- DocuShare
Contents
1. effectively combining two functions into a single selection The selection for this function is limited to a single GPIO connector Please refer to the individual function description for any additional information that may apply This function is not supported in Genie 2000 PHA EXT START STOP IN 17 and MCS EXT START STOP IN 27 PHAEXTSS_IN MCSEXTSS_IN and 28 PHAEXTSS_IN MCSEXTSS_IN NEG Function 27 configures the connector for dual input mode with fixed active high polarity for both modes Function 28 is identical to 27 but the polarity is fixed at active low for both modes Selecting this function internally configures the GPIO connector for dual input mode where the same external user User s Manual 7066438 103 Appendix D External GPIO Configuration Matrix Function Name Description 21 supplied input signal is routed to the PHA EXT START STOP IN see Function 17 and MCS EXT START STOP IN see Function 21 effectively combining two functions into a single selection The selection for this function is limited to a single GPIO connector Please refer to the individual function description for any additional information that may apply PHA EXT START STOP OUT 18 and MCS EXT START STOP IN 21 29 PHAEXTSS_OUT MCSEXTSS_IN Function 29 combines the functionality of the PHA EXT START STOP OUT see Function 182. Full speed USB 2 0 compatible device connection between the Osprey and host PC The connector is a 5 pin mini USB B type receptacle Use a standard USB A to Mini B cable to connect Osprey to your PC This cable is provided with the Osprey unit CAUTION The Osprey requires the USB connection to be to a USB compliant device or damage can occur Controls for the Osprey System This section describes the various controls for the Osprey system Applying Power To power the Osprey plug the device into either a USB connection or an Ethernet connection from a PoE IEEE 802 3af compliant device Power On Self Test When power is first applied to the Osprey the Busy LED will blink green until the instrument has gone through its internal configuration and power on self test POST diagnostics Once this process is complete the Busy LED will change to steady green for a successful power up test The POST takes about 15 seconds Fault Indications If a fault condition is detected within the Osprey the Busy LED will change from blinking green to steady red after POST If the fault condition is serious the Osprey power LED may continue to blink green beyond the normal power on time duration User s Manual 7066438 17 Chapter 2 Controls and Connectors Correcting a Fault If the Osprey signals a fault condition contact your local Canberra Technical Service Center for service before operating the product Factory Reset Control The f
3. Editor 20 The following sections explain how to use the MCA Input Definition MID Editor The MID Editor is used to set the parameters of your MCA as desired and then save those settings as a MID file In addition to using the MID Editor to create a new input definition it may be used to edit an existing MID file You may choose to use the MID Editor to change the default settings for any of the Osprey s programmable Features Two examples are shown below Osprey Universal Digital MCA Tube Base MCA Input Definition MID Editor DSP Gain FDisc Mode Default Auto Coarse Gain Default x8 DSP Filter BLR Mode Default Auto Rise Time Default 1 0 uS Basic Concepts We ll review some basic concepts that are important to understand before actually getting into the details of how you define your system s MCAs Multiple MCA Configurations Since MCA definitions are saved in individual files called MID files you can have as many definitions as you like For example you might have one MCA defined as a 1K Sodium Iodide Spectroscopy MCA in one file and another as a 2K Sodium Iodide Spectroscopy MCA in another file Before you start an experiment you simply pick the configuration you want to use by selecting the appropriate MID file and loading it Because an MCA definition file can include any or all of the MCAs that are available to your system you can use more than one MCA at a time However each MCA can be inc
4. Ethernet cable 3 m 10 ft Ethernet cable PoE input injector 110 220 1 2 m 4 ft MCX BNC cables 3 pcs OSPREY PRO Osprey with S504C Genie 2000 InSpector Basic Spectroscopy Software OSPREY PRO Osprey with S504C Genie 2000 InSpector Basic Spectroscopy Software and S501C Gamma Analysis Option OSPREY E03L 3 m 10 ft Ethernet cable with a right angle plug for use with Model 727 laboratory lead shield LABR 1 5x1 5 14 pin 1 5 x 1 5 in non stabilized LaBr probe NAIS 2x2 8 pin 2 x 2 in LED temperature stabilized Nal probe Model 802 14 pin 2 x 2 in or 3 x 3 in non stabilized Nal probe Osprey Universal Digital MCA Tube Base Communicating with the Osprey B Communication Setup This appendix includes an abbreviated Quick Start for the Network Administrator to summarize a few network connected environments requirements with the Osprey You will need to establish communications with Osprey in order to make any setup changes This may be a temporary setup using your existing PC to interact with the Osprey after establishing an initial connection with Osprey merely to make a few changes so the Osprey can then be accessed normally on your company s network Communicating with the Osprey The Osprey can be operated via Genie 2000 on the host computer The Osprey supports Ethernet TCP IP network connections and USB The USB connection appears as a network adapter This appendix descr
5. Multichannel Scaling mode acquires time correlated data where events are counted into each of the configured channels of a histogram for the specified DWELL time period before advancing to the next channel to eventually produce a full SWEEP Each sweep incorporates a programmed number of channels 256 512 1024 or 2048 Events are counted for the duration of a programmed number of sweeps 4 Osprey Universal Digital MCA Tube Base Acquisition Modes MSS Mode The MSS Multispectral Scaling mode also called ping pong mode alternately collects PHA data in two separate memory groups for a pre programmed condition that can be based on time counts or an external event The Osprey can collect spectra quickly with practically no latency 50ns between acquisitions The spectra can be temporarily held in the device until a client application requests them or can be streamed over the network to waiting client applications List Modes In Standard List mode each PHA energy event is converted to a channel value then is either stored sequentially in an internal buffer until requested by a client application or streamed over the network connection to waiting client applications In Time Stamped List mode each PHA energy event is converted to a channel value time stamped then either stored sequentially in an internal buffer or streamed over the network connection to waiting client applications The time base can be configured for 100 ns o
6. Standard 14 pin PMT socket and CANBERRA proprietary 8 pin socket 8 Pin stabilized detector connector Canberra proprietary 8 pin connector for NAIS 2X2 detector Communication Ports USB 2 0 USB Mini B type 5 pin connector labeled USB D for USB Device Full speed USB support for direct connection of Osprey to a host computer or a USB hub The USB interface is software configurable and must be set up before it is operational Its factory default URL is 10 0 1 4 Ethernet 10 100T Female RJ45 type 8 pin modular jack for connection to an IP Ethernet network or directly to a host computer Port settings under software control and are configurable Factory settings cooperate with Universal Plug n Play detection by a host Windows computer and the wired Internet interface is operational out of the box using the static URL 10 0 0 3 Power over Ethernet PoE is 802 3af compliant Device General Purpose Inputs Outputs Three user configurable General Purpose Input Output connectors labeled GPIO 1 GPIO 2 and GPIO 3 provide access to the device s internal acquisition status counters and start stop control For the connector s functional data refer to the chapter Controls and Connectors on page 6 For detailed description of each GPIO functionality and any restriction s that may apply refer to the appendix External GPIO Configuration Matrix on page 97 GPIO Three freely assignable MCX connectors e TTL compatible mini
