BERT analysis January 2004 179 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses caution Be careful to set the following parameters correctly dvthc dvthe duoc and duoe These are degradation parameters which are usually obtained from DC stress measurements Errors in setting these parameters can lead to inaccurate results B You must set the circuitage parameter correctly in the transient analyses In the following example the Spectre simulator makes a baseline measurement and then examines changes in circuit behavior after 1 5 and 10 years new tran 1n 100n circuitage 0 yearl tran 1n 100n circuitage 1 year5 tran 1n 100n circuitage 5 yearl0 tran 1n 100n circuitage 10 Note After you establish the baseline value you can enter subsequent circuitage parameters in any order Output Options for Hot Electron Degradation Analysis After the transient analyses are completed the Spectre simulator produces a sorted table of device lifetimes Two device lifetimes are calculated for each device that receives hot electron degradation analysis T
304. ol the accuracy of the solution to the discretized equation by setting the reltol and xabstol where x is the access quantity such as v or i parameters in an options or set statement These parameters determine how well the circuit conserves charge and how accurately the Spectre simulator computes circuit dynamics and steady state or equilibrium points You can set the integration error or the errors in the computation of the circuit dynamics such as time constants relative to reltol and abstol by setting the 1teratio parameter Tolerancewn abstol reltol Ref Tolerance rg Tolerancewg lteratio The Ref value is determined by your setting for relref the relative error parameter as explained in Adjusting Relative Error Parameters on page 144 In the previous equations Tolerancewg is a convergence criterion that bounds the amount by which Kirchhoff s Current Law is not satisfied as well as the allowable difference in computed values in the last two Newton Raphson NR iterations of the simulation Tolerance rg is the allowable difference at any time step between the computed solution and a predicted solution derived from a polynomial extrapolation of the solutions from the previous few time steps If this difference is greater than Tolerance rg the Spectre simulator shortens the time step until the difference is acceptable From the previous equations you can see that tightening reltol to create more strict co
305. om Spectre 16 26 58 186 301 input language case sensitivity 59 case sensitivity of scale factors 84 combining with Spectre mode 54 reading 50 language title line 51 sptrcommand 129 sst2 output format 234 start parameter 163 starting asimulation 240 analyses from previous solutions 258 state files analysis efficiency with netlist example Product Version 5 0 Spectre Circuit Simulator User Guide discussed 136 and writefinal parameter 200 262 creating manually 201 263 reading 201 263 special uses for 201 263 using to specify initial conditions and estimate solutions 200 262 write parameter 200 262 state information specifying initial conditions 197 259 nodesets 197 259 state of the simulator modifying initial settings 189 266 statements analysis 66 formatting control 68 instance 62 library 75 model 70 examples formatting netlist 58 paramset 210 save 211 statistics 221 statistical analysis performing 164 statistics blocks 164 multiple Monte Carlo analysis 177 66 67 i specifying parameter distributions 173 statistics statement 221 status checking simulation 241 step parameter 145 163 step size for DC sweep and convergence problems 296 stop parameter 163 stopping a simulation 242 string parameters specifying 120 strobing 145 example 147 skipstart parameter 146 skipstop parameter 146 strobedelay parameter 146 strobeperiod parameter 146 stty
306. option SpectreHDL is proprietary to Cadence and is provided for backward compatibility The Verilog A language is an open standard which was based upon SpectreHDL The Verilog A language is preferred because it is upward compatible with Verilog AMS a powerful and industry standard mixed signal language Both languages use functional description text files modules to model the behavior of electrical circuits and other systems Each programming language allows you to create your own models by simply writing down the equations The AHDL lets you describe models ina simple and natural manner This is a higher level modeling language than previous modeling languages and you can use it without being concerned about the complexities of the simulator or the simulator algorithms In addition you can combine AHDL components with Spectre built in primitives Both languages let designers of analog systems and integrated circuits create and use modules that encapsulate high level behavioral descriptions of systems and components The behavior of each module is described mathematically in terms of its terminals and external parameters applied to the module Designers can use these behavioral descriptions in many disciplines electrical mechanical optical and so on Both languages borrow many constructs from Verilog and the C programming language These features are combined with a minimum number of special constructs for behavioral simulation These high
307. ords currents To save all currents of the device static To save resistive currents of the device displacement To save capacitive currents of the device January 2004 224 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options dynamic To save charge or flux of the device oppoint To save the operating points of the device probe To measure current of the device with a probe pwr To save power dissipated on a circuit subcircuit or device all To save all signals of the device B subcircuitName is the instance name of a subcircuit call Saving terminal currents for subcircuit calls is the same as saving terminal currents for other instance statements except that you must identify individual terminal currents you want to save by the terminal index Note To save all terminal currents for subcircuit calls you use a save statement or specify the subcktprobelvl parameter in an options statement The currents all option of the opt ions statement saves currents only for devices Saving Subcircuit Signals To save a subcircuit signal with the save statement modify the main circuit syntax as follows gt Give a full path to the subcircuit name Start with the highest level subcircuit and identify the signals you want to save at the end of the path Separate each name with a period Examples of the save Statement The following table shows you examples of save statement syntax When you specify node name
308. ot enter a dev or a mod parameter This example changes the ambient temperature to 0 C change2 alter param temp value 0 The following table describes the circuit parameters you can change with the alter statement Parameter Description temp Ambient temperature tnom Default measurement temperature for component parameters scalem Component model scaling factor scale Component instance scaling factor Note If you change temp or tnom using an alter statement all expressions with temp or tnom are reevaluated Modifying Initial Settings of the State of the Simulator You can change the initial settings for the state of the simulator by placing a set statement in the netlist The set statement is similar to the options statement that sets the state of January 2004 266 Product Version 5 0 Spectre Circuit Simulator User Guide Time Saving Techniques the simulator but it is queued with the analysis statements in the order you place them in the netlist You use the set statement to change previous options or set statement specifications The modifications apply to all analyses that follow the set statement in the netlist until you request another parameter modification The set and options statements have many identical parameters but the set statement cannot modify all options statement parameters The parameter listings in the Spectre online help spectre h tell you which parameters you can reset with the set statemen
309. otal harmonic distortion at the end of the transient analysis The total harmonic distortion is found by summing the power in all of the computed harmonics except DC and the fundamental Consequently the distortion is not accurate if you request an insufficient number of harmonics The Fourier analyzer also prints the ratio of the spectrum of the first signal to the fundamental of the second so you can use the analyzer to compute large signal gains and immittances directly If you are concerned about accuracy perform an additional Fourier transform on a pure sinusoid generated by an independent source Because both transforms use the same time points the relative errors measured with the known pure sinusoid are representative of the January 2004 153 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses errors in the other transforms In practice this second Fourier transform is performed on the reference signal To increase the accuracy of the Fourier transform use the points parameter to increase the number of points Tightening reltol and setting errpreset conservative are two other measures to consider The accuracy of the magnitude and phase for each harmonic is independent of the number of harmonics computed Thus increasing the number of harmonics while keeping points constant does not change the magnitude and phase of the low order harmonics but it does improve the accuracy of the total harmonic distortion computatio
310. p command for the SPICE Reader to process the top level netlist spectrespp opamp sp This command calls Spectre with the spp and md1 command line options There are several command line options that can be used in conjunction with spect respp Specifying the Design File The command line option design is used to identify the input file In the absence of any command line options the single argument after the spect respp command is assumed to be the input netlist Therefore the following commands are identical Spectrespp opamp sp spectrespp design opamp sp Specifying the spp Binary to be Used By default the spp binary that is located in the Cadence hierarchy your_install_directory tools dfII bin spp is used by the spectrespp command You can specify the use of other spp executables with the sppbin command line option In the following example spp from the current directory is used spectrespp sppbin spp opamp sp January 2004 43 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility Specifying the Location of the Measurement Output The command line option measure is used to specify the location of the measurement output The following command spectrespp measure design measure design opamp sp writes the output to design measure If you do not use this option the output of the measure statement is written to a file with the same base name as the netlist and the suffix m
311. param temp start 0 stop 50 0 step 1 readns ua741 dc write ua741 dc Drift dc param temp start 0 stop 50 0 step 1 readns ua741 dc writefinal ua741 dc January 2004 262 Product Version 5 0 Spectre Circuit Simulator User Guide Time Saving Techniques Creating a State File Manually The syntax for creating a state file in a text editor is simple Each line contains a signal name and a signal value Anything after a pound sign is ignored as a comment The following is an example of a simple state file State file generated by Spectre from circuit file wilson during stepresponse at 5 39 38 PM jan 21 1992 1 588793510612534 2 1 17406247989272 3 14 9900516233357 pwr 15 vcc p 9 9483766642647e 06 Reading State Files To read a state file as an initial condition use the readic transient analysis parameter To read a state file as a nodeset use the readns parameter This example reads the file intCondasinitial conditions DoTran z12 tran start 0 stop 0 003 step 0 00015 maxstep 6e 06 read intCond This second example reads the file soluEst as a nodeset DoTran_z12 tran start 0 stop 0 003 step 0 00015 maxstep 6e 06 readns soluEst Special Uses for State Files State files can be useful for the following reasons M You can save state files and use them in later simulations For example you can save the solution at the final point of a transient analysis and then continue t
312. pecify values for any number of parameters You can find parameter listings for a control statement by referring to the Spectre online help spectre h Examples of Control Statements SetTemp alter param temp value 27 The preceding example of an alter statement sets the temperature for the simulation to 27 C The name for the alter statement is Set Temp and the name of the control statement type is alter You cannot alter a device from one primitive type to another For example instl 1 2 capacitor c 1pF alterfail altergroup instl 1 2 resistor r 1k is illegal January 2004 69 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists Another example of a control statement is the altergroup statement which allows you to change the values of any modifiable device or netlist parameters for any analyses that follow Within an alter group you can specify parameter instance or model statements the corresponding netlist parameters instances and models are updated when the altergroup statement is executed These statements must be bound within braces The opening brace is required at the end of the line defining the alter group Alter groups cannot be nested or be instantiated inside subcircuits Also no topology changes are allowed to be specified in an alter group The following is the syntax of the altergroup statement Name altergroup netlist parameter statements and or device
313. pecify with save statements Can significantly increase simulation time alu Saves all terminal currents and currents available from selected settings to the raw file Can significantly increase simulation time Note Currently if you set the currents parameter value to nonlinear orall and do not specify a save parameter value in an opt ions statement the Spectre simulator saves circuit nodes as well as the currents you requested This might change in future releases of the Spectre simulator Examples of the currents Parameter You use the following syntax for the currents parameter in the opt ions statement For more information about the opt ions statement see the parameter listings in the Spectre online help spectre h B The Spectre simulator saves all terminal currents for nonlinear components currents specified with the save statement and routinely computed currents optl options currents nonlinear m The Spectre simulator saves all terminal currents opt2 options currents all Setting Multiple Current Probes Sometimes you might need to set a large number of current probes This could happen for example if you need to save a number of ACs Current probes can find such small signal currents when they are not normally computed You can specify that all currents be calculated with current probes by placing useprobes yes in an options statement January 2004 219 Product Version 5 0 Spectre Circuit Simulator User Gu
314. point and computes the steady state response of the circuit to a given small signal sinusoidal stimulus This analysis is useful for obtaining small signal transfer functions For more information about the AC analysis see Chapter 4 Analysis Statements of the Spectre Circuit Simulator Reference Noise analysis noise Linearizes the circuit about the DC operating point and computes the total noise spectral density at the output The output can be either a voltage or a current If you specify an input probe the Spectre simulator computes the transfer function and the equivalent input referred noise for a noise free network For more information about the noise analysis see Chapter 4 Analysis Statements of the Spectre Circuit Simulator Reference Transfer function analysis x Linearizes the circuit about the DC operating point and performs a small signal analysis It calculates the transfer function from every source in the circuit to a specified output The output can be either a voltage or a current For more information about the transfer function analysis see Chapter 4 Analysis Statements of the Spectre Circuit Simulator Reference S parameter analysis s p Linearizes the circuit about the DC operating point and computes S parameters of the circuit taken as an N port You define the ports of the circuit with port statements You must place at least one port statement in the circuit The Spectre simulator tur
315. power dissipated in the circuit subcircuit or device Formatting the pwr Parameter The syntax for the pwr parameter is illustrated by the following examples To save the power dissipated on a device or instance of a subcircuit the syntax is save instance_name pwr To save the total power the syntax is save pwr You can explicitly save particular power variables For example save pwr xl pwr xl x2 ml pwr This statement saves three power signals m The total power dissipated pwr B The power dissipated in the x1 subcircuit instance x1 pwr B The power dissipated in the x1 x2 m1 MOSFET Power Options The pwr parameter in the options statement can also be used to save power The following table shows the five possible settings for the pwr option Setting Action all The total power the power dissipated in each subcircuit and the power dissipated in each device is saved subckts The total power and the power dissipated in each subcircuit is saved devices The total power and the power dissipated in each device is saved total The total power dissipated in the circuit is calculated and saved none No power variable is calculated or saved This is the default setting January 2004 228 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options For example opts options pwr total save xl pwr This creates two power signals pwr generated by the options statement and
316. pragma statements in the output netlist The pragma statements contain important information about encryption such as the method used the key name and the beginning and end of the encrypted block The Spectre circuit simulator uses this information while decrypting the netlist Hence it is important that you do not modify any pragma statement or the encrypted text between the pragma statements in the output file January 2004 248 Product Version 5 0 Spectre Circuit Simulator User Guide Encryption What You can Encrypt You can encrypt signals netlist and subcircuit parameters files devices and model cards You can use multiple pairs of protect unprotect to encrypt different portions of your netlist The content inside the protect unprotect block is encrypted and the content outside this block remains the same as the original netlist Encrypting a File You can encrypt a file by adding protect at the beginning and unprotect atthe end of the file Encrypting Subcircuits As described in the following sections you can encrypt an entire subcircuit part of a subcircuit or multiple subcircuit blocks Encrypting an Entire Subcircuit To encrypt an entire subcircuit place protect before the subckt and unprotect after the ends statement This encrypts the subcircuit name as well as the I O pins Since the interfaces are not readable after encryption Cadence recommends that you add some information on how the interface works outside the