7. Verify new version of Firmware has been installed in the Device Information window Exit web page when complete Osprey Universal Digital MCA Tube Base Security Security The Security page Figure 33 allows the Administrator to change the user s password when logged in with administrative privileges A Username 3dministrator Password Logoft CANBERRA System Status a Lt Co Stb Probe Connected Stb Probe Ready HV On HV Ramping Information Device Information Device Setup PHA Acquisition Status MCS Acquisition Status Lf mm Co Ethernet Network Setup Busy Waitin Idle Busy Waiting E E USB Network Set NIA PresetTime Reach PresetIntegralReach Preset Sweeps Reach NIA N A UPnP Setul ES co co External Stop Manual Stop Overflow Stop External Stop Manual Stop Overflow Stop Devices borate m Ly E Group 1 Active Group 2 Active Ext Trg Event Group 1 Active Group 2 Active Ext Trg Event e FPGA Upgrade Firmware Upgrade Security Password Manager User Name Current Password New Password o Confirm New Password Submit Change Passwords Figure 33 Password Manager Settings Change Passwords Use the following steps in the Password Manager to change the administrator password 1 Under Security click on the Change Password link 2 Type administrator in the Username text box 3 Type the curre
8. Voltage The Voltage scroll bar sets the output voltage of the HVPS between the Voltage Limit s minimum and maximum settings The voltage setting can also be typed in from the keyboard and then accepted with the OK button within the control DSP Gain Settings The DSP Gain settings screen Figure 9 for the Osprey contains the following controls m Coarse gain Fine gain PUR Guard Offset x2 z 1 00000x 1 10x ail fs EE Y 1 0000 5 0000 1 1 2 5 FDisc Setting FDisc Mode LTC mode 1 0 Auto C Off 4 gt C Manual On 0 100 LLD Mode Auto Manual ox ovon Figure 9 DSP Gain Setting Dialog The combination of Coarse and Fine Gain sets the overall system gain to match the requirements of the detector and energy range of the application overall gain is continuously variable from x1 to x40 Coarse Gain Sets the device s coarse gain It s best to choose the highest Fine Gain which com bined with the Coarse Gain will produce the total desired gain The Coarse gain allows selections of x1 through x8 Fine Gain Sets the device s Fine Gain multiplier the adjustment range is x1 to x5 PUR GUARD Sets the device s Guard Time GT multiplier to reject trailing edge pileup in the event that detector preamp signal anomalies occur The PUR guard sets the pileup reject interval which is defined by GT x Trisetime Triattop
9. When finished use the Logoff button at the top of the Osprey page or simply close your Internet browser DHCP Setup Changes Optional for IP Network Use If the Osprey is required to operate on a DHCP network the following must be configured in the Osprey in order for it to operate on that network type After this change is made disconnect the Red Crossover cable and then connect the Osprey to the site s network or router hub connection box using the Yellow straight through CATS network cable 84 Osprey Universal Digital MCA Tube Base Quick IP Setup Summary e You must connect with the Osprey Web Status page to make the following changes Refer to previous section You must change the Osprey setting from its default fixed IP address to connect using DHCP e The Name of the Osprey must be set as desired Its default name is Osprey and if you only have one Osprey unit you may choose to leave this as is e If your PC supports Universal Plug and Play discovery UPnP can help you initially connect with the Osprey See Universal Plug and Play on page 86 for more information Change Osprey from Static IP to DHCP This requires the yellow IP network cable Make these changes after the site s DHCP Network is operational but while still connected to your PC using the Red Crossover cable 1 Connect to the Osprey s Web Status page as described above 2 Under Device Setup click on UPnP Setup Enter a new name for the Ospre
10. free from defects in materials and workmanship for a period of one 1 year from the date of shipment of such equipment and B services performed by us in connection with such equipment such as site supervision and installation services relating to the equipment shall be free from defects for a period of one 1 year from the date of performance of such services If defects in materials or workmanship are discovered within the applicable warranty period as set forth above we shall at our option and cost A in the case of defective software or equipment either repair or replace the software or equipment or B in the case of defective services reperform such services LIMITATIONS EXCEPT AS SET FORTH HEREIN NO OTHER WARRANTIES OR REMEDIES WHETHER STATUTORY WRITTEN ORAL EXPRESSED IMPLIED INCLUDING WITHOUT LIMITATION THE WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE OR OTHERWISE SHALL APPLY IN NO EVENT SHALL CANBERRA HAVE ANY LIABILITY FOR ANY SPECIAL EXEMPLARY PUNITIVE INDIRECT OR CONSEQUENTIAL LOSSES OR DAMAGES OF ANY NATURE WHATSOEVER WHETHER AS A RESULT OF BREACH OF CONTRACT TORT LIABILITY INCLUDING NEGLIGENCE STRICT LIABILITY OR OTHERWISE REPAIR OR REPLACEMENT OF THE SOFTWARE OR EQUIPMENT DURING THE APPLICABLE WARRANTY PERIOD AT CANBERRA S COST OR IN THE CASE OF DEFECTIVE SERVICES REPERFORMANCE AT CANBERRA S COST IS YOUR SOLE AND EXCLUSIVE REMEDY UNDER THIS WARRANTY EXCLUSIONS Our warranty
11. software which is copyrighted by the Free Software Foundation write to the Free Software Foundation we sometimes make exceptions for this Our decision will be guided by the two goals of preserving the free status of all derivatives of our free software and of promoting the sharing and reuse of software generally NO WARRANTY 11 BECAUSE THE PROGRAM IS LICENSED FREE OF CHARGE THERE IS NO WARRANTY FOR THE PROGRAM TO THE EXTENT PERMITTED BY User s Manual 7066438 111 Appendix F RTOS License Agreement 112 APPLICABLE LAW EXCEPT WHEN OTHERWISE STATED IN WRITING THE COPYRIGHT HOLDERS AND OR OTHER PARTIES PROVIDE THE PROGRAM AS IS WITHOUT WARRANTY OF ANY KIND EITHER EXPRESSED OR IMPLIED INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE THE ENTIRE RISK AS TO THE QUALITY AND PERFORMANCE OF THE PROGRAM IS WITH YOU SHOULD THE PROGRAM PROVE DEFECTIVE YOU ASSUME THE COST OF ALL NECESSARY SERVICING REPAIR OR CORRECTION 12 INNO EVENT UNLESS REQUIRED BY APPLICABLE LAW OR AGREED TO IN WRITING WILL ANY COPYRIGHT HOLDER OR ANY OTHER PARTY WHO MAY MODIFY AND OR REDISTRIBUTE THE PROGRAM AS PERMITTED ABOVE BE LIABLE TO YOU FOR DAMAGES INCLUDING ANY GENERAL SPECIAL INCIDENTAL OR CONSEQUENTIAL DAMAGES ARISING OUT OF THE USE OR INABILITY TO USE THE PROGRAM INCLUDING BUT NOT LIMITED TO LOSS OF DATA OR DATA BEING RENDERED INACCURATE OR LOSSES SUSTAINED BY YOU OR THIRD PARTIES OR
12. won t be able to go to the next screen Selecting the Memory Groups box will define two memory groups each with an input size equal to the selected number of channels Steps 4 5 and 6 You won t see the screens for Steps 4 5 and 6 these steps are not used when setting up an Osprey Step 7 Summary The Summary screen Figure 17 displays a summary of the current MCA s configuration for review and lets you enter the name of the MID file that the configuration is to be saved to MID Setup Wizard Step 7 Summary x Mid FileName OSPREY01 E MCA Type Osprey MCA Acq Mode PHA Full Memory 2K INPUT Configuration Detector Settings Input Name DETO1 Type Nal Number of Channels 1024 Number of Memory Groups 1 Amplifier Settings INTERNAL ADC Settings INTERNAL HWPS Settings Type INTERNAL lt Back Cancel Help Figure 17 Summary of the Configuration Ending the Definition To complete your Input Definition select Finish The input that you just defined will be stored as an MID file named inputname MID and is automatically loaded into the MCA Runtime Configuration Database When you select Finish you will be asked if User s Manual 7066438 37 Chapter 3 System Setup you would like to define another input Answering Yes will start the Wizard again and No will close the Wizard Note that if you didn t enter an Input Name you won t be allowed to exit the St
13. 28 Osprey Universal Digital MCA Tube Base Defining an MCA OFFSET Sets the device s digital offset in channels The digital offset shifts the memory assignment of the device s conversions either up or down depending on the sign and value of the offset A positive offset value shifts the spectrum by the amount of the offset in upward direction A negative offset value shifts the spectrum by the amount of the offset in downward direction FDisc Setting This adjustment sets the device s Fast Discriminator threshold level when MANUAL Fdisc Mode is selected The range is 0 to 100 A setting of 100 is approximately 20 of the full energy range The percentage value varies slightly based on the rise time of the detector signal FDisc Mode This adjustment sets the device s Fast Discriminator threshold mode AUTO allows the fast discriminator threshold to be optimized automatically above the system noise level MANUAL allows the threshold to be manually adjusted The fast discriminator is used to quickly detect multiple events during the Osprey s signal processing for the determination of a pile up condition LTC Mode Sets the amplifier s Pulse Pileup Rejector and Live Time Corrector When PUR is On the pileup rejector and live time corrector LTC are enabled Off disables the pileup rejector and LTC LLD Active when the Manual Lower Level Discriminator Mode is selected sets the minimum input acceptance level range is 0 to 10
14. End Sets the end channel of the discrimination window used when ROI mode is enabled as the MCS input signal Notes ROI Start and ROI End values are with reference to the PHA input size Only MCS setting adjustments are available for the MCS datasource A PHA datasource for the device must be opened if adjustments to the Stabilizer High voltage Gain or Filter are required Acquire Setup with Genie 2000 This section includes a review of options presented in the Genie 2000 documentation Only those options that are supported with your Osprey setup will be discussed here The Acquire Set dialog Figure 24 allows you to define the set of acquisition setup parameters to be used when initiating data collection on the current hardware datasource S Acquire Setup E x Mode r Time Preset External Control External GPIO Configuration Live Time 1000 000 Start Stop PHA Nene AS GPIO1 00 None x Die C Real Time Sec Cia C FO C Min e a GPIO 2 00 None zl C Li C Hr Ne CM i i Positive GPI03 00 None CM C Negat egative 01 General purpose logic out LOW er Pp A 02 General purpose logic out HIGH Input Size Computational Preset Coincidence Gate Parameters 05 EMMCS Sweep Advance input None Value Mode 06 Ext MCS Chan Advance input Delay Time C integral C Jani Coincidence 07 Coinc Anti Coinc input 1024 Start Chan 1 pus fo 08 MCS input go
15. The centroid channel becomes the focus point for the stabilization algorithm Gain Window This adjustment sets the width in channels of the upper and lower sampling windows on either side of the gain reference peak For best results the windows should be placed so that a shift in the reference peak reflects a significant change in the count rate through the windows Gain Spacing This adjustment sets the spacing in channels between the upper and lower sampling windows For broad peaks the spacing should be set so that the windows edges are not on the flat part of the peak Gain Mode This adjustment sets the Gain Stabilization mode to Off On or Hold e Off disables the spectrum stabilization and resets the correction to the system gain back to zero e On enables the spectrum stabilization by allowing the Stabilizer in the Osprey to continuously monitor the incoming data and compare its rate against a pre established reference making adjustments to the system gain as necessary to maintain a stable ratio e Hold suspends the spectrum stabilization and retains the current correction to the system gain until the Stabilizer is switched to either Off or On 40 Osprey Universal Digital MCA Tube Base Acquisition Window Adjust Dialogs with Genie 2000 Gain Ratio The Gain Ratio value can be manually entered or automatically calculated by the Osprey depending on the Ratio Mode setting The Gain ratio value is interpreted by t
16. This setting is not adjustable Voltage Limit The Voltage limit control establishes the HVPS s maximum output voltage within the selected range The Voltage Limit setting must be established before the Voltage control is adjusted Voltage The Voltage scroll bar sets the output voltage of the HVPS between the Voltage Limit s minimum and maximum settings The voltage setting can also be typed in from the keyboard and then accepted with the OK button within the control Acceptable settings range from zero up to the full range of the power supply When changed the high voltage output ramps towards its new destination at a rate of 100 volts second updated approximately six times per second HVPS Reset This control resets any HVPS fault condition The Osprey will assert a HVPS fault if the measured output voltage falls outside the expected range or if the Osprey detects communication problems with the HVPS electronics Once asserted a HVPS fault must be acknowledged with the HVPS Reset control DSP Gain Parameters The DSP Gain settings screen Figure 21 for the Osprey contains the following controls x C Stab C HVPS Gain C Filter Coarse gain m Fine gain PUR Guard y r Offset Nex x2 1 00000x 110x 0 Prev 4 ila all E gt Help 1 0000 5 0000 11 1 2 5 2048 2048 Figure 21 Adjust Screen s Gain Settings Osprey Universal Digital MCA Tube Base Acquisition Window Adjust Dia
17. be setup through the Input_McsExternalControl parameter and the polarity through the Input_McsExternalControlPolarity parameter The MCS EXT START STOP IN function is limited to a single GPIO connector MCS EXT START STOP OUT 22 MCSEXTSS_OUT Function 22 configures the connector for output mode The MCS EXT START STOP OUT function directs the Osprey device to drive the GPIO connector logic output with either a pulse or a level when the MCS Input acquisition status changes state When Function 22 is selected the parameter Input _McsExternalControlMode defines whether a change in acquisition produces a logic pulse or a logic level at the selected GPIO connector For pulse mode where the parameter is set to DSA2K a 200 ns pulse is produced when MCS acquisition starts or stops For level mode where the parameter 1s set to Lynx the output will be driven active high when the device s MCS acquisition is enabled and inactive low when the device s PHA acquisition is disabled 102 Osprey Universal Digital MCA Tube Base Optimizing Process Time Function Name Description When configured for level mode the output signal will remain active as the MCS acquisition becomes temporarily suspended by either of the following conditions 1 waiting for the stabilized detector to become ready if one is present and the MCS input mode is set for FD or ROI mode or 2 waiting for the external sus
18. defined MID file e Save saves the settings to an existing MID file To remind you to save a changed definition you ll see an asterisk next to the name of the current definition in the Title Bar CAUTION If you change an existing Input Definition saving it will clear the Acquisition Start time You will be asked to retain the existing energy calibration information After having saved the definition the next step is to load it into the run time database so that it can be used by the Genie 2000 applications To load the definition from the Database menu select the Load To menu option Refer to the MCA Input Definition chapter of the Genie 2000 Operations Manual or Genie PC Operations Manual for additional information regarding saving and loading definition files as well as editing existing files By loading this configuration into the VDM runtime database then exiting the MID Editor you will be able access this detector in the MCA View and Control MVC window utilizing your Genie 2000 software The MID Wizard The MID Wizard helps you set up simple Input Definitions quickly and easily It allows you to create a MID definition in a few simple steps If your Input Definition is more complex than the MID Wizard was designed to handle you ll have to use the MID Editor to create your definition It is covered in detail starting in the MCA Input Definition MID Editor on page 20 User s Manual 7066438 33 Chapter