317. probes can greatly increase the DC and transient analysis simulation times Consequently this method is typically used only for small circuits and AC analysis 4 Important Adding probes to circuits that are sensitive to numerical noise might affect the solution In such cases an accurate solution might be obtained by reducing reltol Saving Subcircuit Terminal Currents You use the subcktprobelvl parameter to control the calculation of terminal currents for subcircuits Current probes are added to the terminals of each subcircuit up to subcktprobelvl deep You can then save these terminal currents by setting the save parameter The nest 1v1 parameter controls how many levels are returned Saving All AHDL Variables If you want to save all the ahdl variables belonging to all the ahdl instances in the design set the saveahdlvars option to all using a Spectre options command For example Saveahdl options saveahdlvars all Listing Parameter Values as Output You can generate lists of component parameter values with the info statement With this statement you can access the values of input output and operating point parameters These parameter types are defined as follows B Input parameters Input parameters are those you specify in the netlist such as the given length of a MOSFET or the saturation current of a bipolar resistor W Output parameters January 2004 232 Product Version 5 0 Spectre Circuit Simulator User Guide Sp
318. protect begin_protected protect data_method RES protect data_keyowner Cadenc protect data_keyname CDS_KEY protect data_block jwrADFASDfdhfjadfahd jau77r42jagadfhjkuer a protect end protected Product Version 5 0 Spectre Circuit Simulator User Guide Encryption Encrypting an Include File If there is an include file in the encrypted portion of your netlist you must encrypt it separately Encrypted Information During Simulation When you simulate an encrypted netlist all warnings error messages and info statements about the encrypted portions of your netlist are suppressed The following sections describe how the Spectre circuit simulator handles the encrypted portions of your netlist Protected Device A device is encrypted if any of the following conditions are met B Itis a primitive and inside a protected block W ltisaninstance of a subcircuit The instance is not in a protected block but the subcircuit is protected Here is an example X1 in out INV subckt INV in out protect mpl vdd in vdd pmos W 1 0e 6 L 1 0e 6 mnl out in 0 0 nmos W 1 0e 6 L 1 0e 6 unprotect ends INV In the flattened netlist devices X1 mp1 and X1 mn1 are protected W Itis an instance of a subcircuit and the instance is in a protected block Whether the subcircuit is protected or not all the flattened primitive devices from that hierarchical level are protected An example is given below prote
319. r User Guide Preface This manual assumes that you are familiar with the development design and simulation of integrated circuits and that you have some familiarity with SPICE simulation It contains information about the Spectre circuit simulator Spectre is an advanced circuit simulator that simulates analog and digital circuits at the differential equation level The simulator uses improved algorithms that offer increased simulation speed and greatly improved convergence characteristics over SPICE Besides the basic capabilities the Spectre circuit simulator provides significant additional capabilities over SPICE SpectreHDL Spectre High Level Description Language and Verilog A use functional description text files modules to model the behavior of electrical circuits and other systems SpectreRF adds several new analyses that support the efficient calculation of the operating point transfer function noise and distortion of common RF and communication circuits such as mixers oscillators sample holds and switched capacitor filters This Preface discusses the following topics m Related Documents on page 13 m Typographic and Syntax Conventions on page 14 m References on page 15 Related Documents The following can give you more information about the Spectre circuit simulator and related products B The Spectre circuit simulator is often run within the analog circuit design environment under the Cadence design
320. r diode model at bv Telling Spectre to Perform Additional Checks of Parameter Values You can perform a check analysis at any point in a simulation to be sure that the values of component parameters are reasonable You can perform checks on input output or operating point parameters The Spectre simulator checks parameter values against parameter soft limits To use the check analysis you must also enter the param command line argument with the spect re command to specify a file that contains the soft limits The following example illustrates the syntax of the check statement It tells the Spectre simulator to check the parameter values for instance statements ParamChk check what inst B ParamChk is your unique name for this check statement m The keyword check is the component keyword for the statement B The what parameter tells the Spectre simulator which parameters to check The what parameter of the check statement gives you the following options Option Action none Disables parameter checking models Checks input parameters for all models only January 2004 290 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Option Action inst Checks input parameters for all instances only input Checks input parameters for all models and all instances output Checks output parameters for all models and all instances all Checks input and output parameters for all models an
321. r subcircuit calls you use a save statement or specify the subcktprobelvl parameter in an options statement The currents all option of the options statement saves currents only for devices Saving Subcircuit Signals To save a subcircuit gt Give a full path to the subcircuit name Start with the highest level subcircuit and identify the signals you want to save at the end of the path Separate each name with a period Examples of the save Statement The following table shows you examples of save statement syntax When you specify node names the Spectre simulator saves node voltages Currents are identified by the terminal node name or the index number Exception Currents through probes take the name of the probe save Statement Action save 7 Saves voltage for a node named 7 save Q4 currents Saves all terminal currents associated with component Q4 save Q4 static Saves resistive terminal currents associated with component Q4 save D8 cap Saves the junction capacitance for component D8 Assumes D8 is a diode and therefore cap is an operating point parameter January 2004 213 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements save Statement Action Save Save Save Save Save Save Q5 Qs Qs M2 Q3 FA D9 0ppoint 1 d displacement currents Ml all S1 BJT3 0ppoint Saves all signal information for component Q5 and the oper
322. rVsTemp xf start 0 stop 50 step 1 probe Rload param temp freq 1k Gain pleasel alter dev Vfb param mag value 1 annotate no OpenLoop ac 9 OpenLoop ac start 1 stop 10M dec 10 nestlvl 0 please2 alter dev Vfb param mag value 0 annotate no f f XF XferVsFreq x XferVsFreq xf start 1 stop 10M dec 10 probe Rload Transient StepResponse op StepResponse tran MEER StepResponse tran stop 250u oppoint fiMe please3 alter dev Vin param type value sin SineResponse tran stop 150u errpreset moderate method trap SineResponse tran Results File Description logFile Log file identifies output file format OpPoint op Nonlinear device DC operating point file OpPoint dc Node voltages at the operating point Drift dc DC sweep XferVsTemp xf Transfer function versus temperature OpenLoop ac AC analysis XferVsFreq xf Transfer function versus frequency StepResponse tran Transient analysis StepResponse op Operating point information for transient analysis SineResponse tran Transient analysis January 2004 237 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options Filenames for SPICE Input Files If you specify analyses with standard SPICE syntax the name of the output file for the first instance of each type of analysis is the same as the name shown in the following table SPICE Analysis Output Filename OP opBegin dc AC frequencySweep ac DC srcSweep dc T
323. radation in the Spectre simulator You must properly characterize and extract the degradation parameters dvthc dvthe duoc and duoe These are usually obtained from DC stress measurements Because device degradations are power functions of the substrate current if you do not accurately determine the degradation parameters the predicted device lifetimes and degradations might lead to false conclusions Hot Electron Degradation Circuit Spectre degradation model subckt inv 1 2 3 cl 3 0 0 1p ml 3 2 1 1 pmen 1 1 5u w 30u ad 120p as 75p pd 36u ps 6u m2 3 2 0 0 nmen 1 1 5u w 15u ad 60p as 37 5p pd 23u ps 6u ends x1 21 2 3 inv x2 13 4 inv x3 145 inv x4 15 6 inv x5 1 6 7 inv x6 17 8 inv x7 18 9 inv x8 19 10 inv x9 X0 El an x10 1 11 12 inv xli k LZ 2 rnv vddl 1 0 vsource dc 5 0 vdd 21 0 pulse 0 5 0 0 0 1m 1n 500n tran 0 1n 10n circuitage 0 0 tran 0 1n 10n circuitage 4 0 model nmen nmos level 3 vto 0 6876 gamma 0 5512 kappa 5 0 kp 0 8675e 4 tox 0 206e 7 nsub 0 197e17 vmax 4e5 theta 0 2 cbs 10f cbd 10f degramod spectre degradation yes strc 1 5e 6 sube 1 duoc 0 9 duoe 0 9 wnom 15u lnom 2u model pmen pmos level 3 vto 0 6893 gamma 0 4411 kappa 5 0 ld 0 45e 6 kp 0 3269e 4 tox 0 206e 7 nsub 0 197e17 vmax 4e5 theta 0 2 cbs 10f cbd 10f degramod spectre degradation yes strc 3 0e 6 sube 1 duoc 0 9 duoe 0 9 wnom 30u lnom 2u save xl ml isub xl ml stress xl ml age
324. rameters for devices models circuit and subcircuit parameters during a simulation with the alter statement The modifications apply to all analyses that follow the alter statement in your netlist until you request another parameter modification Changing Parameter Values for Components To change a parameter value for a component device or model you specify the device or model name the parameter name and the new parameter value in the alter statement You can modify only one parameter with each alter statement but you can put any number of alter statements in a netlist The following example demonstrates alter statement syntax SetMag alter dev Vtl param mag value 1 B SetMag is the unique netlist name for this alter statement Like many Spectre statements each alter statement must have a unique name B The keyword alter is the primitive name for the alter statement B dev vVt1 identifies vc 1 as the netlist name for the component statement you want to modify You identify an instance statement with dev and a mode1 statement with mod When you use the alter statement to modify a circuit parameter you leave both dev and mod unspecified B param mag identifies mag as the parameter you are modifying If you omit this parameter the Spectre simulator uses the first parameter listed for each component in the Spectre online help as the default B value 1 identifies 1 as the new value for the mag parameter If you leave value unspecifi
325. re cedo ie ER Dare oed P Pr qe Par edad dca osi oth dream 34 Starting Wave SCAN iouis e Oeste T aput ee pp ele hte LR ES e SUA TR afe ntes A 34 January 2004 3 Product Version 5 0 Spectre Circuit Simulator User Guide PIOWING SIQMAlS s ors woe dert pri rq ys tg elas cea Ree RR Sele re 35 CHANGING the Trace Color oou veut a rane eee edP ed Bel i tcr ara ae ane EYE CE a 37 Learning More about WaveScan lees 38 3 SPICE Compatibil eor xe ER Ie b ERE eta 41 Reading SPICE Netlists dio hb kien dentur eu PS GPO Se AY Asia cB a RET ada d ole dde 42 Running the SPICE Reader a cuo Re eek ER NEA A7 AR ae eos he VIE gen 42 Running the SPICE Reader from Cadence Analog Design Environment 43 Running the SPICE Reader from the Command Line 43 Using the SPICE Reader to Convert Netlists llle 44 Language Differences uLsuoiuesestiii do P Ecol eher e decode Rd de ET edente 48 Comparing the SPICE and Spectre Languages 0 0c cece eens 48 Reading SPICE and Spectre Files 0 0 cece eee 50 Scope of the Compatibility 7 59 22 2 4 5 0 Soden d ee Ew ew ee 51 SOURCES sepsis asta aE a e p EC REOR REOR EAST Dic tbe th elevates Geb b EA CRF TRUE eei ER ase 51 Compatibility GuidGlnies 59 eate CE ERR EE e nr ERS ERE VES 51 General Input Compatibility ru v eere ERI euros etre igo xx gee paga 51 Compatibility Limita
326. representing the resistance value in SPICE The SPICE Reader maps this to a parameter if a param statement is encountered with this assignment or to a model name if a model card with the name myres is found If neither is present the field is assumed to be a model name In the case of the convert mode where these assignments could be part of included January 2004 45 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility files this assumption could be incorrect and the instance statement would need to be fixed m Global nodes In Spectre global nodes must be at the very beginning of the netlist while they can be present anywhere in a SPICE netlist If a converted file contains global nodes these must be moved to the top level of the netlist before the file can be included in a higher level netlist Multiple global statements cause fatal errors in Spectre m Location of measurement data The SPICE Reader converts Hspice style measure statements to Measurement Description Language MDL statements The SPICE Reader does this by creating an MDL control file which can then be used in the simulation In normal operation using the spectrespp netlist command the control file that is created takes on the name of the netlist with the suffix md1 When a netlist is converted with the convert option the MDL control file that is created is always named Net list mdl If this control file is used in a subsequ
327. resistor whose resistance is r force Spectre then removes these voltage sources and resistors and computes the true solution from this initial guess Nodesets have two important uses First if a circuit has two or more solutions nodesets can bias the simulator towards computing the desired one Second they are a convergence aid By estimating the solution of the largest possible number of nodes you might be able to eliminate a convergence problem or dramatically speed convergence When you simulate the same circuit many times we suggest that you use both the write and readns parameters and give the same filename to both parameters The DC analysis then converges quickly even if the circuit has changed somewhat since the last simulation and the nodeset file is automatically updated You may specify values to force for the DC analysis by setting the parameter force The values used to force signals are specified by using the force file the ic statement or the ic parameter on the capacitors and inductors The force parameter controls the interaction of various methods of setting the force values The effects of individual settings are force none Any initial condition specifiers are ignored force node The ic statements are used and the ic parameter on the capacitors and inductors are ignored force dev The ic parameters on the capacitors and inductors are used and the ic statements are ignored force all Both the i c statements and the
328. rited local 4 2 5 4 4 ends time sweep tran start 0 stop pl p2 50e 6 use 5 50e 6 150 us dc sweep dc param pl values 0 5 1 p2 sqrt p2 p2 sweep pl Parameter Declaration Parameters can be declared anywhere in the top level circuit description or on the first line of a subcircuit definition Parameters must be declared before they are used referenced Multiple parameters can be declared on a single line When parameters are declared in the top level their values are also specified When parameters are declared within subcircuits their default values are specified The value or default value for a parameter can be a constant expression a reference to a previously defined parameter or any combination of these You can declare parameters between subcircuit definitions if the subcircuits do not refer to parameters in the parent scope defined after the subcircuit definition If you want to use altergroups you must declare all parameters before the subcircuit definitions Parameter Inheritance Subcircuit definitions inherit parameters from their parent enclosing subcircuit definition or top level definition This inheritance continues across all levels of nesting of subcircuit January 2004 85 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features definitions that is if a subcircuit s1 is defined which itself contains a nested subcircuit definition s2 th
329. rmation see Spectre Circuit Simulator Known Problems and Solutions Melting Current Warnings A separate model parameter imelt is used as a limit warning for the junction current This parameter can be set to the maximum current rating of the device When any component of the junction current exceeds imelt Spectre issues a warning and the results become inaccurate The junction current is linearized above the value of imelt to prevent arithmetic exception with the exponential term replaced by a linear equation at imelt Breakdown Region Warnings Messages like the following are breakdown region warnings D2 Breakdown voltage exceeded Q1 The collector substrate voltag xceeded breakdown voltage The warning message identifies the relevant component name D2 and Q1 and the affected junction The Spectre simulator issues breakdown region warnings only when you specify conditions for them For information on setting parameters to identify a breakdown region see Customizing Error and Warning Messages on page 284 Missing Diode Would Be Forward Biased Warning from spectre at time 501 778 ns during transient analysis tran to lu il q0 Missing collector substrate diode would be forward biased Notice from spectre at time 510 1688 ns during transient analysis tran to lu January 2004 279 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting il q0 Missing collec
330. rotect Systems pragma protect pragma protect pragma protect rl mid out 2k pragma protect begin protected data method RC5 data keyowner Cadence Design data keyname CDS KEY data block QERWfdjau77r42jagadfhjkuer end protected begin protected etu45j6jgfly5po765t8tnji5j5i76k pragma protect end protected ends inv If you have multiple subcircuits in your netlist you can encrypt them by using multiple pairs of protect and unprotect as shown in the example above Encrypting a Model Card You can encrypt one or more model cards with a pair of protect and unprotect keywords The keywords do not have to be within or outside the model card Even if you encrypt only a portion of the model card the entire model card is protected during simulation In case there are no parameters within a protected block the Spectre circuit simulator displays a warning message but still encrypts the model card Example 1 January 2004 252 Product Version 5 0 Spectre Circuit Simulator User Guide Encryption In the following example the encryption keywords are around the model card definition The model name and all parameters are encrypted Original Netlist The 1st model name is pmos type is p The 2nd model name is nmos type is n subckt inv out in paramemters wi lu le 3u mpl mid in vd vd pmos w wi l le mnl mid in 0 0 nmos w wi l le ends inv protect model pmos bsim3v3
331. run the analysis you get different results that is a different stream of pseudorandom numbers is generated If you do not specify a seed the Spectre simulator uses the Spectre process id PID as a seed January 2004 166 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Parameter Description scalarfile This parameter specifies the name of an ASCII file where scalar data calculated by the export state ments the results of export expressions that resolve to scalar values is saved For each iteration of each Monte Carlo child analysis Spectre writes a line to this ASCII file with one scalar expression per column for example slew rate or bandwidth The default name for this file is name mcdata where name is the name of the Monte Carlo analysis instance The file is created in the psf directory by default unless you specify a path in the filename This file contains only the matrix of numeric values The analog design environment Monte Carlo tool can read this ASCII file and plot the data in histograms and scattergrams When you use the analog design environment Monte Carlo tool to generate the Spectre netlist file Spectre merges the values of the statistically varying process parameters into this file containing the scalar data The analog design environment statistical plotting tool can later read the data and create scatter plots of the statistically varying process parameters against each other or against the
332. s every 10 seconds ExStrobe tran skipstart 5 skipstop 20 strobeperiod 10 This example is identical to the previous one except that it sets a delay of 2 seconds between the skipstart time and the first strobe point ExStrobe2 tran skipstart 5 skipstop 20 strobeperiod 10 strobedelay 2 Data Compression Some circuits such as mixed analog and digital designs and circuits with switching power supplies have substantial amounts of signal latency If unchanged signal values for these circuits are repetitively written for each time point to a transient analysis output file this output file can become very large You can reduce the size of output files for such transient analyses with the Spectre simulator s data compression feature With data compression the Spectre simulator writes output data for a signal only when the value of that signal changes Using data compression is not always appropriate The Spectre simulator writes fewer signal values when you turn on data compression but it must write more data for every signal value it records For circuits with small amounts of signal latency data compression might actually increase the size of the output file You turn on data compression by adding the parameter compression yes to the transient analysis command line in a Spectre netlist DoTran z12 tran start 0 stop 003 step 0 00015 maxstep 6e 06 compression yes January 2004 147 Product Version 5 0 Spectre Circuit Simulator Us
333. s formatting in analysis statements 67 names rules for components 60 nodes 60 old netlists 62 nestlvl parameter 217 229 netlist conventions 58 definition 28 elements of 29 introduction to 29 Spectre example 28 netlist parameters predefined 93 netlist statements 58 Product Version 5 0 Spectre Circuit Simulator User Guide use of in example 30 newlink keywords 212 224 newlink save statement 211 224 Newton Raphson iteration 267 276 node capacitance table printing 205 nodes as info statement parameter 203 233 definition of 59 naming 60 rules fornames 60 specifying initial conditions with 198 260 nodeset statement 199 261 nodesets 197 259 convergence problems and 297 specifying for individual analyses 200 262 node to terminal map 203 233 noise analysis brief description of 131 none as homotopy parameter option 267 as info statement parameter 203 233 as pwr option 216 228 as Save parameter option 217 229 nonlinear component models and convergence problems 297 notifications responding to 33 nport component and S parameter files 122 nport statement example in netlist 120 N ports example 120 modeling 120 numerical error improved control of 17 numruns parameter Monte Carlo analysis 166 nutascii output format 234 nutbin output format 234 Nutmeg format 234 O online help 20 open loop gain in netlist example of measuring 136 operating regions determin
334. s the Spectre simulator saves node voltages Currents are identified by the terminal node name or the index number Exception Currents through probes take the name of the probe save Statement Action save 7 Saves voltage for a node named 7 save Q4 currents Saves all terminal currents associated with component Q4 save Q4 c static Saves resistive terminal currents associated with component Q4 January 2004 225 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options save Statement Action save D8 cap Saves the junction capacitance for component D8 Assumes D8 is a diode and therefore cap is an operating point parameter save Q5 D9 oppoint Saves all signal information for component Q5 and the operating point parameters for component D9 save Ql c Saves the collector current for component o1 Example assumes Q1 is a BJT and therefore c is a terminal name save Q1 1 Same effect as the previous statement Saves the collector current for component Q1 Identifies the terminal with its terminal index instead of its terminal name save M2 d displacement Saves capacitive current associated with the drain terminal of component M2 Example assumes v2 is a MOSFET so d is a terminal name save Q3 currents Ml all Saves all currents for component Q3 and all signals for component M1 save F4 S1 BUT3 oppoint Saves operating point parameters for terminal BJT3 BJT3 is in su
335. s analAC ql area and analAC nbjtl rb sens vbb p qgl int c ql gm 7 to ql area nbjtl rb for analDCl This command computes DC sensitivities of the branch current vbb p the operating point parameter gm of transistor q1 the internal collector voltage q1 int c and the node 7 voltage to the instance parameter q1 area and the model parameter nb jt 1 rb The values are computed for analysis analDC1 sens 1 n2 7 for analAC This command computes the AC sensitivities of nodes 1 n2 and 7 to all available device and model parameters Note This can result in a lot of information Fourier Analysis The ratiometric Fourier analyzer measures the Fourier coefficients of two different signals at a specified fundamental frequency without loading the circuit The algorithm used is based on the Fourier integral rather than the discrete Fourier transform and therefore is not subject to aliasing Even on broad band signals it computes a small number of Fourier coefficients accurately and efficiently Therefore this Fourier analyzer is suitable on clocked sinusoids generated by sigma delta converters pulse width modulators digital to analog converters sample and holds and switched capacitor filters as well as on the traditional low distortion sinusoids produced by amplifiers or filters The analyzer is active only during a transient analysis For each signal the analyzer prints the magnitude and phase of the harmonics along with the t
336. s file is instname process mcdata Where instname is the name of the Monte Carlo analysis instance This file is created in the psf directory by default unless you specify some path information in the filename You can load processscalarfile and processparamfile into the analog design statistical postprocessing environment to plot verify the process parameter distributions If you later merge processparamfile with the data in scalarfile you can then plot export scalar values against the corresponding process parameters by loading this merged file into the analog design statistical postprocessing environment processparamfile This specifies the output file where process parameter scalar data labels are saved This file contains the titles and sweep variable values for each of the columns in processscalarfile These titles are the names of the process parameters processparamfile is equivalent to paramfile except that paramfile contains the name of the export expressions whereas processparamfile contains the names of the process parameters The default name for this file is instname process mcparam where instname is the name of the Monte Carlo analysis instance This file is created in the psf directory by default unless you specify some path information in the filename January 2004 168 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Parameter Description Saveprocessvec firstrun variations January
337. s the distributions for parameters W Distributions specified in the process block are sampled once per Monte Carlo run are applied at global scope and are used typically to represent batch to batch process variations W Distributions specified in the mismatch block are applied on a per subcircuit instance basis are sampled once per subcircuit instance and are used typically to represent device to device on chip mismatch for devices on the same chip When the same parameter is subject to both process and mismatch variations the sampled process value becomes the mean for the mismatch random number generator for that particular parameter Note Statistics blocks can be specified using combinations of the Spectre keywords statistics process mismatch vary truncate and correlate Braces are used to delimit blocks The following example shows some sample statistics blocks which are discussed after the example along with syntax requirements define some netlist parameters to represent process parameters such as sheet resistance and mismatch factors parameters rshsp 200 rshpi 5k rshpi std 0 4K xisn 1 xisp 1 xxx 20000 uuu 200 define statistical variations to be used with a MonteCarlo analysis statistics process process generate random number once per MC run vary rshsp dist gauss std 12 percent yes vary rshpi dist gauss std rshpi std rshpi std is a parameter January 2004 173 Product Version
338. s voltage probes M Iftheprobe component has more than two terminals you specify which pair of terminals to use as the probe by specifying a port of the probe In the following instance statement port 1 is nodes 5 and 8 and port 2 is nodes 2 and 4 bjtl 5 8 2 4 bmod1 m If the probe component measures more than one branch current you specify which branch current to use as the probe by specifying a port In the following instance statement current port 1 is the branch from node 4 to node 5 and port 2 is the branch from node 8 to node 9 tline2 4 5 8 9 tline m Every component has a default probe type and port number In the following example the netlist contains a resistor named Rocm and a voltage source named Vcm These components are used as probes for the noise analysis statement The parameters oprobe and iprobe specify the probe components and the parameters oportv and iportv specify the port numbers cmNoise noise start 1k stop 1G dec 10 oprobe Rocm oportv 1 iprobe Vcm iportv 1 Multiple Analyses This netlist demonstrates the Spectre simulator s ability to run many analyses in the order you prefer In this example the Spectre simulator completely characterizes an operational amplifier in one run In analysis OpPoint the program computes the DC solution and saves it to a state file whose name is derived from the name of the netlist file On subsequent runs January 2004 135 Product Version 5 0 Spectre Circuit Simulator
339. s when the first error level violation occurs Default value warning When yes the parameter value is printed and the min max and duration parameters are ignored The info parameter is not applicable for expressions Default no The following table displays some ways to use the assert parameters Assert parameters 1 dev device or subckt instance param paramname January 2004 Description Applies to paramname can bean The specified instance Instance parameter Operating point parameter For subcircuit instances paramname canbea subcircuit parameter 191 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements 10 Assert parameters mod model param paramname mod model modelparam paramname primitive primitive param paramname primitive primitive modelparam paramname sub subcircuit_master dev X1 param paramname sub subcircuit master mod model param paramname sub subcircuit_master mod model modelparam paramname sub subcircuit_master primitive primitive param paramname sub subcircuit_master primitive primitive modelparam paramname January 2004 Description paramname can be an Instance parameter Operating point parameter paramname must be a model parameter paramname can be an Instance parameter Operating point parameter paramname must be a model parameter 192 Applies to All instances of the specified model
340. same node x Use the captab analysis to display the capacitance between the nodes in your circuit This is an option in the info statement Here is an example of the info settings you would set to perform a captab analysis Parameter Setting Action Taken what captab Performs captab analysis The default value is oppoint where logfile Prints the parameters to a logfile Other possible values are nowhere screen and file The value rawfileis not supported for node capacitance title captab Prints captab as the title of the analysis in the output file threshold 0 Specifies the threshold capacitance value The nodes for which the total node capacitance is below the threshold value will not be printed in the output table detail node Displays the total node capacitances Other possible values are nodetoground and nodetonode sort value Sorts the captab output according to value The other possible value is name January 2004 205 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements For a complete list of captab parameters and values consult the Spectre online help spectre h Use the infotimes option of the transient analysis when you bind the capt ab analysis to a transient analysis This runs the capt ab analysis at specified time intervals The syntax for the infotimes option is infotimes xl x2 where x1 and x2 are time points for which the info analysis should be performed The
341. sarate te tu heise dud ed oa tre ates i 135 Multiple ArialyS8S 13 244 terpe ci ir is eee ete eke ieee ek Eee ee 135 Multiple Analyses in a Subcircuit lille 138 January 2004 6 Product Version 5 0 Spectre Circuit Simulator User Guide EXaMple 42452 x ERG anie FO CHR de Sed wh cea denn Le SOR o EN 138 BIOS EI EID RET Tc 139 AE PVA SIS earn ipee mop delet a add WM Tod aparte Eon whos Uu uci dea ap AN RR ACRE Ey Pa 140 Transient AD SIS 4 whee seh wale ee re be pea Be Gece at LS ho erate ent Ede 141 Trading Off Speed and Accuracy with a Single Parameter Setting 142 Controlling the Accuracy 4 a5 Moss bees P ae Pokus wade Ao CaP ped meade 143 Setting the Integration Method 0 0 cee 144 Improving Transient Analysis Convergence 0 cc cece eee 145 Controlling the Amount of Output Data ee 145 Pole Zero AMMA SIS cxtra ch ee Dao SE Rod Ur Decl Wee e te Ha a aad eub ase Evi bh eee 148 Syntax sgire eeii eie eed eh etd te poro cub he PAD enu Dti Manns Rat sa eie nein ead 149 Examples 25 du echt Se an ARE nda oe LS DUE eee Se 149 Example2 aug aicut seta open i pu 3314 V RD ee eee SEU ur d acie Ea e RE was ous 149 Examples duse nob sacer e d Rt Y RE gh don d bauen E A oir Gee ek nS 149 Outp t EL Og Eller udo psv ar ws one tino ee Ree ui deua Ree ees 150 Other Analyses sens fourier dcmatch and stb eee eae 150 Sensitivity Analy
342. scillator Spectre Deck for Two Input NAND Ring with No Fanouts nand2 ring sp on page 304 Ring Oscillator Spectre Deck for Three Input NAND Ring with No Fanouts nand3_ring sp on page 305 Ring Oscillator Spectre Deck for Two Input NOR Ring with No Fanouts nor2 ring sp on page 307 Ring Oscillator Spectre Deck for Three Input NOR Ring with No Fanouts nor3 ring sp on page 308 Opamp Circuit opamp cir on page 310 Opamp Circuit 2 opamp1 cir on page 310 Original Open Loop Opamp openloop sp on page 310 Modified Open Loop Opamp openloop1 sp on page 311 Example Model Directory q35d4h5 modsp on page 31 1 January 2004 300 Product Version 5 0 Spectre Circuit Simulator User Guide Example Circuits Notes on the BSIM3v3 Model The Spectre circuit simulator supports the standard BSIM 3v3 MOS model both BSIM 3v3 1 and BSIM 3v3 2 as published by the University of California at Berkeley Further information about this model can be obtained by using Spectre s online help by typing spectre h bsim3v3 at the command line or by consulting the BSIM3 home page at www device eecs berkeley edu bsim3 index html Spectre does not add proprietary parameters to its implementation of the standard model Spectre Syntax Notes explaining Spectre syntax are included as comments throughout the example netlists The Spectre circuit simulator reads Spice2G6 input along with its own native format The model card c
343. sens command as follows sens output_variables_list to design parameters list for analyses list where output variables list ovar ovars design parameters list dpar dparp analyses list ana anap January 2004 151 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses The ovar are the output variables whose sensitivities are calculated These are normally node names deviceInstance parameter Of modelName parameter specifications Examples are 5 n1 and Qout betadc The dpar are the design parameters to which the output variables are sensitive You can specify them in a format similar to ova r However they must be input parameters that you can specify for example R1 x If you do not specify a to clause sensitivities of output variables are calculated with respect to all available instance and model parameters Note The method for specifying design parameters and output variables is described in more detail in the documentation for the save statement in Chapter 8 Specifying Output Options The following table shows you the types of design and output parameters that are normally used for both AC and DC analyses AC Analysis DC Analysis Design Instance parameters Instance parameters paraineisis Model parameters Model parameters Output Node voltages Node voltages paramerets Branch currents Branch currents Instance operating point parameters You ca
344. side of inline subcircuits 103 inline subcircuits containing inline model statements 103 modeling parasitics 100 parameterized models 102 probing 101 process modeling using 99 input data reading from multiple files 72 input files examples differential amplifier 112 GaAs traveling wave amplifier 95 process file 115 two port test circuit 120 uA741 operational amplifier 135 input language mixing SPICE and Spectre 54 input parameters listing 202 232 input as info statement parameter 233 inst as info statement parameter 203 233 instance correlation statement 177 instance scaling factor changing with alter statement 189 266 instance statements 62 annotated example 30 control statements 31 examples 64 formatting 62 model statements 31 parameter values 31 rules for using 64 use of in example 30 INT signal 242 interrupting a simulation 242 introductory netlist how to use 26 invalid parameter values 275 iprobes and convergence problems 296 italics in syntax 14 K keywords 14 for save statement Spectre 60 kill command UNIX 104 208 January 2004 kill 9 warning about use of 242 kill 1 as interrupt method 242 USH1 option example 241 USR2 option example 243 Kirchhoff s Current Law KCL 18 59 144 Kirchhoff s Flow Law KFL 18 9 144 L lang spectre command 84 lang spice command 84 language title line 51 language modes 59 library definition 75 library reference
345. simulator s Fourier analyzer has greater resolution for measuring small distortion products on a large sinusoidal signal Resolution is normally greater than 120 dB Furthermore the Spectre simulator s Fourier analyzer is not subject to aliasing a common error in Fourier analysis As a result the Spectre simulator can accurately compute the Fourier coefficients of highly discontinuous waveforms BW Better control of numerical error January 2004 17 Product Version 5 0 Spectre Circuit Simulator User Guide Introducing the Spectre Circuit Simulator Many algorithms in the Spectre circuit simulator are superior to their SPICE counterparts in avoiding known sources of numerical error The Spectre circuit simulator improves the control of local truncation error in the transient analysis by controlling error in the voltage rather than the charge In addition the Spectre circuit simulator directly checks Kirchhoff s Current Law also known as Kirchhoff s Flow Law at each time step improves the charge conservation accuracy of the Spectre circuit simulator and eliminates the possibility of false convergence Superior time step control algorithm The Spectre circuit simulator provides an adaptive time step control algorithm that reliably follows rapid changes in the solution waveforms It does so without limiting assumptions about the type of circuit or the magnitude of the signals More accurate simulation techniques Techniques that