19. however there are no user indicators that require the Osprey be visible to the user Refer to the Factory Reset Control on page 18 section for description of the reset button Panel Indicators The LED indicators are summarized in LED Status on page 7 Figure 1 shows the Osprey s front panel LED indicators communication connectors and general purpose T O connectors A CANBERRA CE irr O HV 10 100 T BUSY Figure 1 Front Panel of Osprey It is not absolutely necessary to be able to observe the LED indicators during operation as the real time results are displayed in the Osprey s user interface For more information refer to the appendix Specifications on page 73 6 Osprey Universal Digital MCA Tube Base Panel Indicators LED Status The Osprey has three LED indicators labeled BUSY HV and ICR After applying power under normal operation the Osprey will initialize in approximately 10 to 20 seconds During the initialization both the BUSY and HV indicators will blink green The status of the ICR indicator will be undefined until the device completes its initialization When the device completes the initialization the BUSY indicator should be steady green the HV should be off and the ICR will depend on the input signal BUSY A multicolor LED showing instrument status and presence of system power The different LED states may be observed during or after the power up self test Blinking Green Instrument
20. list including options groups in the left border 3 Select the Add Remove Windows Components icon in the left hand pane Note Do not double click on this icon to open it If you double click the icon you ll launch two instances of the Add Remove dialog 4 Select the Networking Services item and then select the Details button Figure 36 i x Windows Components You can add or remove components of Windows XP gl To add or remove a component click the checkbox A shaded box means that only part of the componentwill be installed To see what s included in a component click Details Components O HH Message Queuing O Y MSN Explorer M z Networking Services O By Other Network File and Print Services 0 0MB O 3 Outlook Express oome 7l Description Contains a variety of specialized network related services and protocols Total disk space required 56 5 MB Details Space available on disk 4740 8 MB lt Back Cancel Figure 36 Windows Components Wizard User s Manual 7066438 87 Appendix B Communication Setup 5 Select the UPnP User Interface check box Figure 37 Networking Services x To add or remove a component click the check box A shaded box means that seg partofthe componentwill be installed To see what s included in a component click Details Subcomponents of Networking Services O internet Gateway Device Discovery and Control Client O Peer to Peer 0 0 MB CRIP List
21. must be corrected before the data source can be opened If you get a Hardware Verification Error there is a mismatch between the MID Definition setup and the hardware configuration Likely causes are the High Voltage Power Supply configuration or the hardware settings have been changed You can choose to accept or not accept the verification error in the associated dialog box If you select NO a RED error box will appear in the top left corner of the Acquisition and Analysis window You can determine the source of the verification error by looking at the Status Page which you can access by clicking MCA Status The problematic item will be marked with an asterisk The following section describes those parameters for the Osprey that can be accessed from the acquisition windows Adjust dialog screen Select the MCA Adjust menu options to access these screens Note that the Adjust screen for a given device may actually be composed of several screens which are accessed by using the Next Prev buttons Osprey Universal Digital MCA Tube Base Acquisition Window Adjust Dialogs with Genie 2000 Stabilizer The Stabilizer control in the Adjust dialog provides access to a set of parameters used to adjust the Spectrum Stabilizer Note This control is not supported when using NAIS 2X2 detector The spectrum stabilizer algorithm in the Osprey Multi Channel Analyzer is based on similar implementations of spectrum stabilization in oth
22. setup and basic operation of each of these interfaces 34 Osprey Universal Digital MCA Tube Base The MID Wizard The Configure MCA screen Figure 14 lets you define the MCA s Number 1 PHA and 2 MCS and IP address or UPnP name MID Setup Wizard Step 2 Configure MCA OspreyP1 0000000000 Figure 14 Configuring the MCA Discovering the Osprey MCA If the Discover button is selected and the Universal Plug and Play features have been activated in Osprey and with your Windows PC the Osprey identification information will be displayed Select the desired Osprey and click the OK button to automatically fill the IP address information in the Device IP Address field User s Manual 7066438 35 Chapter 3 System Setup Note Discover will only work on networks that do not block Universal Plug and Play UPnP messages and the PC must have UPnP enabled Discover Osprey MCA Figure 15 MID Plug and Play Discovery of Osprey Step 3 Configuring the Detector The Configure Detector screen Figure 16 lets you enter an Input Name Memory Groups Number of Channels and Detector Type this parameter is described in detail in Input Settings on page 32 MID Setup Wizard Step 3 Configure Detector x y a E E Figure 16 Assigning the Detector Type 36 Osprey Universal Digital MCA Tube Base The MID Wizard You can change the default Input Name if you like but if the field is empty you
23. so they know their rights We protect your rights with two steps 1 copyright the software and 2 offer you this license which gives you legal permission to copy distribute and or modify the software User s Manual 7066438 107 Appendix F RTOS License Agreement 108 Also for each author s protection and ours we want to make certain that everyone understands that there is no warranty for this free software If the software is modified by someone else and passed on we want its recipients to know that what they have is not the original so that any problems introduced by others will not reflect on the original authors reputations Finally any free program is threatened constantly by software patents We wish to avoid the danger that redistributors of a free program will individually obtain patent licenses in effect making the program proprietary To prevent this we have made it clear that any patent must be licensed for everyone s free use or not licensed at all The precise terms and conditions for copying distribution and modification follow GNU GENERAL PUBLIC LICENSE TERMS AND CONDITIONS FOR COPYING DISTRIBUTION AND MODIFICATION 0 This License applies to any program or other work which contains a notice placed by the copyright holder saying it may be distributed under the terms of this General Public License The Program below refers to any such program or work and a work based on the Program means either the Pr
24. too small the stabilization algorithm will not be able to correct for normal peak shifts resulting from typical variations in ambient temperature Turn the stabilizer mode to On Since the stabilization algorithm relies on spectral data to establish its reference and changes in spectral data for its decisions on applying correction the algorithm is active when PHA acquire is On and inactive when PHA acquire is Off In addition once the stabilizer is activated neither the fine gain nor the high voltage setting can be changed Turning the high voltage to Off while the stabilizer is active will disable the stabilizer by placing it in the Hold mode In Hold mode the stabilizer will hold the current Osprey Universal Digital MCA Tube Base Acquisition Window Adjust Dialogs with Genie 2000 correction level Once the high voltage is turned back to On the stabilization can be resumed by turning the stabilizer mode to On Turning the stabilizer to Off will reset any correction currently in effect back to zero A shift in peak centroid will take place if the correction was non zero High Voltage Parameters The High Voltage control in the Adjust dialog Figure 20 provides access to a set of parameters required to control the High Voltage Power Supply HVPS in the Osprey Note The only parameter supported when using a NAIS 2X2 detector is HVPS Reset z C Stab HVPS C Gain C Filter Off Prev Nex Range V