346. sis croire domi ch o eMe e e hd obe E bar bfc SO eer 151 BOURGEAMALYSIS erect hama iuo are DO caen tua aA D aei i tad la a 153 DC Match Analysis gt ons a e Dis 5 ache Sudden Loo 98 MRS Scaled nce we ae Olek 154 Stability Analysis 5 eura iE ire E on ES R OS ceed pce ae Ye red Sea Era eee 157 Advanced Analyses sweep and montecarlo 2 0 cece eee 159 SWesDAHalySIS sr kao a wai and ceca de Ue RR Eu Vt ae eed ee wee ens 159 Morte Garlo AnalySiS umido iouis dei cae cheat ue cre Dua Ra tua Dd dcs heh eds 164 Special Analysis Hot Electron Degradation 0 0 0 cee eee 178 Hot Electron Degradation Analysis 00 cece eee 179 Output Options for Hot Electron Degradation Analysis 180 Example of Hot Electron Degradation ee 181 T4 Control Statements reaa e a esee 186 The alter and altergroup Statements 0 0 0 0 ccc eee eee 187 Changing Parameter Values for Components 00 cee eee eee 187 Changing Parameter Values for Models 0 00 cece eee ees 188 Further Examples of Changing Component Parameter Values 188 Changing Parameter Values for Circuits 0 0 02 ee eee 189 January 2004 7 Product Version 5 0 Spectre Circuit Simulator User Guide Theassert Statement xuuaxadanieitaiee yr ooo ee Ris ta d vwd amie Ae NE ee es 189 Example see ala eosfana poena EI a de PA ne
347. sistor r 775 resistor r 465 capacitor c 21p resistor r 50 resistor r 500 capacitor c 12p port r 50 num 1 mag 0 capacitor c 1n stage capacitor c 1n stage capacitor c 1n port r 50 num 2 Sparams sp start 100M stop 100G dec 100 Rules to Remember When you use subcircuits z0 96 z0 96 z0 96 z0 96 z0 96 z0 96 z0 96 z0 96 vel 1 0 36 vel vel vel vel 1 0 36 vel 0 36 0 36 0 36 0 36 0 36 0 36 B You must place the same number of nodes in the same order in subcircuit definitions and their respective subcircuit calls m Models and subcircuits defined within a subcircuit definition are accessible only from within that subcircuit You cannot use the model names in a subcircuit definition in statements from outside the subcircuit You can however use both the model name and the subcircuit definitions in new subcircuits within the original subcircuit Local models or subcircuits hide nodes or subcircuits with the same names defined outside the subcircuit January 2004 96 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features m When you use model statements within subcircuit definitions where model parameters are expressions of subcircuit parameters definitions a new model is created for every instance of the subcircuit These different models are expanded models which are derived from the original model statement Each of the new models
348. specifying an sp analysis see Chapter 6 Analyses and the parameter listings for the sp analysis in the Spectre online help spectre h sp Creating an S Y or Z Parameter File Manually To create an S Y or Z parameter file manually in a text editor observe the following guidelines and rules B The Spectre simulator accepts the following formats for S Y or Z parameters real imag mag deg mag rad db deg and db rad The formats do not have to be the same for each parameter For clarity use a comma to separate the two parts of an S Y or Z parameter Begin each file with a semicolon Semicolons indicate comment lines Use spaces commas and newlines as delimiters You can enter the parameters in any order You can specify any number of frequency points The frequency points do not have to be equally spaced but the frequency index must be in ascending or descending order m You must place the frequency specification before the S parameters and you must separate the frequency specification from the S parameters with a colon January 2004 121 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features m There is no limit to the number of ports If either port number is greater than nine place a colon between the two port numbers when you specify the S Y or Z parameter format 519215 Note The S Y or Z parameters can be given in any order and in any supported
349. ss n 1 0 35u w 2 40u ad 1 75p pd 6 26u as 0 25p ps 2 61u m5 7 vdd 8 vss n 1 0 35u w 2 40u ad 0 25p pd 2 61u as 0 25p ps 2 61u m6 nq vdd 8 vss n 1 0 35u w 2 40u ad 1 75p pd 6 26u as 0 25p ps 2 61u cO 8 vdd capacitor c 1 341e 17 el vdd vss capacitor c 9 9445302e 16 nq vdd capacitor c 2 0719818e 15 a vss capacitor c 5 3760487e 16 vdd capacitor c 1 2446956e 15 nq capacitor c 7 308e 17 vdd capacitor c 2 0115e 17 Io c2 nq vss capacitor c 6 287e 16 S Begin top level circuit definition xna3pll 1 90 na3pl xna3p12 21 na3pl xna3p13 32 na3pl xna3pl4 4 3 na3pl xna3p15 5 4 na3pl xna3pl6 6 5 na3pl xna3pl17 7 6 na3pl xna3p18 8 7 na3pl xna3p19 9 8 na3pl xna3p110 10 9 na3pl xna3p111 11 10 na3pl xna3p112 12 11 na3p1 xna3p113 13 12 na3pl xna3p114 14 13 na3p1 xna3p115 15 14 na3pl xna3p116 16 15 na3pl xna3pl17 90 16 na3p1 Next couple of lines sets variables for vdd and vss parameters vdd S1 23 3 parameters vss S1 20 0 vdd Il vdd gnd vsource dc vdd S1 vss Il vss gnd vsource dc vss S1 Next line initializes nodes within ring ic 220 420 6 20 8 20 1020 include q35d4h5 modsp section tt Transient analysis card tempOption options temp 25 typ tran tran step 0 010n stop 35n alter ss altergroup include q35d4h5 modsp section ss parameters vdd S1 23 0 January 2004 306 Product V
350. ssages error Does not print error messages warning Prints warning messages warning Does not print warning messages info Prints informational messages info Does not print informational messages As a default the Spectre simulator prints all these messages Correcting Convergence Problems In this section you will learn about procedures that can help you if a simulation does not converge Correcting DC Convergence Problems If you have DC convergence problems these suggestions might help you Simple solutions generally precede more radical or complex measures in the list m Evaluate and resolve any warning or error messages W Check for circuit connection errors Check to see that the polarity and value are correct for independent sources Check to see if the polarity and multiplier are correct for controlled sources M Try all of the homotopy methods gmin source ptran and dpt ran These are tried by default B Check for an incorrect estimated operating region The default estimated operating region in the Spectre simulator is on in the forward region for all devices If there are a January 2004 295 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting reasonable number of devices that are really off set them off in the schematic For a large number of devices this might not be practical Check for extremely high gain circuits with nonlinearities and feedback Th
351. ssion in the Spectre netlist rl 1 0 resistor r myfunc 2 0 4 5 Predefined Netlist Parameters There are two predefined netlist parameters B temp is the circuit temperature in degrees Celsius and can be used in expressions BH tnomis the measurement nominal temperature in degrees Celsius and can be used in expressions For example rl 1 0 res r temp tnom 15 10k ol options TEMP 55 Note If you change temp or t nom using a set statement alter statement or simulator options card all expressions with temp or tnom are reevaluated Hence you can use the temp parameter for temperature dependent modeling this does not include self heating however Subcircuits The Spectre simulator helps you simplify netlists by letting you define subcircuits that you can place any number of times in the circuit You can nest subcircuits and a subcircuit definition can contain both instances and definitions of other subcircuits The main applications of subcircuits are to describe the circuit hierarchy and to perform parameterized modeling In this section you learn to define subcircuits and to call them into the main circuit January 2004 93 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Formatting Subcircuit Definitions You format subcircuit definitions as follows subckt SubcircuitName nodel nodeN parameters namel valuel nameN valueN
352. st 115 parameterized models using inline subcircuits 102 parameters 84 circuit 84 85 Monte Carlo analysis table of 166 predefined netlist 93 subcircuit 84 85 parameters statement 84 paramfile parameter Monte Carlo analysis 167 paramset 162 paramset statement 210 paramset statement using 162 210 paramtest statement checking subcircuit parameter values with 98 checking values of subcircuit parameters 292 errorif option 293 example 293 example of use in netlist 115 formatting 292 message option 293 printif option 293 severity option 293 warnif option 293 parasitic elements in parallel with device terminals 102 in series with device terminals 102 parasitics modeling in inline subcircuits 100 parentheses in Spectre syntax 59 pdisto analysis brief description of 22 132 percent codes 244 customizing 271 example 271 formatting 271 Product Version 5 0 Spectre Circuit Simulator User Guide removing customized settings 271 predefined 269 9696 27 A 270 C 270 D 270 H 270 M 270 P 270 S 271 substitution in 271 T 271 V 271 redirected files 272 use with piped files 272 percent parameter Monte Carlo analysis 174 176 periodic AC analysis pac brief description of 132 periodic distortion analysis pdisto brief description of 132 periodic noise analysis pnoise brief description of 132 periodic small signal analyses description 22 periodic steady state an
353. st have had distributions specified for it in a mismatch block or by specifying no parameter list in which case all parameters with mismatch statistics specified are correlated with the given correlation coefficient The correlation coefficients are specified in the va 1 ue gt field and must be between 1 0 not including 1 0 or 1 0 Note Correlation coefficients can be constants or expressions aS can std and N when specifying distributions Characterization and Modeling The following statistics blocks can be used with the example in Process Modeling Using Inline Subcircuits on page 104 if they are included in the main netlist anywhere below the main parameters statement These statistics blocks are meant to be used in conjunction with the modeling and characterization equations in the inline subcircuit example for a Monte Carlo analysis only statistics process vary RSHSP dist gauss std 5 vary RSHPI dist lnorm std 0 15 vary SPDW dist gauss std 0 25 vary SNDW dist gauss std 0 25 correlate param RSHSP RSHPI cc 0 6 mismatch vary XISN dist gauss std 1 vary XBFN dist gauss std 1 vary XRSP dist gauss std 1 statistics correlate dev R1 R2 cc 0 75 correlate dev TNSA1 TNSA2 cc 0 75 Special Analysis Hot Electron Degradation The Spectre simulator lets you control the age of the circuit when simulating hot electron degradation This feature has the following options and restrictions m Only the tra
354. statement can refer to only one model statement B Occasionally a component allows a parameter to be specified as either an instance parameter or as a model parameter If you specify it as a model parameter it acts as a default for instances If you specify it as an instance parameter it overrides the model parameter m Values for model parameters can be expressions of netlist parameters Input Data from Multiple Files If you want to use data from multiple files you use the include statement to insert new files When the Spectre simulator reads the include statement in the netlist it finds the new file reads it and then resumes reading the netlist file If you have older netlist files you want to incorporate into your new larger netlist the include statement is particularly helpful Instead of creating a completely new netlist you can use the include statement to insert your old files into the netlist at the location you want Note The Spectre simulator always assumes that the file being included is in SPICE language mode unless the extension of the filename is scs Formatting the include Statement You can use any of two formatting options for the include statement When you want to use C preprocessor CPP macro processing capabilities within your inserted file use the second format 4 include These are the two format options include filename include filename The first option include is performed
355. sting manually with a text editor such as vi The S Y or Z parameter data file describes the characteristics of a linear N port over a list of frequencies The format of the data file used by the Spectre simulator is flexible and self documenting The Spectre simulator native format describes N ports with an arbitrary number of ports specifies the reference resistance of each port mentions the frequency with no hidden scale factors and allows the S parameters to be given in several formats The Spectre circuit simulator can also read the Touchstone and CITIfile format N Port Example This example demonstrates the use of the nport statement Two port test circuit global gnd simulator lang spectre Models January 2004 120 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features model sp_data nport file Spara data Components Portl il gnd port num 1 TL1 il gnd ol gnd tline z0 25 f 1M Port2 ol gnd port num 2 Port3 i2 gnd port r 50 num 3 X1 02 gnd o2 gnd sp_data Port4 02 gnd port r 50 num 4 Analyses Op Point dc Sparams sp stop 0 3MHz lin 100 ports Portl Port3 Creating an S Parameter File Automatically To create an S parameter file automatically run an sp analysis that sweeps frequency and set the output file parameter to file filename The parameter filename is the name you select for the S parameter file For more information about
356. subcircuit or an AHDL component Parameter Values Real numbers can be specified using scientific notation or common engineering scale factors For example you can specify a 1 pF capacitor value either as c 1pf or c 1e 12 Depending on whether you are using the Spectre Netlist Language or SPICE you might need to use different scale factors for parameter values Only ANSI standard scale factors are used in Spectre netlists For more information about scale factors see Instance Statements on page 62 Control Statements The next section of the sample netlist contains a control statement which sets initial conditions Model Statements Some components allow you to specify parameters common to many instances using the model statement The only parameters you need to specify in the instance statement are those that are generally unique for a given instance of a component You need to provide the following for a model statement B The keyword model at the beginning of the statement m A unique name for the model reference by master names in instance statements m The master name of the model identifies the type of model a The parameter values associated with the model January 2004 31 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre The following example is a model statement for a bjt The model name is npn and the component type name is b jt The backslash tells you that the stateme
357. t January 2004 271 Product Version 5 0 Spectre Circuit Simulator User Guide Managing Files variable you might want to undefine them for a given simulation run To do this you include the x command line option in the spect re command that starts the simulation Undefined percent codes return to predefined values If an undefined percent code has no predefined value it is treated like an empty string Enabling the Spectre Simulator to Recognize the Input Names of Piped or Redirected Files One practical application for customized percent codes is to enable the Spectre simulator to recognize the input filenames of piped or redirected files If the Spectre simulator reads the circuit from standard input as it does when it reads from a pipe the Spectre simulator cannot determine the name of the original input file If you want the results filename to be a variant of the input filename you can enable the Spectre simulator to recognize the input filename by redefining the Spectre simulator s predefined percent codes In the following two examples the circuit file is passed through sed 1 The resulting file ckt file is then piped to the Spectre simulator as input The first example shows the problem created if you want the results filename to be a modification of the input filename and the second example shows how you can correct this difficulty In the first example the Spectre simulator cannot identify the name ckt
358. t Formatting the set Statement The following example demonstrates the set statement syntax This example turns off several annotation parameters Quiet set narrate no error no info no B Quiet is the unique name you give to the set statement B The keyword set is the primitive name for the set statement E narrate error and info are the parameters you are changing Note If you want to change t emp or t nom use the alter statement Saving Time by Selecting a Continuation Method The Spectre simulator normally starts with an initial estimate and then tries to find the solution for a circuit using the Newton Raphson method If this attempt fails the Spectre simulator automatically tries several continuation methods to find a solution and tells you which method was successful Continuation methods modify the circuit so that the solution is easy to compute and then gradually change the circuit back to its original form Continuation methods are robust but they are slower than the Newton Raphson method If you need to modify and resimulate a circuit that was solved with a continuation method you probably want to save simulation time by directly selecting the continuation method you know was previously successful You select the continuation method with the homotopy parameter of the set or options statements In addition to the default setting a11 five settings are possible for this parameter gmin stepping gmin source stepping sour
359. t character in the filename which is not interpreted as a percent code indicator The predefined percent codes feature does not perform recursive substitutions For example if you have an input file named A SD xyz and you create an output file with the percent code designation C raw the Spectre simulator creates the output file A SDxyz raw The Spectre simulator does not substitute the simulator name for 5 in this case Customizing Percent Codes You can define your own percent codes or redefine existing codes with the lt x gt option of the spect re command Names of customized percent codes can be any single uppercase or lowercase letter You can define percent codes in two ways m You can define percent codes for a single simulation by typing this option into the command line with the spect xe command at the start of the simulation m You can specify the customized percent code as a default by typing the spectre command into the SPECTRE_DEFAULTS environment variables For example if you type in the following instruction at the command line spectre E opampl test3 the Spectre simulator runs a simulation for circuit test 3 During this simulation the Spectre simulator substitutes the name opamp1 for any E it finds in results filename specifications You undefine customized percent codes with the x spectre command option For example if you customize percent codes with the SPECTRE DEFAULTS environmen
360. t has index 3 To specify a limit that notifies you if any BJT is reversed use either of the following specifications 2 lt region lt 2 or 3 lt region lt 1 m You must give the keyword model when you place limits on model parameters If you do not give the keyword mode1 the limits are applied to instance parameters m You can indicate upper or lower limits for the absolute value of a parameter with the vertical line character vto For example resistor 0 1 r 1M specifies that the absolute value of r should be greater than 0 1 ohm and less than 1 megohm There can be no spaces between the absolute value symbols and the parameter name m You currently cannot place limits on vector parameters m You can write parameter limits using Spectre native mode scale factors For example you can write the limit f lt 1 0e6 as f lt 1M Example of a Parameter Range Limits File This example shows a parameter limits file with correct syntax mos3 0 5u lt 1 lt 100u 0 5u lt w 0 lt as lt 1e 8 0 lt ad lt le model vto lt 3 You can find the parameter names 1 w as ad vto and component keywords mos3 in the parameter listings in the Spectre online help spectre nh This example instructs the Spectre simulator to accept without warnings mos3 components for these conditions January 2004 288 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubles
361. t information save ml oppoint m Save specific operating point information save ml vbe M Save all currents and operating point information Save ml Note If the device is embedded in a regular subcircuit you have to know that the device is a subcircuit and find out the appropriate hierarchical name of the device in order to save or probe the device However with inline components you can use the subcircuit call name just as if the device were not in a subcircuit January 2004 101 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Operating point information for the inline component is reported with respect to the terminals of the inline component itself and not with respect to the enclosing subcircuit terminals This results in the following cautions Caution Parasitic Elements in Series with Device Terminals If the parasitic elements are in series with the device terminals the reported operating point currents are correct but reported operating point voltages might be incorrect For example consider the case of an inline MOSFET device with parasitic source and drain resistances inline subckt mos_r dg s b parameters pl 1u p2 2u mos r dp g sp b mos mod l p1 w p2 inline component rd d dp resistor r 10 series drain resistance rs s sp resistor r 10 series source resistance ends mos r If an instance M1 is created of this mos r inline subcircuit an
362. t or analysis parameter values the Spectre circuit simulator accepts and how to specify them Types of Parameter Values Spectre component or analysis parameters can take the following types of values W Real or integer expression consisting of Q Literals Q Arithmetic or Boolean operators Q Predefined circuit or subcircuit parameters a Built in constants fixed values or mathematical functions software routines that calculate equations Q Realor integer constants The name of a component instance or model The name of a component parameter A character string must be surrounded by quotation marks A name from a predefined set of names available to specify the parameter value enumerated types Parameter Dimension Component or analysis parameters can be either scalar or vector If a component or analysis parameter value is a group of numbers or names you specify the group as a vector of values by enclosing the list of items in square brackets for example coeffs 0 0 1 0 2 0 5 to specify the parameter values 0 0 1 0 2 and 0 5 You can specify a group of number pairs such as time voltage pairs to specify a waveform as a vector of the individual numbers Remember these guidelines when you specify vectors of value m You can mix numbers and netlist or subcircuit parameter names in the same vector coeff 0 coeffl coeff2 0 5 January 2004 80 Product Version 5 0 Spectre Circuit Simulator User Guide Par
363. t to revoke this authorization at any time and any such use shall be discontinued immediately upon written notice from Cadence Disclaimer Information in this publication is subject to change without notice and does not represent a commitment on the part of Cadence The information contained herein is the proprietary and confidential information of Cadence or its licensors and is supplied subject to and may be used only by Cadence s customer in accordance with a written agreement between Cadence and its customer Except as may be explicitly set forth in such agreement Cadence does not make and expressly disclaims any representations or warranties as to the completeness accuracy or usefulness of the information contained in this document Cadence does not warrant that use of such information will not infringe any third party rights nor does Cadence assume any liability for damages or costs of any kind that may result from use of such information Restricted Rights Use duplication or disclosure by the Government is subject to restrictions as set forth in FAR52 227 14 and DFAR252 227 7013 et seq or its successor Spectre Circuit Simulator User Guide Contents mit A AA 13 Related Documents clle rh 13 Typographic and Syntax Conventions 0 00 ee 14 Heferenc s Le ee ee Ba BS lw ni SED IRURE hed eg eee ee ER
364. t two parameter settings WB Set the save parameter to either 1v1 or 1v1pub m Set the nest1v1 parameter to the number of levels in the hierarchy you want to save The default setting for nest 1v1 is infinity which saves all levels Saving Groups of Currents The currents parameter of the opt ions statement computes and saves terminal currents You use it to create settings for currents that apply to all terminals in the netlist For two terminal components the Spectre simulator saves only the first terminal entering currents You must use a save statement or use the global redundant currents parameter of the opt ions statement to save data for the second terminal of a two terminal component For more information about the save statement see Saving Signals for Individual Nodes and Components on page 211 January 2004 218 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Setting the currents Parameter The currents parameter has the following options Setting Action selected Saves only currents that you specifically request with save statements or save parameters Also saves naturally computed branch currents currents through current probes voltage sources and inductors This is the default setting nonlinear Saves all terminal currents for nonlinear devices naturally computed branch currents currents through current probes voltage sources and inductors and currents you s
365. t under the Cadence analog design environment To see how the Spectre circuit simulator is run under the analog circuit design environment read the Cadence Analog Design Environment User Guide You can also run the Spectre circuit simulator in the Composer to Spectre direct simulation environment The environment provides a graphical user interface for running the simulation B The Spectre circuit simulator gives you an online help system With this system you can find information about any parameter associated with any Spectre component or analysis You can also find articles on other topics that are important to using the Spectre circuit simulator effectively m The Spectre circuit simulator also includes a waveform display tool Analog Waveform Display AWD to use to display simulation results For more information about AWD see the Analog Waveform User Guide m If you experience a stubborn convergence or accuracy problem you can send the circuit to Customer Support to get help with the simulation For current phone numbers and e mail addresses see the following web site http sourcelink cadence com supportcontacts html January 2004 20 Product Version 5 0 Spectre Circuit Simulator User Guide Introducing the Spectre Circuit Simulator Analog HDLs The Spectre circuit simulator works with two analog high level description languages AHDLs SpectreHDL and Verilog A These languages are part of the Spectre Verilog A
366. t up as follows designl ckt1 designl param lmts designl resistor lmts design2 ckt2 design2 param lmts design2 resistor lmts and you run the Spectre simulator in design1 with the following spect re command spectre tparam design2 param lmts cktl If the file designl param 1mts contains the line include resistor lmts January 2004 289 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting the Spectre simulator reads in the design2 resistor 1mts file but not the designl resistor lmts file Requesting Breakdown Region Warnings for Transistors If you want warning messages about the breakdown regions of transistors you must set the appropriate parameters for each component when you identify the component with an instance or model statement For most transistors you set the bvj parameter For BJTs you must set three parameters bvbe bvbc and bvsub These are breakdown parameters for the base emitter the base collector and the substrate junctions Diodes are also exceptions because you can set both the bv j and bv parameters You need two different parameters for the diode breakdown voltage because of the Zener breakdown model in the diode When you use the diode as a Zener diode it is purposely biased in the breakdown region and you do not want to be warned about the Zener breakdown By specifying the bv parameter you tell the Spectre simulator to implement the Zene
367. t want to divide your device as follows not drawn to scale A 100 um Mod1 Mod2 10 um W Mod4 Mod5 1 um Mod7 Mod8 Mod9 25 um 25 um 1 um 10 um 100 um p L In this example nine models are used These devices are divided into bins For devices whose length lies between 1 um and 10 um and width lies between 10 um and 100 um Mod6 is used January 2004 107 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features The process of generating these models is called binning The binning process is usually identical for all simulators because the equations for binning are always the same P PO Pl Leff Pw Weff Pp Leff Weff There are two ways to do binning with the Spectre simulator m Auto model selection For more information on auto model selection see the following section B Conditional instances For more information on using conditional instances see Conditional Instances on page 109 For more information on using inline subcircuits for model selection see Scaling Physical Dimensions of Components on page 118 Auto Model Selection Automatic model selection is a simulator feature that automatically assigns the correct models to devices based on their device sizes without using conditional instantiation Binning is usually used together with automatic model selection Model selection is now automatic for MOSFETs BSIM1 BSIM2 and BSIM3 Help
368. t2 m2 b2 Tt t1 bl t2 m2 transformer n1 2 Tb t1 bl m2 b2 transformer n1 2 end ct xfmr Circuits that contain ideal transformers N ports or transmission lines can have floating nodes or loops of zero resistance branches because the topology checker cannot adequately verify these components Finding these currents is difficult because all these components act like ideal transformers at DC When you look into one port of a transformer you can see either a short or an open circuit depending on what you see looking out of the other port Internal Error Messages If the Spectre simulator detects an internal error it displays a message like one of the following Internal error detected by spectre Please s http sourcelink cadence com supportcontacts html for Customer Support contact information Error detected in file file c at line 101 Internal error detected by spectre Please s http sourcelink cadence com supportcontacts html for Customer Support contact information Arithmetic exception Cadence can help you find solutions to these problems If you get one of these messages call Cadence Customer Support or contact a Cadence application engineer January 2004 277 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Time Is Not Strictly Increasing PWL takes a wave parameter that accepts time value pairs If the time value does not increase the Spectre s
369. tatement for each component lt q p gt Link between components and instance statements CC Vcc cc cc I out iE Vcc C2 cc bl b2 Q1 Q2 A RI Tee aes gy b Ql cc bl e npn B amp B C3 b1 0 capacitor c 3nF R1 bl 0 resistor r 10k Sample Netlist A netlist is an ASCII file that lists the components in a circuit the nodes that the components are connected to and parameter values You create the netlist in a text editor such as vi or January 2004 28 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre emacs or from one of the environments that support the Spectre simulator The Spectre simulator uses a netlist to simulate a circuit BIT ECP Oscillator Comment indicated by Indicates the file contains a Spectre netlist simulator lang spectre PaE lt see the next section Place below first line Tee e 0 isource dc 1mA Vcc cc 0 vsource dc 5 Q1 cc bl e npn Q2 out b2 e npn L1 cc out inductor 1 1uH Instance statements C1 cc out capacitor c 1pf C2 out bl capacitor c 272 7pF C3 b1 0 capacitor c 3nF C4 b2 0 capacitor c 3nF R1 b1 0 resistor r 10k R2 b2 0 resistor r 10k ic cc 5 41 Control statement sets initial conditions model npn bjt type npn bf 80 rb 100 vaf 50 Model statement cjs 2pf t
370. tatements In addition be sure that the absolute tolerance parameters vabstol and iabstol are set to appropriate values If tightening xe1tol does not help or if it greatly slows the simulation try the additional suggestions in the following sections Suggestions for Improving DC Analysis Accuracy B Be sure there are no errors in the circuit Use the computed DC solution and the operating point to debug the circuit Check the topology the component parameters the models and the power supplies B Be sure you are using appropriate models and that the model parameters are consistent and correct m f the circuit might have more than one solution use nodeset statements to influence the Spectre simulator to compute the solution you want B Be sure that gmin is not influencing the solution If possible set gmin to 0 in an options Or set statement January 2004 298 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems and Troubleshooting Suggestions for Improving Transient Analysis Accuracy W Verify that the circuit biased up properly If it did not there might be a problem in the topology the models or the power supplies B Be sure you are using appropriate models and that the model parameters are consistent and correct Check the operating point of each device B Set the transient analysis parameter errpreset to conservative B If there is a charge conservation problem use only charge conserv
371. tax for two port noise data is noiseformat freq Fmin mag db Gamma real imag mag deg db deg Rn followed by two port noise parameters The syntax for general n port noise data is noiseformat freq CY1 1 CY2 2 CY1 2 CY2 2 followed by the noise coefficient matrix Example A Spectre S parameter file for three ports looks as follows S parameter data file port2 data Generated by spectre from circuit file gendata during analysis swp 12 13 06 PM Fri May 8 1998 reference resistance port3 137 ds pott ps port2 137 is port p2 porti 137 is port pl format freq s33 real imag real imag s13 real imag s32 real imag s22 real imag s12 real imag s31 real imag s21 real imag s11 real imag 0 00000000e 00 0 333333 0 0 666667 0 January 2004 123 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features 2 50000000e 07 5 00000000e 07 0 666667 0 333333 0 666667 0 333333 0 549736 0 450264 0 546593 0 450264 0 549736 0 546094 0 453906 0 533673 0 453906 0 OOOO 0 0181715 0 0181715 0 0556029 0 0181715 0 0181715 0 0359074 0 0359074 0 10951 0 0359074 546094 0 0359074 The following is an example of two port noise data noiseformat freq Fmin mag 1 2 3 4 5a 00000000e 09 00000000e 09 00000000e 09 00000000e 09 00000000e 09 3 3 3 3 3 40 85 40 85 40 85 40 85
372. ted from the values of parameters You specify these conditions with the structural if statement This statement lets you put if else statements in the netlist You can also use conditional instantiation with inline subcircuits For more information on using inline subcircuits see Scaling Physical Dimensions of Components on page 118 Formatting the if Statement You format the structural i statement as follows if condition statementi else statement2 condition The condition fields are Boolean valued expressions where any nonzero value is taken as true statement The statementi and statement2 fields contain one or more instance statements or i f statements The else part of the statement is optional An if Statement Example The following example illustrates the use of the i statement There are additional i f statements in the statement1 and statement2 fields if rseries 0 cl a b capacitor c c if gparallel 0 gpl ab resistor r 1 gparallel else r2 a x resistor r rseries c2 x b capacitor c c if gparallel 0 gp2 x b resistor r 1 gparallel In this example the Spectre simulator puts different instance statements into the simulation depending on the values of two parameters rseries and gparallel January 2004 109 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features If both rseries andgparallel are zero the Spectr
373. tegration method 144 traponly integration method parameter 142 144 trigonometric functions 88 truncate statement 176 truncation factor 176 tutorial for using Spectre 25 two port test circuit sample input file 120 typographical conventions 14 U U 77 uA741 operational amplifier sample input file 135 unif parameter 175 uniform distribution 175 unitless 77 UNIX commands and environment defaults 245 unload shared object 314 unusual parameter size warnings 280 usability features 20 user defined functions 92 V V 76 N predefined percent code 271 vabstol parameter 210 setting to correct accuracy problems 298 values parameter 163 variations parameter Monte Carlo analysis 169 vbcfwd parameter and determining operating regions for BJTs 292 vbefwd parameter and determining operating regions for BJTs 292 Product Version 5 0 Spectre Circuit Simulator User Guide VCO definition of 22 vector parameter values 80 vector values piecewice linear 74 Verilog coupling with Spectre 23 Verilog A 13 vertical bars in syntax 14 viewing output 34 W warning messages 19 about size of gmin 280 caused by invalid parameters in subcircuit calls 98 customizing 284 generating about transistor operating regions 291 options of spectre command 295 parameter is unusually large or small 280 P N junction warnings 278 requesting breakdown region warnings for transistors 290 responding to 33 selecting l
374. tements Another way to insert new files is to use the library statements There are two statements one to refer to a library and one that defines the library A library is a way to group statements into multiple sections and selectively include them in the netlist by using the name of the section As for the include statement the default language of the library file is SPICE unless the extension of the file is scs then the default language is the Spectre Netlist Language Library Reference This statement refers to a library section This statement can be nested To see more information on including files see spectre h include The name of the section has to match the name of the section defined in the library The following is the syntax for library reference include file section Nam where file is the name of the library file to be included The library reference statement looks like an include statement except for the specification of the library section When the file is being inserted only the named section is actually included Library Definition The library definition has to be in a separate file The library has to have a name Each section in the library has to be named because this name is used by the library reference statement to identify the section to include The statements within each section can be any valid statement This is importantto remember when using libraries in conjunction with alter groups because t
375. th scale factors and exponents in the same parameter value For example the Spectre simulator ignores the p in a value such as 1 234E 3p N Caution The Spectre simulator also accepts additional data files such as the waveform and noise files accepted by the independent sources or the S parameter file accepted by the N port Generally these files do not accept numbers with scale factors January 2004 83 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features The Spectre mode simulator lang spectre accepts only the following ANSI standard SI scale factors T 10 G 10 M 10 K 10 k 10 _ 1 1 0 c 1 0 m 1 0 u 1 0 n 10 p 10 210 a 10 Note SI scale factors are case sensitive The Spectre simulator allows you to specify units but only if you specify a scale factor If specified units are ignored Thus c 1pf units f l 1uH units H are accepted but r 500hms is rejected because units are provided without a scale factor For the last example use r 50 Ohms SPICE mode simulator lang spice accepts only the following SPICE scale factors Note SPICE scale factors are not case sensitive Any other scale factor is ignored treated as 1 0 t 10 g 10 meg 10 k 10 p 10 m 10 mile254x10 u 10 n 10 210 N Caution If you are not clear about the scaling rules for each simulation mode you can cause errors in your simulation For ex