25. 0 The LLD setting is a percentage of the full scale spectral size or range ULD The digital Upper Level Discriminator sets the maximum input acceptance level Range is 0 to 100 The ULD setting is a percentage of the full scale spectral size or range LLD Mode Selects Automatic and Manual LLD modes the digital Lower Level Discriminator selects minimum input acceptance level With AUTO select the LLD cutoff is automatically optimized just above the spectral noise threshold MANUAL allows the LLD cutoff to be set manually using the LLD slider bar as a percentage of the full scale spectral size or range The LLD slider bar does not function when AUTO is selected User s Manual 7066438 29 Chapter 3 System Setup DSP Filter Settings The DSP Filter settings screen Figure 10 for the Osprey contains the following controls DSP Filter for input DETO1 BLR mode Auto Me Rise Time m Flat Top 1 0 X 1 0 X x svom oo Figure 10 DSP Filter Settings Rise Time Symmetrically sets the rise time and fall time of the digital filter time response As with conventional Gaussian shaping the degree of noise filtering is proportional to the rise time selection The Rise Time setting range is from 0 2 to 5 0 us Flat Top The Flat Top allows for the charge light collection time of the particular Scintillator Independent adjustment of the flat top allows the shaping function to be optimized for Scintillato
26. 3 System Setup Note Osprey MCA can be used with the no key Genie S504 InSpector Basic Spectroscopy software but only a single Osprey MCA definition can be loaded at a time Configuring Spectrum Refresh Rate Genie software uses the same registry parameter for configuring the default spectrum refresh interval for both Lynx and Osprey MCAs The default rate is 1 second The value of this parameter must be specified in milliseconds e g for a 1 5 seconds update rate enter 1500 This property is located in Windows Registry under the following path HKEY LOCAL MACHINE SOFTWARE Canberra Industries Inc Genie 2000 Environment Lynx SpectrumCacheTime CAUTION Making changes to the Windows Registry is a dangerous procedure If you modify the registry incorrectly your Genie and even Windows may become unusable Only experienced users should be making these changes Osprey and MID Files Your Osprey s MCA information can be saved as a file or files that you can save and exchange with Genie 2000 This file is referred to as a MID file Genie 2000 includes tools to create and modify MID files specifically the MID Wizard and the MID Editor These tools and MID files are discussed in depth in the Genie 2000 manuals and are covered in the following sections as they relate to the Osprey including e Using the MID Editor to Set Up your Osprey MCA e Using the MID Wizard e Using the Acquisition and Analysis Window MCA Input Definition MID
27. 3 System Setup Using the Wizard To use the MID Wizard open the Genie 2000 folder and select the MID Wizard exe cutable file Mid Wiz exe or from the Start menu select Programs GENIE 2000 MID Setup Wizard to start the definition process Note At any time you can click Next to proceed to the next screen click Back to return to the previous screen or click Cancel to exit the wizard You can also access the help topic for each screen by clicking on the Help button Step 1 Selecting the MCA The Select MCA screen Figure 13 lets you select the MCA you want to create a definition for Select Osprey MCA from the list of available MCAs by clicking on the symbol next to Network MCAs and then click the Next button MID Setup Wizard Step 1 Select MCA x To start select an MCA device from the list below Available MCAs 589 Network MCAs E9 AM BH AM DSP E9 DSA net z9 DSA 2000 8 Falcon 5000 using I2K F5K E9 Lynx MCA E9 Multiport Il Net a m USB MCAs H RS232 MCAs m Plug in Board MCAs 1 EB EE E 488 MCAs Unknown MCAs Figure 13 Selecting the MCA Step 2 Configuring the MCA Note At this point in the setup process the Osprey is required to be connected to the network or directly to the host computer Note the device s IP address or UPnP name as it will be required to complete the setup Refer to the appendix Communication Setup on page 81 as it describes the initial
28. 5 Select Internet Protocol TC IP and then click on Properties The Internet Protocol Properties page Figure 38 opens This sets up the client side e g your PC s end of the USB connection to some otherwise unused address Local Area Connection 3 Properties General Authentication Advanced Connect using o ta This connection uses the following items ml QoS Packet Scheduler f Canberra NDIS 5 0 SNAP Protocol Driver V1 2 fgg Internet Protocol TCP IP R R Install Uninstall Properties Description Transmission Control Protocol Internet Protocol The default wide area network protocol that provides communication across 7 Show icon in notification area when connected V Notify me when this connection has limited or no connectivity Figure 38 Set up the USB Connection 90 Osprey Universal Digital MCA Tube Base Setting Up a USB Connection 6 Select the General tab and then select the Use the following IP address option Enter the following settings Refer to Figure 39 Internet Protocol TCP IP Properties E 2 x General You can get IP settings assigned automatically if your network supports this capability Otherwise you need to ask your network administrator for the appropriate IP settings Obtain an IP address automatically Use the following IP address IP address 10 0 1 10 Subnet mask 255 255 255 0 Default gate
29. A FAILURE OF THE PROGRAM TO OPERATE WITH ANY OTHER PROGRAMS EVEN IF SUCH HOLDER OR OTHER PARTY HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES END OF TERMS AND CONDITIONS Osprey Universal Digital MCA Tube Base Index A About this manual cee ceeeceeeeceteceeeeeeneeeeenes 2 Access the web status page cccescesesseeseereeees 84 ACQUITE SUD 48 COMIC is 52 computational preset oooonccincnionnnononcnonnnnnnonos 51 COUNTING MOMES ssie eserse ssrt 49 data acquisition oooonooonoccnononononnnonncnn nono nonnonnnnnos 49 inputs Ze ns 51 MCS IPIeset td e E 49 HIME presetan Sa a a 49 Acquisition modes Acquisition Modes cc ccescesseseessesseeeeeeeeeees 4 Auxiliary COUNtCTS cccceesceeeesceeeeeteeeteeneeeaes 5 MCS preset mode cooooonoonccccocononoconcconccnnonnnonnnonnns 4 A ON 5 Acquisition status MES a 61 fon PAA ee a Ra 60 Acquisition units AUX acquisition Ult oooooconoccnoninononononnnnanonnnonos 4 Lists Odes aii tii 5 MCS acquisition unit oooooonncconnnocnconccnncnnnonnnonnos 3 PHA acquisition UMIt ccceseeceseeeteeseeseeenes 3 SCA acquisition unit seere serere 4 Single Channel Analyzer SCA 5 Adding an MCA ii ts E E 22 Applying pOWeT essssessesseeessseeeessesersreseessseeressese 17 Cc Changing the password cccsssceeseesseeseeneeenes 71 COINC ANTI COINC coccccoconccnoncononnnnnoncnncnnonons 8 52 Communication interfaces Elli 57 GPIO connections ooccoccconoccnonon
30. Active Group 2 Active Ext Trg Event Firmware Upgrade Security Ethernet Setup Change Passwords static MAC Address 00 00 AF 00 20 1 DHCP Submit USB Network Setup static MAC Address 00 00 AF 00 20 1F Assigned Address fo Jo b f IP Address mo jo J4 Default Gateway 10 Jo 1 J4 Subnet Mask ass Ja5s _ 255 o Submit UPnP Setup UPnP Friendly Name fosp P2 UPnP TTL E Enable UPnP vw Figure 31 Device Setup Parameters Ethernet Network Setup Refer to the appendix Communication Setup on page 81 for network setup directions for Ethernet connection Static and DHCP Static enables Static IP addressing and DHCP enables DHCP User s Manual 7066438 65 Chapter 4 Web Based Status MAC Address The network card Media Access Control Address This is a read only field for information purposes and cannot be changed Assigned Address The current IP address of the device This can be a static address or the address assigned by the DHCP server if DHCP is enabled This is a read only field for information purposes and cannot be changed IP Address Defines the static IP address of the device When the Static radio button is selected the device s static IP address can be changed by typing the desired IP address in the appropriate boxes and pressing the submit button It is required to re