376. than four terminals on a device such as vbic hbt or bta_soi the fifth and higher terminals do not return actual currents but return 0 0 You can save signals and include them as simulation results Signals you can save include the following m Voltages at topological nodes B All currents B Other quantities the Spectre circuit simulator computes to determine the operating point and other analysis data Saving Signals for Individual Nodes and Components You can include signals for individual nodes and components in the save list by placing save statements not to be confused with the save parameter in your netlist When you specify signals ina save statement Spectre sends these signals to the output raw file as long as the nest1v1 setting does not filter them In this section you will learn the following m How to save voltages for individual nodes m Howto save all signals for an individual component m How to save selected signals for an individual component The syntax for the save statement varies slightly depending on whether the requested data is from the main circuit or a subcircuit You will learn about the syntax for main circuit statements first and then you will learn how to modify the save statement to store signals from subcircuits January 2004 223 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options Saving Main Circuit Signals The save statement general syntax has the follow
377. the Spectre circuit simulator performs only the pole analysis For a detailed description of the parameters see spectre h pz Example 1 myPZ1l pz Performs pole analysis Example 2 mypz2 nl n2 pz iprobe VIN Performs pole zero analysis for a circuit whose input is VIN and output is the voltage difference between nodes n1 and n2 Example 3 mypz3 nl n2 pz iprobe I1 param temp start 25 stop 100 step 25 Performs pole zero analysis for a circuit whose input is 11 and output is is the voltage difference between nodes n1 and n2 January 2004 149 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Output Log File The output log file contains the following information Complex numbers for poles B Complex numbers for zeroes m Gain for zeroes m Quality factor Q which can be defined as 0 5 IAN Qfactor signo s Z 1 where signis 1 if rea1 0 and sign is 1 if reai gt 0 When rea is 0 Qfactor is not defined If the output of the pole zero analysis contains positive real part poles indicating an unstable circuit the label RHP is appended to those poles An example is shown below CkCk ck ckckck ck ck ck k ck k k kk PZ Analysis mypz Okckckckckckckckck ck ck ck ck ck KKK Poles Hertz Real Imaginary Ofactor 1 4 5694e 10 0 RHP 0 5 2 4 2613e 10 0 RHP 0 5 3 1 4969e 10 0 RHP OS 4 1 4925e 10 0 RHP 0 5 5 1 0167e 10 0 RHP 0 5 6 1 0165e 10 0 RH
378. the Spice input file are converted to MDL Measurement Description Language before being passed on to Spectre The conversion is done via the creation of an MDL control file which is written to the current directory This control file takes on the name of the netlist with a suffix of md1 The simulation that immediately follows the conversion uses the MDL option to Spectre with this control file to evaluate the measure expressions Results are written to a file with the same name as the control file netlist with a measure suffix For example the amp sp SPICE netlist above creates a control file named amp md1 and a measurement output file named amp measure You simply enter the spect respp command with the netlist and the rest of the steps are completed for you automatically The MDL control file is left behind for future use Note In previous releases the command line option spp was used to invoke the SPICE Reader While this method is still supported it is advised that you use the spect respp command if measure statements are included in the input file For more information on MDL see the SpectreMDL User Guide and Reference For backward compatibility a limited SPICE2 netlist reader is embedded into the Spectre netlist reader This reader supports much of SPICE2G6 syntax and has as its primary use the processing of SPICE style model cards If the SPICE Reader is not used this limited SPICE netlist reader is used This is only for
379. the last two iterations These parameter values are added to the tolerances specified by re1to1 They let the Spectre simulator converge when the differences accepted by reltol approach zero You can also set these values with the quantity statement Additional options Statement Settings You Might Need to Adjust This section provides some explanation of commonly used opt ions statement parameters It is not a complete listing of opt ions statement parameters For a complete list consult the Spectre online help spectre h tempeffects This parameter defines how temperature affects the built in primitive components It takes the following three values vt Only the thermal voltage v a is allowed to vary with temperature tc The component temperature coefficient parameters parameters that start with tc such as tcl and tc2 are active as well as the thermal voltage You use this setting when you want to disable the temperature effects for nonlinear devices a11 AII built in temperature models are enabled compatible This parameter changes some of the device models to be more consistent with the models in other simulators See Chapter 3 Component Statements of the Spectre Circuit Simulator Reference manual and the opt ions statement parameter listings in the Spectre online help spectre h for more information The paramset Statement For the sweep analysis only the paramset statement allows you to specify a list of par
380. the same name as a built in primitive device The following message tells you that the local definition will override the built in definition model resistor bjt ql 1 2 3 resistor q1 is considered a bjt device rather than a resistor Initial Condition Messages Notice from spectre during IC analysis during transient analysis tranl Initial condition computed for node 2 is in error by 755 152 uV To reduce error in computed initial conditions decrease rforce However setting rforce too small may result in convergence difficulties or in the matrix becoming singular The Spectre simulator sets initial conditions on a node by attaching a voltage source through a resistor The default value of this resistor is 1 but you can control the value through the options parameter rforce This notice indicates that the initial condition calculated for this node is about 755uV from the value specified in the netlist You can lower the value of rforce to bring the voltage values into agreement in one of the following ways m Through the Analog Options window in the Analog Design Environment B Inserting an options statement in the netlist An example is given below myOptions options rforce 1m Output Messages Notice from spectre during transient analysis tranl No outputs found Loosening output filter criterion to lvlpub January 2004 283 Product Version 5 0 Spectre Circuit Simulator User Guide Identifying Problems an
381. their own alterations to the SPICE input language The SPICE Reader in Spectre does support many of these variations using the following sources and guidelines Sources m The SPICE Version 2G User s Guide vladimirescu81 is the reference for the SPICE2 input language The SPICE Reader accepts input formats from this document for all SPICE capabilities the Spectre simulator supports The SPICE Reader might not accept variations from SPICE 2G6 that are not in the user guide m The SPICE3 Version 3e User s Manual B JohnsonXX is the reference for SPICE3 batch input language The SPICE Reader accepts input formats batch mode only from this document for all SPICE capabilities the Spectre simulator supports m The SPICE BOOK vladimirescu81 is a general reference for SPICE2 3 based syntax s with common extensions m Publicly available netlists provide references for many of the extensions to SPICE Compatibility Guidelines m Mapping of SPICE must not adversely affect simulation results m Where simulators follow different syntax rules support for each is attempted For example the TC property is an instance property in SPICE2 and model parameters TC1 TC2 in SPICE3 both are supported m When a conflict exists between simulator syntax rules one method is selected and documented General Input Compatibility By default the SPICE Reader processes its input in the following manner W Accepts the SPICE instance A Z and contro
382. thod is described in detail in Saving Main Circuit Signals on page 224 Consult this discussion if you need further clarification about the following example ic Voff 0 X3 7 2 5 Ml int_d 3 5 L1 1 1u This example sets the following initial conditions M The voltage of node voff is set to 0 m Node 7 of subcircuit X3 is set to 2 5 V m The internal drain node of component M1 is set to 3 5 V See the following table for more information about specifying internal nodes m The current for inductor L1 is set to 1p Specifying initial node voltages requires some additional discussion The following table tells you the internal voltages you can specify with different components Component Internal Node Specifications BJT int c int b int e BSIM int d int s MOSFET int d int s GaAs MESFET int_d int_s int_g JFET int_d int_s int_g int_b Winding for Magnetic Core int_Rw Magnetic Core with Hysteresis flux January 2004 260 Product Version 5 0 Spectre Circuit Simulator User Guide Time Saving Techniques Supplying Solution Estimates to Increase Speed You use the nodeset statement to supply estimates of solutions that aid convergence or bias the simulation towards a given solution You can use nodesets for all DC and initial transient analysis solutions in the netlist The nodeset statement has the following format nodeset signalName value Values you can supply with the nodeset statement include vo
383. ting the Integration Method The method parameter specifies the integration method You can set the met hod parameter to adjust the speed and accuracy of the simulation The Spectre simulator uses three different integration methods the backward Euler method the trapezoidal rule and the second order Gear method The method parameter has six possible settings that permit different combinations of these three methods to be used The following table shows the possible settings and what integration methods are allowed with each Backward Euler Trapezoidal Rule Second Order Gear euler traponly e trap e gear2only P gear2 s January 2004 144 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Backward Euler Trapezoidal Rule Second Order Gear trapgear2 e The trapezoidal rule is usually the best setting if you want high accuracy This method can exhibit point to point ringing but you can control this by tightening the error tolerances The trapezoidal method is usually not a good choice to run with loose error tolerances because it is sensitive to errors from previous time steps If you need to use very loose tolerances to get a quick answer it is better to use second order Gear While second order Gear is more accurate than backward Euler both methods can overestimate a system s stability This effect is less with second order Gear You can also reduce this effect if you request high accuracy
384. tion of circuit test1 spectre V testl m You activate some Spectre options by typing a plus before the option You deactivate these options by typing a minus before the option For example the following spectre command starts a simulation run for circuit test1 In this simulation the Spectre simulator sets checkpoints but does not print error messages spectre checkpoint error testl Some Spectre options have abbreviations You can find these abbreviations in Chapter 2 Spectre Command Options of the Spectre Circuit Simulator Reference manual For example you can type the previous command as follows Spectre tcp error testl Specific spect re command options are discussed throughout this guide For a complete list of options and formats consult the Spectre Circuit Simulator Reference manual January 2004 240 Product Version 5 0 Spectre Circuit Simulator User Guide Running a Simulation Using License Queuing You can turn on license queuing by using the 1qt imeout parameter If a license is not available when you begin a simulation job the Spectre circuit simulator waits in queue for a license for the specified time If you specify the value 0 for this parameter the Spectre circuit simulator waits indefinitely for a license The 1qtimeout parameter has no default value for the standalone Spectre circuit simulator If you invoke Spectre through the Analog Design Environment the default value for the 1qgt imeo
385. tions you specify a standard deviation using the std keyword The following distributions and associated parameters are supported Gaussian This distribution is specified using di st gauss For the Gaussian distribution the mean value is taken as the current value of the parameter being varied giving a distribution denoted by Normal mean std Using the example in Specifying Parameter Distributions Using Statistics Blocks parameter rshpi is varied with a distribution of Normal 5k 0 4k The nominal value for the Gaussian distribution is the value of the parameter before the Monte Carlo analysis is run The standard deviation can be specified using the std parameter If you do not specify the percent parameter the standard deviation you specify is taken as an absolute value If you specify percent yes the standard deviation is calculated from the value of the std parameter multiplied by the nominal value and divided by 100 that is the value of the sta parameter specifies the standard deviation as that percentage of the nominal value Log normal This distribution is specified using dist 1norm The log normal distribution is denoted by log x Normal log mean std where x is the parameter being specified as having a log normal distribution Note log is the natural logarithm function For parameter xxx in the example in Specifying Parameter Distributions Using Statistics Blocks the process variation is according t
386. tions s 455o da 62er er ier hein dre oa a Soie sigo eed aa Coah 55 4 Spectre Netllsis oor ea ort re YR xa Mehl 57 Netlist St tements ua obo eod aaa cic d eve oe ara a OA on Boca es Eoo dO Ova dde 58 Netlist Conventions screenen ware d bcUo ere eR edd RES RS PO Roun 58 Basie Synta RUES ssas hig focus eur PUT Sep ur Avus i mds 59 Specie Language Modes nis sou aas aha treading OR ou ratu Sia aba rabo A CU uad 59 Creating Component and Node Names llle 60 Escaping Special Characters in Names 2 ccc eee 62 Instance Statements isceR6neei Beli b RESRRXGebR beet Deb 2 oot ete keke SEE 62 Formatting the Instance Statement 0 0 ccc eee 62 Examples of Instance Statements 0 eee eee 64 Basic Instance Statement Rules eee 64 Identical Components or Subcircuits in Parallel 0 20 00 e eee eee 65 Analysis StatementsS 5x bedding rry eters ee b ane da cce he dd gp 66 Basic Formatting of Analysis Statements 0c cece eee 66 January 2004 4 Product Version 5 0 Spectre Circuit Simulator User Guide Examples of Analysis Statements uar sche Pie wk tack n Ade RP CR Cad 67 Basic Analysis Rules 2 06 o naQ ise a tea arated saa bok eat Saad arabe 68 CONMOLS AteMENIS oraora er Pa eee o8 Ao ieee hoe Raha aad oto ee s eed 68 Formatting the Control Statement 0 teens 69 Examples of Control Statements 2534 026302
387. tor substrate diode returns to normal bias condition Most p n junctions in semiconductor models include both a resistive the diode and a capacitive the junction capacitance model If the diode reverse saturation current is set to zero the resistive part of the junction is turned off and the Spectre simulator assumes that the resistive portion of the junction does not exist but the junction capacitance may still be present In this case if the voltage across the missing diode is larger than 10 Vt where Vt is the thermal voltage Spectre will issue a warning message telling you that the junction which is missing will be forward biased A follow up notice is issued if and when the device returns to a normal bias condition Tolerances Might Be Set Too Tight When you simulate high voltage or high current circuits the default tolerances might be tight enough to make convergence difficult or impossible If you get a Tolerances might be set too tight message try relaxing tolerances by increasing the value of reltol iabstol and vabstol Parameter Is Unusually Large or Small The Spectre simulator checks the parameter values to see if they are within a normal range of expected values This check can catch data entry errors or identify situations that can cause the Spectre simulator to have difficulties simulating the circuit The Parameter is unusually large or small message issues a notice about a parameter value The message loo
388. u are saving measurements for a current that passes between two parts of a circuit but not through a terminal January 2004 214 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements The following example inserts a current probe to measure the current flowing between A and B Because there is no component between A and B there is no other way to measure this current except to insert a current probe that has an identical current to the one you want to measure A B Current probe inserted to measure current from A to B Example Name in out iprobe Name The unique netlist name for the current probe component The measured current also receives this name in Input node of the probe out Output node of the probe iprobe Primitive name of the component In the following example the current probe measures the current between nodes src and in names the measured current Iin and saves I in to the raw file Iin src in iprobe Note You can also direct the Spectre simulator to save currents with probes with a save statement option For further information see the description of save statement keywords in this chapter Saving Power To save power dissipated on a circuit subcircuit or device you use the pwr parameter Power is calculated only during DC and transient analyses The results are saved as a waveform representing t
389. u ur tace OOO OY EOLA Bae ed ey O ode 84 Circuit and Subcircuit Parameters 3 2 24 E hee ee bil eeS ese ee ee se EUER ees 85 P r meter Declaratii 51 each gne poe soda dte Gee RA RA ES GN EE M M d ae et 85 ParatmeternherltdbibO smira 33 20 3 S Rag utar Dri b PCR ORE O aat CR a S ES 85 Parameter Referencing 255 5 0 99 9 eases Je dete tend fta Ie ah re afe eee 86 Altering Sweeping Parameters llll leere 86 EXpressiafiS ev sa aer Paes tS DRM NL d dr ERR ER DAE pie boe da E S EUER dud 86 Behavioral Expressions 4 9 24 eR eX dus enr OOPS Dre Mat xD de bade eia f edel 90 January 2004 5 Product Version 5 0 Spectre Circuit Simulator User Guide BUilEIGONStAMIS xus d wari ere EE tat dta a EER RP Re Als OS 91 User Defined Functions nn SiS bs os eared DURS ue ae cedi UE Hae D cse 92 Predefined Netlist Parameters lt 0 24 sess ose y Rae oe cce 93 SHDCIECHIES ab caa de uem eek e tae aca Ned Fe ve xe 838 Skt M Aeg are Ana A cathe n D Ga 93 Formatting Subcircuit Definitions 55 9 3 24 5 26045608 aoa AL Bea Shee as 94 A Subcircuit Definition Example 0 000 94 S bcirc it Example yd cess nc toc iu teu at LAM i espe d a i 95 PUES to Remembel 4 32 23 9 ud dx e X 64k hohe Rui aue ca tU NER Eu uu a 96 Calling SUDCICUNS 2nd reid ds a Uti re aab PR RE trae oda be er eff cid 97 Modifying Subcircuit Parameter Values 6 1 ee 98 Checking for Invalid Parameter