31. CA in the definition table We ll take a brief look at the other items in the entry now As we get further into the definition process we ll cover them in greater detail Note the letter following the unit number in each Definition Table item available an M indicates a manually controlled unit and a P indicates a programmable unit Osprey Universal Digital MCA Tube Base Defining an MCA MCA This is the type of MCA device being used for this particular entry in the table Input This is the name that will be used to refer to this specific hardware entry in the table The MID Editor automatically assigns these names sequentially as DETnn starting with nn 01 You can easily change these names to something you find more meaningful Size This shows the number of data channels assigned to this input Stab This column describes the Stabilizer associated with the Osprey HV This column describes the High Voltage Power Supply associated with the Osprey Gain This column describes the DSP Gain associated with the Osprey Other Entries All of the other entries ADC MXR and Amp are not configurable parameters for the Osprey Device Setup The Devices menu sets the parameters for the Osprey s MCA and associated devices Some Devices options are disabled grayed out because they do not have any adjustable parameters Of the enabled Devices only the MCA has user selectable parameters The remainder default to their only p
32. C_IN Function 19 configures the connector for input mode The EXT SYNC IN function directs the respective GPIO connector to accept a user supplied external TTL signal and route it to the Osprey s internal Sync Module for internal distribution to the various acquisition units including MSS unit Aux Counter unit SCA unit and List TList unit When properly configured the Osprey will accept a user supplied signal to synchronize the acquisition of the various acquisition units To accept an external signal the Sync Module must be configured for Slave mode through the Input_ExternalSyncMode parameter The polarity is selected through the Input_ExternalSyncPolarity parameter The EXT SYNC IN function is limited to a single GPIO connector This function is not supported in Genie 2000 EXT SYNC OUT 20 EXTSYNC_OUT Function 20 configures the connector for output mode The EXT SYNC OUT function directs the Osprey device to drive the GPIO connector output from the internal Sync Module to provide a synchronization signal to other devices To provide an output the Sync Module must be enabled through the Input_ExternalSyncStatus parameter and selected for MasterA or MasterB mode through the Input_ExternalSyncMode parameter In MasterA mode then User s Manual 7066438 101 Appendix D External GPIO Configuration Matrix Function Name Description output will be a pulse whose rate is de
33. Osprey Universal Digital MCA Tube Base 7066438 User s Manual Copyright 2010 Canberra Industries Inc All rights reserved The material in this document including all information pictures graphics and text is the property of Canberra Industries Inc and is protected by U S copyright laws and international copyright conventions Canberra expressly grants the purchaser of this product the right to copy any material in this document for the purchasers own use including as part of a submission to regulatory or legal authorities pursuant to the purchaser s legitimate business needs No material in this document may be copied by any third party or used for any commercial purpose or for any use other than that granted to the purchaser without the written permission of Canberra Industries Inc Canberra Industries 800 Research Parkway Meriden CT 06450 Tel 203 238 2351 FAX 203 235 1347 http www canberra com Canberra is an AREVA company The information in this document describes the product as accurately as possible but is subject to change without notice Printed in the United States of America For technical assistance call our Customer Service Hotline at 1 800 255 6370 or email techsupport canberra com Osprey and Genie are trademarks of Canberra Industries Inc Microsoft Windows Vista and XP are registered trademark of Microsoft Corporation in the United States and or other countries Table of Cont
34. Pin Probe CAUTION Do not force the connection doing so can permanently damage either or both units If resistance is felt pull the two units apart recheck the alignment of the keyway and carefully press them together again Refer to the specific Scintillation Detector User s Manual for the tube base pin configuration 54 Osprey Universal Digital MCA Tube Base System Connections for a Detector 14 Pin Tube Socket Pin out The 14 pin tube base socket is a standard JEDEC B14 38 socket that will accept a 10 stage PMT The pin out is as follows Pin Function 1 Dynode 1 2 Dynode 2 3 Dynode 3 4 Dynode 4 5 Dynode 5 6 Dynode 6 7 Dynode 7 8 Dynode 8 9 Dynode 9 10 Dynode 10 11 Anode 12 N C 13 FOCUS 14 K Cathode User s Manual 7066438 55 Chapter 3 System Setup 8 Pin Stabilized Detector To connect the NAIS 2X2 stabilized detector with the Osprey device refer to the photos and steps below Figure 27 Connecting the Osprey to an 8 Pin Stabilized Probe 56 Osprey Universal Digital MCA Tube Base System Connections for a Detector CAUTION Do not force the connection doing so can permanently damage either or both units If resistance is felt pull the two units apart recheck the alignment of the keyway and carefully press them together again 1 Carefully align the keyway and pins on your detector with the 14 pin tube socket base on the Osprey device To ensure correct alignment the detector has a key which ma
35. ROI Selection or the and buttons to move to the next ROI These functions automatically replace the limits with the current ROI s start and stop channels User s Manual 7066438 51 Chapter 3 System Setup Note ROI Start Channel and ROI Stop Channel values are with reference to the PHA input size Coincidence Coincidence is the ability to qualify the recording of incoming events A qualifying gate signal must arrive within a time window which is selectable by the user The gate input signal at the configured GPIO connector determines which incoming events are recorded Events which do not meet the qualification requirements are not recorded Select the proper GPIO for the Coincidence Gate input using the External GPIO Configuration Refer to the appendix External GPIO Configuration Matrix on page 97 for GPIO configuration selection chart and descriptions Mode Gating Select the gating mode Coincidence or Anti Coincidence or Off e In Coincidence mode an incoming pulse of the selected polarity within the selected gate window permits recording of the event e Jn Anti Coincidence mode an incoming pulse of the selected polarity within the selected gate window inhibits recording of the event e In OFF mode the Coincidence function is disabled Polarity Selects the polarity of the gate input Positive or Negative Delay Time us Selects the time window in microseconds available for arrival of the qualifying gat