390. uitfile and format the results in binary Nutmeg spectre format nutbin circuitfile Example Using the options Statement You set format options with the rawfmt parameter of the opt ions statement as shown in the following example This statement which you place in the netlist instructs the Spectre simulator to create an output file in binary Nutmeg For more information about the opt ions statement see the parameter listings in the Spectre online help spectre h Settings options rawfmt nutbin Accessing Output Files After you run a simulation you will want access to results of the various analyses you specified To access these results you need to know the names of the files and directories where the Spectre simulator stores these results In this section you will learn how the January 2004 235 Product Version 5 0 Spectre Circuit Simulator User Guide Specifying Output Options Spectre simulator names its output directories and files and how you can change these naming conventions to fit your needs The information in this section applies to psf and wsf formats How the Spectre Simulator Creates Names for Output Directories and Files When you create a netlist you give the netlist a filename When you simulate the circuit the Spectre simulator adds the suffix raw to this filename to create the name of the output directory for the simulation For example results from the simulation of a file named test are stored
391. ult Chapter 13 Identifying Problems and Troubleshooting to find information about installing Cadence defaults or creating your own range limits file if you need to customize defaults m Youcanfind additional information about percent code defaults in Description of Spectre Predefined Percent Codes on page 270 Overriding Defaults You can override defaults in the UNIX environment variables for a given simulation with either spectre command line arguments or opt ions statement specifications The spectre command line arguments also override opt ions statement specifications January 2004 246 Product Version 5 0 Spectre Circuit Simulator User Guide 10 Encryption Encryption allows you to protect your proprietary parameters subcircuits models and netlists and release your libraries to your customers without revealing sensitive information Your customers can run simulations in the Spectre circuit simulator with the encrypted netlists the Spectre circuit simulator does not print any data inside the encrypted blocks Messages about the encrypted portions of your circuit are suppressed You can encrypt netlists that are in the Spectre and Berkeley SPICE formats To encrypt other SPICE netlists you must first convert them to Spectre format by using SPP For more information on coverting netlists see Chapter 3 SPICE Compatibility You cannot use encryption if you are using the Spectre Compiled Model Interface CMI
392. uments of type real and results of type real real myfunc real a real b return atb 2 sqrt a sin b When you define a function follow these rules B Functions can be declared only at the top level and cannot be declared within subcircuits B Arguments to user defined functions can only be real values and the functions can only return real values You must use the keyword real for data typing m The Spectre function syntax does not allow references to netlist parameters within the body of the function unless the netlist parameter is passed in as a function argument B The function must contain a single return statement Note If you create a user defined function with the same name as a built in function the Spectre simulator issues a warning and runs the user defined function January 2004 92 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Calling the Function Functions can be called from anywhere that an expression can currently be used in the Spectre simulator Functions can call other functions however the function must be declared before it can be called The following example defines the function myfunc and then calls it real myfunc real a real b return atb 2 sqrt a sin b real yourfunc real a real b return atb myfunc a b call myfunc The next example shows how a user defined function can be called from an expre
393. urce dc 5 Tee e 0 isource dc 1mA Q1 vcc bl e npn Q2 out b2 e npn L1 vcc out inductor l 1uH Cl vcc out capacitor c 1pf C2 out bl capacitor c 272 7pF C3 b1 0 capacitor c 3nF C4 b2 in capacitor c 3nF R1 bl 0 resistor r 10k R2 b2 in resistor r 10k January 2004 48 Product Version 5 0 Spectre Circuit Simulator User Guide SPICE Compatibility ic bl 1 model npn bjt type npn bf 80 rb 100 vaf 50 cjs 2pf tf 0 3ns tr 6ns cje 3pf cjc 2pf OscResp tran stop 80us maxstep 10ns method trap This example shows several of the basic differences between SPICE and Spectre netlists Spectre netlists define the language context at the beginning of the netlist with the simulator lang spectre statement By default netlists are assumed to be in SPICE unless the simulator lang spectre statement is encountered or unless the netlist file ends in the extension scs The SPICE Reader will insert this line at the beginning of each SPICE to Spectre converted netlist In the SPICE language the component type is determined by the first letter of the component name which limits the component types to 26 The Spectre Netlist Language has unlimited component types since the component type is determined by the master name instead of the first letter of the component name An example of using the master name is the resistor field in the instance statements for R1 and R2 In many versions of SPICE the component name node numbers and other
394. urce type pulse dc 0 val0 0 vall1 10 width 100u period 200u rise 2u fall 2u tdi1 20 taul 20u td2 100u tau2 100u freq 10k ampl 10 delay 5u file sinel0 scale 10 0 stretch 200 0e 6 Vfb nin out vsource Op Amps OA1 pin nin out ua741 Resistors Rload out gnd resistor r 10k Analyses DC operating point pleasel alter param temp value 25 annotate no OpPoint dc print yes readns C r dc25 write C r dc25 Temperature Dependenc Drift dc start 0 stop 50 0 step 1 param temp readns C r dcO write C r dcO XferVsTemp xf start 0 stop 50 step 1 probe Rload param temp freq lkHz readns C r dc0 Gain please2 alter dev Vfb param mag value 1 annotate no OpenLoop ac start 1 stop 10M dec 10 readns C r dc25 please3 alter dev Vfb param mag value 0 annotate no XF XferVsFreq xf start 1 Hz stop 10M dec 10 probe Rload Transient StepResponse tran stop 250u please4 alter dev Vin param type value sin SineResponse tran stop 150u January 2004 137 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses Multiple Analyses in a Subcircuit You might want to run complex sets of analyses many times during a simulation To simplify this process you can group the set of analyses into a subcircuit Because subcircuit definitions can contain analyses and control statements you can put the analyses inside a single subcircuit and perform the multiple analyses wit
395. urrent probe or zero DC valued voltage source on the feedback loop to identify the loop of interest The probe component does not change any of the circuit characteristics and there is no special requirement on the polarity configuration of the probe component The loop based algorithm provides accurate stability information for single loop circuits and multi loop circuits in which a probe component can be placed on a critical wire to break all loops For a multi loop circuit in which such a wire may not be available the loop based algorithm can be performed only on individual feedback loops to ensure they are stable Although the stability of all feedback loops is only a necessary condition for the whole circuit to be stable the multi loop circuit tends to be stable if all individual loops are associated with reasonable stability margins Device Based Algorithm The device based algorithm produces accurate stability information for circuits in which a critical active device can be identified such that nulling the dominant gain source of this device renders the whole network to be passive Examples are multistage amplifier single transistor circuit and S parameter characterized microwave component This algorithm is often applied to assess the stability of circuit design in which local feedback loops cannot be neglected the loop based algorithm cannot be performed for these applications because the local feedback loops are inside the devices an
396. us solutions B Specify initial conditions for components and nodes M Specify solution estimates with nodesets Reducing the Number of Simulation Runs With the Spectre simulator you can run many analyses including analyses of the same type in a single simulation With other SPICE like simulators you might require multiple simulations to complete the same tasks In a single simulation run you can run a set of Spectre analyses modify the component temperature or opt ions parameters and then run additional analyses with the new parameters Adjusting Speed and Accuracy You can use the errpreset parameter to increase the speed of transient analyses but this speed increase requires some sacrifice of accuracy Saving Time by Starting Analyses from Previous Solutions A solution for one analysis can be an appropriate starting point for the next analysis For example if a DC analysis precedes a transient analysis you can use the DC solution as the first guess for the initial point in the transient analysis solution There are two Spectre analysis parameters that let you start analyses from previous solutions They are available for most Spectre analyses m The restart parameter If you set this parameter to rest art no in an analysis statement the Spectre simulator uses the DC solution of the previous analysis as an initial guess for the following analysis B The prevoppoint parameter January 2004 258 Product Version 5 0 Spectr
397. us time fd file for each specified harmonic of the clock fundamental In summary with periodic small signal analyses you apply a small signal at a frequency that might not be harmonically related noncommensurate to the periodic response of the undriven system the clock This small signal is assumed to be small enough so that the circuit is unaffected by its presence With PDISTO you can apply one or two additional signals at frequencies not harmonically related to the large signal and these signals can be large enough to drive the circuit to behave nonlinearly For complex nonlinear circuits hand calculation of noise or transfer function is virtually impossible Without SpectreRF these circuits must be breadboarded to determine their performances SpectreRF eliminates unnecessary breadboarding saving time Mixed Signal Simulation You can use the Spectre circuit simulator coupled with the Verilog XL simulator in the Cadence analog design environment to simulate mixed analog and digital circuits efficiently This mixed signal simulation solution can easily handle complex designs with tens of thousands of transistors and tens of thousands of gates The digital Verilog data can come from the digital designer as either an RTL block or gates out of synthesis Environments The Spectre circuit simulator is fully integrated into the Cadence design framework II for the Cadence analog design environment and also into the Cadence analog workb
398. useful up to nest 1v1 deep in the subcircuit hierarchy This option is equivalent to allpub for subcircuits Normally useful signals include shared node voltages and currents through voltage sources and iprobes lvl Saves all signals up to nest 1v1 deep in the subcircuit hierarchy This option is relevant for subcircuits January 2004 217 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Setting Action allpub Saves only signals that are normally useful Normally useful signals include shared node voltages and currents through voltage sources and iprobes all Saves all signals Use 1v1 or all instead of 1v1pub or allpub to include internal node voltages and currents through other components that compute current Use 1v1pub or allpub to exclude signals at internal nodes on devices the internal collector base emitter on a BJT the internal drain and source on a FET etc 1v1pub and allpub also exclude the currents through inductors controlled sources transmission lines transformers etc Note Setting the save parameter value to selected without any save statements in the netlist is not equivalent to specifying no output Currently the Spectre simulator saves all circuit nodes and branch currents with this combination of settings This might change in future releases of the Spectre simulator Saving Subcircuit Signals To save groups of signals for subcircuits you must adjus
399. usively within protected blocks are encrypted However identical names appearing outside the protected blocks are bound to their encrypted counterparts Hence Cadence recommends that you give unique names to the parameters subcircuits models and devices you want to protect January 2004 256 Product Version 5 0 Spectre Circuit Simulator User Guide 11 Time Saving Techniques In this chapter you will learn about different methods to reduce simulation time This chapter discusses the following topics W Specifying Efficient Starting Points on page 258 Reducing the Number of Simulation Runs on page 258 Adjusting Speed and Accuracy on page 258 Saving Time by Starting Analyses from Previous Solutions on page 258 Saving Time by Specifying State Information on page 259 Saving Time by Modifying Parameters during a Simulation on page 264 Saving Time by Selecting a Continuation Method on page 267 January 2004 257 Product Version 5 0 Spectre Circuit Simulator User Guide Time Saving Techniques Specifying Efficient Starting Points The Spectre circuit simulator arrives at a solution for a simulation by calculating successively more accurate estimates of the final result You can increase simulation speed by providing information that the Spectre simulator uses to increase the accuracy of the initial solution estimate There are three ways to provide a good starting point for a simulation m Start analyses from previo
400. ut but the SPICE based simulator ignores the whole line as a comment spectre Rp 15 0 resistor r 50m Note These statements must be in the Spectre context of a netlist If you need to place the Spectre input in continuation lines begin each line of a continuation with a Vbias vbb 0 1 2 spectre tc 0 001 options reltol 0 001 spectre diagnose yes Compatibility Limitations Conflicts between Spectre and Spice The Spectre simulator does not support all SPICE capabilities for example the disto and PZ analyses Slight modifications are often necessary to make input acceptable to both languages Superficial punctuation differences such as ignoring extra parentheses or equal signs fit this category For example the statement temp 125 whichis legal in SPICE cannot be mapped by the SPICE Reader Removing the extraneous punctuation solves the problem Compatibility is limited in the area of unsupported primitive devices in Spectre You are encouraged to use the extensive capabilities of Verilog A to model such devices Parameters that are to be passed into a subcircuit from an instance statement must be specified on the SPICE subcircuit line Allowing the instance to define a subcircuit parameter is not allowed in Spectre Incompatibilities remain for some rarely used SPICE2 features because the authors have concentrated their efforts on creating compatibility with commonly used features January
401. ut parameter is 900 seconds You can use the 1qsleep parameter to specify the interval in seconds at which the Spectre circuit simulator should check for license availability The default value for the 1qsleep parameter is 30 seconds For more information see spectre h options Determining Whether a Simulation Was Successful When the Spectre simulator finishes a simulation it sets the shell status variable to one of the following values O If the Spectre simulator completed the simulation normally 1 If the Spectre simulator stopped any analysis because of an error 2 Ifthe Spectre simulator stopped the simulation early because of a Spectre error condition 3 Ifa Spectre simulation was stopped by you or by the operating system Checking Simulation Status If you want to check the status of a simulation during a run type the following UNIX command kill USR1 PID PID is the Spectre process identification number which you can find by activating the UNIX ps utility The Spectre simulator displays the status information on the screen or sends it to standard output if it cannot write to the screen If you check the status from a remote terminal the Spectre simulator also writes the status to the SpectreStatus file in the directory from which the Spectre simulator was called The Spectre simulator deletes this file at termination of the run January 2004 241 Product Version 5 0 Spectre Circuit Simulator User Guide Running a Simul
402. utility UNIX 242 sub parameter 161 subcircuit calls checking for invalid parameter values in 98 example 97 formatting 97 January 2004 names unrestricted 98 saving signals 213 225 subcircuit parameters 84 subcircuits calling 93 97 composed of analyses calling 139 example 138 formatting 138 defining 93 example 94 95 formatting 94 expressions within 97 inline 99 multiplication factor in 65 parameters 85 range checking for parameter values 292 saving groups of signals saving individual signals subckts as pwroption 216 228 suppressing messages 295 sweep limits setting 163 sweeping parameters See parameter sweeps 159 swept periodic steady state SPSS analysis brief description of 21 synopsis fourier 154 syntax conventions 59 system generated messages controlling 244 eo 218 23 213 225 T t colon modifier 273 T predefined percent code 271 tdr analysis brief description of 132 Temp 77 temp parameter 93 162 in alter statement 189 266 tempeffects parameter 210 temperature changing with alter statement 189 266 in Celsius 77 terminal index subcircuit calls 213 225 use insave statement 212 224 terminal name useinsave statement 212 Product Version 5 0 Spectre Circuit Simulator User Guide 224 terminals as info statement parameter 203 233 terminal to node map 203 2 terminations of Spectre because of a Spectre error condition 241 b
403. value You can specify sweep limits by giving the end points or by providing the center value and the span of the sweep Steps can be linear or logarithmic and you can specify the number of steps or the size of each step You can give a step size parameter step lin log dec to determine whether the sweep is linear or logarithmic If you do not give a step size parameter the sweep is linear when the ratio of stop to start values is less than 10 and logarithmic when this ratio is 10 or greater All frequencies are in Hertz The small signal analysis begins by linearizing the circuit about an operating point By default this analysis computes the operating point if it is not known or recomputes it if any significant component or circuit parameter has changed However if a previous analysis computed an operating point you can set prevoppoint yes to avoid recomputing it For example if you use this option when the previous analysis was a transient analysis the operating point is the state of the circuit on the final time point Transient Analysis You can adjust transient analysis parameters in several useful ways to meet the needs of your simulation Setting different Spectre parameters that control the error tolerances the integration method and the amount of data saved let you choose between maximum speed and greatest accuracy in a simulation You normally use reltol or errpreset to control accuracy but you can use additional methods i