36. RTOS Demo CORTEX LM3S102 GCC hw_ include and FreeRTOS Demo CORTEX_LM3S316 IJAR hw_include directories The copyright of these files is owned by Luminary Micro Permission has been granted by Luminary Micro for these files to be included in the FreeRTOS download Users must ensure the license conditions stated in the EULA txt file located in the same directories is understood and adhered at all times for all files in those directories The files contained within FreeRTOS Demo WizNET_DEMO_TERN_186 tern_code which are slightly modified versions of code provided by and copyright to Tern Inc Errors and omissions should be reported to Richard Barry contact details for whom can be obtained from http www FreeRTOS org The GPL license text follows 106 Osprey Universal Digital MCA Tube Base Optimizing Process Time A special exception to the GPL is included to allow you to distribute a combined work that includes FreeRTOS org without being obliged to provide the source code for any proprietary components See the licensing section of http www FreeRTOS org for full details The exception text is also included at the bottom of this file GNU GENERAL PUBLIC LICENSE Version 2 June 1991 Copyright C 1989 1991 Free Software Foundation Inc 59 Temple Place Suite 330 Boston MA 02111 1307 USA Everyone is permitted to copy and distribute verbatim copies of this license document but changing it is not allowed Preamble The licen
37. S EXT START STOP OUT This mode combines the PHA EXT START STOP IN and MCS EXT START STOP OUT functionality into a single GPIO connector to provide a synchronization signal from the MCS Acquisition Unit into the external start stop logic of the PHA Acquisition Unit When this mode is selected the signal at the designated GPIO connector can further be used to drive other logic such as the counter logic or external start stop logic of other Osprey devices Refer to the individual functions for more details and any restrictions that may apply This function is limited to a single GPIO connector additionally the PHA EXT START STOP IN cannot be selected again on any other GPIO connector MCA PROBE I O This mode provides a special feature used during factory testing and should never be selected by client applications User s Manual 7066438 15 Chapter 2 Controls and Connectors PHA TEST IN This mode provides a special feature used during factory testing and should never be selected by client applications Tube Socket The Osprey detector socket is compatible with all standard 14 pin scintillation detectors including Nal Tl and LaBr3 Ce and a CANBERRA proprietary LED temperature stabilized 8 pin locking Nal detector Please refer to Basic Detector Setup on page 53 for instructions on how to connect each detector type Osprey System Power Each Osprey unit receives power through either the USB connection or the Ethernet conne
38. STOP OUT function directs the Osprey device to drive the GPIO connector logic output with either a pulse or a level when the PHA Input acquisition status changes state 100 Osprey Universal Digital MCA Tube Base Optimizing Process Time Function Name Description When Function 18 is selected the parameter Input_PhaExternalControlMode defines whether a change in acquisition produces a logic pulse or a logic level at the selected GPIO connector For pulse mode where the parameter is set to DSA2K a 200 ns pulse is produced when PHA acquisition starts or stops For level mode where the parameter is set to Lynx the output will be driven active high when the device s PHA acquisition is enabled and inactive low when the device s PHA acquisition is disabled When configured for level mode the output signal will remain active as the PHA acquisition becomes temporarily suspended by either of the following conditions 1 waiting for the stabilized detector to become ready if one is present or 2 waiting for the external suspend resume signal to resume PHA acquisition if the external start stop logic has been configured for level mode Logic polarity for PHA EXT START STOP OUT is fixed at active high Multiple GPIO connectors can be configured for the PHA EXT START STOP OUT function to extend the same output to multiple connectors This function is not supported in Genie 2000 EXT SYNC IN 19 EXTSYN
39. TXD GPIO 3 not used This function is intended for factory use and should never be configured outside of the factory This function is not supported in Genie 2000 104 Osprey Universal Digital MCA Tube Base Optimizing Process Time E Installation Consideration This unit complies with all applicable European Union requirements Compliance testing was performed with application configurations commonly used for this device During design and assembly of the device precautions were taken by the manufacturer to minimize the effects of EMI on the system However care should be taken to maintain full compliance These considerations include e Single point external cable access e Compliant grounding and safety precautions for any internal power distribution e The use of CE compliant accessories such as cables UPS etc Preventive Maintenance This unit does not require any periodic cleaning maintenance Any maintenance should be performed by a qualified Canberra service representative Operating Protection Impairment Canberra is not liable for any operational malfunctions or personal injuries due to mishandling or unauthorized repair and maintenance not detailed in this manual Cleaning Decontamination When needed the unit may be cleaned Remove power from the unit A before cleaning Use only a soft cloth dampened with warm water and do not allow water to enter the unit Make sure unit is fully dry before restor
40. actory reset button is located behind a small hole in the Osprey s panel to the left of the GPIO 1 connector CAUTION Operating this control will interrupt an acquisition in process To reset the instrument to a factory default condition with power applied to the Osprey press and hold the button with a small screwdriver as noted below e Press and hold for greater than 1 second and release before 7 seconds to reset the instrument to the factory default condition and settings e Press and hold for 7 seconds to perform a reboot of the instrument and restart in boot loader mode This mode is used for updating the firmware Please note the device will need to be communicating via USB to load firmware This mode is for diagnostic purposes and not for normal operation e Press while applying power to enter boot loader mode This mode is used for updating the firmware Please note the device will need to be communicating with USB to load firmware This mode is for diagnostic purposes and not for normal operation e If the device requires a hard reset and then to start up in normal operating mode disconnect and reconnect the USB or Ethernet connector whichever connector is supplying power 18 Osprey Universal Digital MCA Tube Base The Osprey Digital MCA Tube Base 3 System Setup This chapter serves as an overview of setting up a basic Osprey system Those user based commands that are related to a one time only setup function such as
41. aeved RAA a eSa 65 Ethernet Network Setup imita td Bs 65 USB Network Sep a ss 66 UPOP Setup A A AA A A A A a tel eelet tee 67 Device Pp a Ka masilla lesa ia OE 68 Installing the Firmware and FPGA Files cccccceecccessceseceseceeeceeeeeeeeeeeeeeseecseecsaeeaecnaeenaeenaeens 69 SECUN NN 71 Web Update Utensilios 72 A SPCC AU OS sii 73 Inputs OUt puts cid aa a id ai 73 ComimuniCation Ports succionar oir naaa 73 Device General Purpose Inputs Outputs oooccoocnnononononononononononon cono nono noon nono nono nncnaconnnnnnonn nono ncannnos 73 Acquisition Mode ca sa 75 Performante adm Reece tas gage SERS os oa ang Ad ity dass 76 Programmable Controls A east 77 High Voltage Power Supply cccsccssscssscesscessceeeceeeeeeeeeeseeeseecseecseecsaecsaecnseceseeeseeseeeseeeeeseeseeeeaees 77 O A weedy a cain E nolan A S AE NS 77 Indicators E E TE EEEE E EE 78 DISIK Ee N EAEE EE EAEE AAA EE E E T E 78 POW ais neioii A A AA A E a Saa 78 RON 78 ENVIO Mii A A aaa 78 User s Manual 7066438 iii Compliance a id te RL e ceo dl 79 II A a o 79 Computer Requitements tad aiii 80 Ordering Information A A A AA A A AAA ie 80 B Communication Setup sci scececccccccicccecscessccsesentecsseseecendesecesedesescseees 81 Communicating with the Osprey ccccccssecssecssecsseeseecssecesecesecnsecnseeseeeeeeeseeeceseeeseecseceseseeenseeses 81 Factory Settings for the Osprey cccccesccesscessceeeceeeceeeeeeseeeseecseecsaecseecssecesesee