404. w wi l le mnl mid in 0 0 nmos w wi l le rl mid out resistor r 2k model pmos bsim3v3 type p tnom 27 0 tox 2 9e 09 model nmos bsim3v3 type n tnom 27 0 tox 2 8e 09 unprotect ends open latch module subckt latch q qbar clk d Encrypted Netlist subckt inv out in prag prag prag Desi prag prag ma ma ma gn ma ma pro pro pro Sys pro pro COCU COSCE COCE Lect COCE cems begin protected data method RC5 data keyowner Cadenc data keyname CDS KEY data block fajdfejwrADFASDfdhfjadfahd OERWfdjau77r42jagadfhjkuer pragma protect end protected ends open subckt Encrypting Portions of a Subcircuit or Multiple Subcircuits latch module latch q qbar clk d You can use multiple pairs of protect and unprotect in a subcircuit to protect portions of it See the example below January 2004 251 Product Version 5 0 Spectre Circuit Simulator User Guide Encryption Example Original Netlist subckt inv out in parameters wi lu le 3u protect mpl mid in vd vd pmos w wi l le mnl mid in 0 0 nmos w wi l le unprotect rl mid out resistor r 2k protect model pmos bsim3v3 type p tnom 27 0 tox 2 9e 09 model nmos bsim3v3 type n tnom 27 0 tox 2 8e 09 unprotect ends inv Encrypted Netlist subckt inv out le 3u parameters wi lu global vd pragma protect pragma protect pragma p
405. with Spectre The graph is zoomed such that 70us and 80us are the end points of the X axis Graph Display E m File Edit Graph Axis Trace Marker Zoom Tools Help amp B s EE Aug 20 2003 Transient Analysis OscResp time 0 s 80 us jl 7 Labet out 24049 70 71 72 73 74 76 76 T 78 79 time us gt P graph0 selected double click to bring up attribute dialog c a de nce 5 Click Zoom Fit to return the graph to the unzoomed state Changing the Trace Color To change the color of the trace 1 Double click on the trace January 2004 37 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre The Trace Attributes dialog box appears s Trace Attributes EN Create Help Namen vj Default Strip Chart Visible Rows Type Style Line Solid v Fine v Symbols Plus w 20 Show Foreground SED v Cursor XY Offset 0s DA
406. x Hyperbolic tangent All x Arc hyperbolic sine All x Arc hyperbolic cosine x gt 1 Arc hyperbolic tangent 1 lt x lt 1 Integer part of x number before the decimal Smallest integer All x greater than or equal to X Largest integer less All x than or equal to x Floating point y 0 remainder of x y January 2004 89 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Using Expressions in Vectors Expressions can be used as vector elements as in the following example dc sweep dc param pl values 0 5 1 p2 sqrt p2 p2 sweep pl Note When expressions are used within vectors anything other than constants parameters or unary expressions unary unary must be surrounded by parentheses Vector elements should be space separated The preceding dc_sweep example shows a vector of four elements 0 5 1 p2 and sqrt p2 p2 Note that the square root expression is surrounded by parentheses Behavioral Expressions You can use behavioral expressions within a resistor inductor capacitor voltage or current source Using behavioral expressions you can express the value of a resistance capacitance voltage or current as a combination of device operating points node voltages branch currents and built in Spectre expressions The syntax is name nodel node2 resistor inductor capacitor behav param param list where behav param can be c simple e
407. x1 pwr generated by the save statement January 2004 216 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements Saving Groups of Signals To save groups of signals as results use the save and nest 1v1 parameters Specify which signals you want to save with the save parameter Use the nest 1v1 parameter when you save signals in subcircuits The nest 1v1 parameter specifies how many levels deep into the subcircuit hierarchy you want to save signals You can set these parameters as follows E In options statements or set statements If you set the save and nest 1v1 parameters with an options ora set statement the setting applies to signal data from all analyses that follow that statement in the netlist B In most analysis statements If you set the save and nest1v1 parameters with an analysis statement the setting applies to that analysis only It overrides any previous save or nest 1v1 settings Formatting the save and nestlvl Parameters The syntax for both the save and nest1v1 parameters is illustrated by the following options statement settingl options save lvlpub nestlvl 2 The save Parameter Options The following table shows the possible settings for the save parameter Setting Action none Does not save any data currently does save one node chosen at random selected Saves only signals specified with save statements This is the default setting lvlpub Saves all signals that are normally
408. xample specifies a process distribution for this parameter with a Gaussian distribution with a mean value of 200 and a standard deviation of 24 12 percent of 200 The parameter rshpi sheet resistance varies about its nominal value with a standard deviation of 0 4 K ohms square In the mismatch block the parameter rshsp is then subject to further statistical variation on a per subcircuit instance basis for on chip variation Here it varies a little for each subcircuit instance this time with a standard deviation of 2 For the first Monte Carlo run if there are multiple instances of a subcircuit that references parameter rshsp then assuming variations all it might get a process random value of 210 and then the different instances might get random values of 209 4 211 2 210 6 and so on The parameter xisn also varies on a per instance basis with a standard deviation of 0 5 In addition the parameters rshsp and rshpi are correlated with a correlation coefficient cc of 0 6 Specifying Distributions Parameter variations are specified using the following syntax January 2004 174 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses vary PAR NAME dist type std lt value gt N lt value gt percent yes no Three types of parameter distributions are available Gaussian log normal and uniform corresponding to thet ype keywords gauss lnorm and unif respectively For both the gauss and the 1norm distribu
409. xamples of the stb command stbloop stb start 1 0 stop 1e12 dec 10 probe Iprobe stbdev stb start 1 0 stop 1e12 dec 10 probe mos1 The analysis parameters are similar to the small signal ac analysis except for the probe parameter which must be specified to perform stability analysis When the probe parameter points to a current probe or voltage source instance the loop based algorithm will be invoked when it points to a supported active device instance the device based algorithm will be invoked The gain margin and phase margin are automatically determined from the loop gain waveform by detecting zero crossing in the gain plot and phase plot If margins cannot be determined for a particular stability analysis a log file displays the corresponding reason Loop Based Algorithm The loop based algorithm is based on considering the feedback loop as a lumped model with normal and reverse loop transmission It calculates the true loop gain which consists of normal loop gain and reverse loop gain Stability analysis approaches for low frequency applications assume that signal flows unilaterally through the feedback loop and they use the January 2004 157 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses normal loop gain to assess the stability of the design However the true loop gain provides more accurate stability information for applications involving significant reverse transmission You can place a probe component c
410. xpr Capacitance between the nodes g simple expr Conductance between the nodes l simple expr Inductance between the nodes r simple expr Resistance between the nodes The performance of bsource devices has been improved by implementing a one time compilation step The performance improvement obtained is proportional to the complexity of the bsource expression Following the initial compilation recompilation is only performed if the bsource expression is changed By default the compilation step is enabled If you are making frequent changes to bsource expressions in your design the overhead of the compilation step may become an issue To turn off compilation type setenv CDS AHDLCMI ENABLE NO To re enable bsource compilation type setenv CDS AHDLCMI ENABLE YES January 2004 90 Product Version 5 0 Spectre Circuit Simulator User Guide Parameter Specification and Modeling Features Built in Constants You can use built in constants to specify parameter values The Spectre Netlist Language contains the built in mathematical and physical constants listed in the following table Mathematical constants start with M_ and physical constants start with P_ Constant Name Value Description M_E M_LOG2E M LOGIOE M LN2 M LN10 M PI M TWO PI M_PI_2 MPI A M 1 PI M 2 PI M 2 SORTPI M_SORT2 M_SORT1_2 M_DEGPERRAD January 2004 2 718281828459045
411. xt checklimit statement is encountered Mychecklimit2 checklimit enable assert2 assert6 disable assert7 start 1ns stop 5ns severity warning January 2004 196 Product Version 5 0 Spectre Circuit Simulator User Guide Control Statements specifically enables assert2 and assert 6 thereby disabling all the other asserts assert 2 and assert 6 are run within 1ns and 5ns and a warning is displayed if the asserts are violated Mychecklimit3 checklimit disable assert2 start 5ns stop 10ns severity none Nowassert6 is checked within 5ns and 10ns The severity level is disabled in this checklimit statement so assert 6 determines the severity level if this check is violated dcOpdc runs the DC analysis and checks only assert 6 Since this is a DC analysis the start and stop parameters are ignored Mychecklimit4 checklimit checkallasserts yes disable assertl start l1ns stop 10ns tranl tran 10ns enables all asserts except assert1 and checks them within 1ns and 10ns The ic and nodeset Statements The Spectre simulator lets you provide state information to the DC and transient analyses You can specify two kinds of state information m Initial conditions The ic statement lets you specify values for the starting point of a transient analysis The values you can specify are voltages on nodes and capacitors and currents on inductors m Nodesets Nodesets are estimates of the solution you provide for the DC or
412. y placing a simulator lang command at the beginning of the file For more information about the simulator lang command see Chapter 3 SPICE Compatibility The Spectre simulator assumes that the file to be included is in the SPICE language unless one of the following conditions occurs Q The file to be included has a simulator lang spectre line at the beginning of the file The first line is not a comment title line even in SPICE mode Q The file to be included has a scs file extension With the include format if you change the language mode in an inserted file the language mode returns to that of the original file at the end of the inserted file You cannot start a statement in an original file and end it in an inserted file or vice versa You can use include filename and the Spectre simulator looks for filename in your home directory This does not work for include You can use environment variables in your include statements For example include SMYMODELS filename The Spectre simulator looks for filename in the directory specified by MYMODELS This works for include but not for include January 2004 73 Product Version 5 0 Spectre Circuit Simulator User Guide Spectre Netlists There are two major differences between using include and include m You can specify include to run CPP and use macros and defined constants B include does not expand special characters or environment variables
413. y analysis parameters see the Spectre Circuit Simulator Reference Advanced Analyses sweep and montecarlo There are two advanced analyses sweep and montecarlo Sweep Analysis The sweep analysis sweeps a parameter processing a list of analyses or multiple analyses for each value of the parameter The sweeps can be linear or logarithmic Swept parameters return to their original values after the analysis However certain other analyses also allow you to sweep a parameter while performing that analysis For more details check spectre h for each of the following January 2004 159 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses analyses The following table shows you which parameters you can sweep with different analyses A component A component A netlist Time TEMP FREQ instance model param eter parameter parameter DC analysis dc AC analysis ac Noise analysis noise S parameter analysis sp Transfer function analysis x Transient analysis tran Time domain reflectometer analysis t dr Periodic steady state analysis pss Periodic AC analysis pac Periodic transfer function analysis pxf Periodic noise analysis pnoise Envelope following analysis env1p Sweep analysis sweep DC Match Analysis dcmatch January 2004 160 Product Version 5 0 Spectre Circuit Simulator User Guide Analyses A component A component Time TEMP FREQ instance model
414. y improvements 17 case sensitivity 59 coupling with Verilog 23 customer service 20 differences from SPICE 186 301 environments 23 exitcodes 241 improvements 17 introduction to netlists 29 keywords 60 language title line 51 model improvements 20 netlist elements of 29 reliability improvements 19 RF capabilities 21 run terminations 241 schematic example 26 speed improvements 18 SPICE compatibility reasons for incompatibilities 55 scope 51 stress parameters 179 syntax 59 tutorial 25 usability features 20 Spectre and SPICE input languages reading 50 Spectre and SPICE input languages mixing 54 spectre command checkpoint option in transient analysis recovery 243 16 26 58 January 2004 defaults changing 245 examining 244 error options 295 info options 295 introduction to 32 options format 235 raw 238 restarting transient analysis recover 244 specifying simulation options 240 starting a simulation 240 using to override environment defaults 246 using to specify output directory names 238 using to specify output file format 235 warning options 295 Spectre input mode combining with SPICE input mode 54 Spectre Netlist Language syntax rules 59 SPECTRE_DEFAULTS environment variable 245 284 overriding with param option of spectre command 284 SpectreHDL definition 13 21 SpectreRF brief description 13 description of 21 SpectreStatus file 241 SPICE and Spectre input languages mixing 54 differences fr
415. y the operating system 241 manual 242 normal 241 recovering from transient analysis 242 with an error in an analysis 241 3 testing values of subcircuit parameters 292 time not increasing error message 278 time domain reflectometer tdr analysis brief description of 132 time step adjustment 145 uds control algorithm advantages o timestep used minimum 281 title card 29 title line 29 51 title parameter in Monte Carlo analysis 171 tnom parameter 93 in alter statement 189 266 tolerance warnings 280 tolerances setting with the options statement 209 Toshiba model for hot electron degradation simulation 179 total as pwr option 216 228 tran analysis brief description of 131 transfer curves 161 transfer function analysis xf brief description of 131 transient analysis accuracy 144 brief description of 131 ckptperiod parameter example 244 convergence problems 298 correcting accuracy problems 299 error tolerances See error tolerances 143 ic parameter 197 259 improving convergence 145 integration method 144 read parameter for state files 201 263 readns parameter for state files 201 263 January 2004 restarting 244 specifying initial conditions in 197 259 speed 144 terminations recovering from 242 transistors requesting breakdown region warnings for 290 specifying forbidden operating regions for 291 trap integration method parameter 144 trapezoidal rule in
416. you are new to simulation looking at the schematic and netlist can prepare you to understand the later chapters of this book You can also get more information about command options components analyses controls and other selected topics by using the spectre h command to access the Spectre online help Sample Schematic A schematic is a drawing of an electronic circuit showing the components graphically and how they are connected together The following schematic has several annotations m Names of components Each component is labeled with the name that appears in the instance statement for that component The names for components are in italics for example Q2 January 2004 26 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre m Names of nodes Each node in the circuit is labeled with its unique name or number This name can be either aname you create or anumber Names of nodes are in boldface type for example b1 Ground is node 0 B Sample instance statements January 2004 27 Product Version 5 0 Spectre Circuit Simulator User Guide Getting Started with Spectre The schematic is annotated with instance statements for some of the components Arrows connect the components in the schematic with their corresponding instance statements Bold Type Names of nodes All connections to ground have the same node name Italic Type Names of components also appear in the instance s
417. ype n vto 1 04 gamma 1 34 phi 55 nsub 1e15 cgso 290p cgdo 290p cgbo 250p cj 360u tox 700e 10 pb 0 914 js 1e 4 xj 1 2u ld 1 2u wd 0 9u uo 2793 bvj 14 model pmos mos3 type p vto 0 79 gamma 0 2 phi 71 nsub 1 7e16 cgso 140p cgdo 140p cgbo 250p cj 80u tox 700e 10 pb 0 605 js 1e 4 xj 0 8u 1ld 0 9u wd 0 9u uo 2245 bvj 14 model dnp diode is 3 1e 10 n 1 12 cjo 3 1e 8 pb 914 m 5 bvj 45 imax 1000 model dpn diode is 1 3e 10 n 1 05 cjo 9 8e 9 pb 605 m 5 bvj 45 imax 1000 endsection fast section typical MOSFETS and DIODES for process corner TYPICAL model nmos mos3 type n vto 1 26 gamma 1 62 phi 58 nsub 1e15 cgso 370p cgdo 370p cgbo 250p cj 400u tox 750e 10 pb 0 914 js 1e 4 xj 1u 1d20 8u wd 1 2u uo 717 bvj 14 model pmos mos3 type p vto 1 11 gamma 0 39 phi 72 nsub 1 7e16 cgso 220p cgdo 220p cgbo 250p cj 100u tox 750e 10 pb 0 605 js le 4 xj 0 65u l1d20 5u wd 1 2u uo 206 bvj 14 model dnp diode is 3 1e 10 n 1 12 cjo 3 1e 8 pb 914 m 5 bvj 45 imax 1000 model dpn diode is 1 3e 10 n 1 05 cjo 9 8e 9 pb 605 m 5 bvj 45 imax 1000 endsection typical section slow MOSFETS and DIODES for process corner SLOW model nmos mos3 type n vto 1 48 gamma 1 90 phi 59 nsub 1e15 cgso 440p cgdo 440p cgbo 250p cj 440u tox 800e 10 pb 0 914 js 1e 4 xj 0 8u 1d20 38u wd 1 5u uo 2641 bvj 14 model pmos mos3 type p vto 1 42 gamma 0 58 phi 73 nsub 1 7e16 cgso 300p cgdo 300p cgbo 250p cj 120u
418. yses with netlist instructions This section also tells you how to restart a simulation after a transient analysis termination Customizing Automatic Recovery By default the Spectre simulator creates checkpoint files every 30 minutes during a transient analysis The Spectre simulator deletes these checkpoint files when the simulation ends successfully January 2004 242 Product Version 5 0 Spectre Circuit Simulator User Guide Running a Simulation Reactivating Automatic Recovery for a Single Simulation If you have deactivated the default setting by putting the checkpoint setting in an environment variable you can reactivate the default value for a given simulation run with the following procedure gt Type checkpoint as a command line argument to the spect re command that starts the simulation Determining How Often the Spectre Simulator Creates Recovery Files If you want to change how often the Spectre simulator creates checkpoint files for a particular simulation or if you want your checkpoint files saved after a successful completion you should set the ckptclock parameter of the opt ions statement For more information about the options statement consult the parameter listings in the Spectre online help spectre h The following opt ions statement tells the Spectre simulator to create checkpoint files every 3 1 2 minutes for all transient analyses in a simulation You indicate parameters for ckptclock in seconds
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