42. al to the device through the designated GPIO connector Selecting SCAn function on a GPIO connector makes the same pulses counted by the SCA counter available on that GPIO connector The internal SCA counters can be read by the GetSCAbuffer command The SCA energy windows can be set through the PutSCA definitions command and read through the GetSCA definitions command Multiple GPIO connectors can be configured for other SCAn functions or to the same SCAn function There are no restrictions These functions are not supported in Genie 2000 PHA EXT START STOP IN 17 PHAEXTSS_IN Function 17 configures the connector for input mode The PHA EXT START STOP IN function directs the GPIO connector to accept an external user supplied signal to synchronize the start or stop of the Osprey s PHA acquisition The Osprey supports both pulsed and level modes of external acquisition control The PHA input s external start stop logic must be enabled and configured for either pulsed DSA2K or level Lynx control mode through the Input_PhaExternalControlMode parameter The pulsed mode behavior must be setup through the Input_PhaExternalControl parameter and the polarity through the Input_PhaExternalControlPolarity parameter The PHA EXT START STOP IN function is limited to a single GPIO connector PHA EXT START STOP OUT 18 PHAEXTSS_OUT Function 18 configures the connector for output mode The PHA EXT START
43. ale cd AASE EEEE E Heron nnurEEEnnE me Teer enie aes AE EEEE EET 113 iv Osprey Universal Digital MCA Tube Base Preface The Osprey Universal Digital MCA Tube Base is a fully integrated 2K channel signal analyzer offering advanced signal processing filters and digital stabilization User s Manual 7066438 All in one HVPS preamplifier and digital MCA Compatible with all standard 14 pin scintillation detectors including Nal TI and LaBr3 Ce Optional temperature stabilized locking Nal detector USB 2 0 connection for PC plug and play Ethernet 10 100T PoE connection for network applications PHA MCS SCA AUX Counter MSS List and Time stamped List modes of acquisition PHA and MCS modes are fully supported by Genie 2000 Software SCA AUX Counter MSS List and Time Stamped List modes are supported by programming libraries Includes programming libraries with examples The programming libraries expose methods to client applications for accessing the Osprey s full complement of parameters and controls for acquisition external start stop coincidence gating and counters Compatible with Canberra Model 727 shield Support for scintillation detectors used in gamma and x ray spectroscopy with up to 2K channels of spectral memory User interfaces e Full featured acquisition analysis capability through Canberra s Genie 2000 spectroscopy software e Live system status and firmware updates using an Internet brows
44. an external MCS Sweep Advance Input signal for synchronizing the start of an MCS sweep The MCS Input defaults to internal sweep advance mode therefore must be specifically configured to accept an external sweep advance signal through the Input_ McsExternalSweepAdvMode parameter The polarity defaults to active high but can also be selected through the Input_ McsExternalSweepAdvPolarity parameter The MCS EXT SWP ADV selection is limited to a single GPIO connector MCS EXT CHN ADV 06 MCSEXTCHN_IN Function 06 configures the connector for input mode The MCS EXT CHN ADV function directs the respective GPIO connector to accept an external MCS Channel Advance Input signal for user controlled dwell time during an MCS sweep The MCS Input defaults to internal channel advance mode 98 Osprey Universal Digital MCA Tube Base Optimizing Process Time Function Name Description therefore must be specifically configured to accept an external channel advance signal through the Input_McsExternalChannelAdvMode parameter The polarity defaults to active high but can also be selected through the Input_ McsExternalChannelAdvPolarity parameter The MCS EXT CHN ADV selection is limited to a single GPIO connector COINC ANTI COINC 07 COINCANTI IN Function 07 configures the connector for input mode The COINC ANTI COINC function directs the respective GPIO connector to accept a user supp
45. arameter Internal Note At this point in the setup process the Osprey is required to be connected to the network or directly to the host computer Note the device s IP address or UPnP name as it will be required to complete the setup Refer to the appendix Communication Setup on page 81 as it describes the initial setup and basic operation of each of these interfaces User s Manual 7066438 25 Chapter 3 System Setup MCA From the Device menu select the MCA command to display the dialog box Figure 6 Enter the IP address or its exact UPnP Name can be entered and define the MCA s Number 1 PHA and 2 MCS then click on OK to accept the changes MCA for input DETO1 f x Device IP Address Name fi0 0 1 4 MCA Number a Discover Cancel Help Figure 6 Identify Osprey Device by entering its IP Address Note Device names are restricted to 10 characters in length Discovering the Osprey MCA If the Discover button is selected and the Universal Plug and Play features have been activated in Osprey and with your Windows PC the Osprey identification information will be displayed Select the desired Osprey and click the OK button to automatically fill the IP address information in the Device IP Address field Note Discover will only work on networks that do not block Universal Plug and Play UPnP messages and the PC must have UPnP enabled Discover Osprey MCA y xi Serial Number x ce F
46. as External Start Stop or External Sync has occurred MCS Acquisition Status The following indicators provide status of the MCS acquisition of the Osprey The descriptions below describe the active state of the indicators User s Manual 7066438 61 Chapter 4 Web Based Status Idle The device is not in acquire Busy The device is in acquire or armed and waiting to start acquire Waiting Acquisition is armed but has not started because waiting for one of several events External Start External Sync or CANBERRA NAIS 2x2 LED stabilized detector performing internal calibration Preset Sweeps Reach Acquisition has stopped due to preset sweeps being reached External Stop An external event has stopped acquisition Manual Stop Acquisition was stopped by pressing Acquire Stop in Genie 2000 Overflow Stop Acquisition was stopped due to MCS channel overflow counts Group 1 Active Device is in acquisition and group 1 is active Group 2 Active Device is in acquisition and group 2 is active Ext Trig Event An external event such as External Start Stop or External Sync has occurred 62 Osprey Universal Digital MCA Tube Base Information Information The Device Information page Figure 30 provides a summary of the device configuration that can be accessed without the need to log in to the device A Username Password Login CANBERRA System Status E E co co Stb Probe Connected Stb Probe R
47. ation Advanced and click Next Select Search for the best drivers in this location and check the Include this location in the search box Browse for the proper path for the USB Drivers from the included CD lt Drive gt Bin Osprey OspreyUSB X86 and click Next Note 64 bit operating system drivers are supplied in the X64 folder These drivers are only supported when custom programming using the SDK Click Continue Anyway on window stating this hardware has not passed Windows logo testing When complete click Finish Do not stop It is required to run the Found New Hardware Wizard a second time Repeat the same steps above Configuring Your PC for the Osprey via USB Follow the steps below to configure your Windows XP PC Note Refer to your operating system documentation for non Window XP configuration steps Connect or leave connected the USB cable from your PC to the Osprey After auto discovery 1s finished 1t may take a brief period of time before the USB connection functions Wait until it appears to complete this process Right click on the My Network Places icon and select Properties This will bring up the Network Connections window Right click on the Local Area Connection with the device name Canberra Osprey MCA Click on Properties Note Record the name of this Local Area Connection for referencing later in step 9 User s Manual 7066438 89 Appendix B Communication Setup
48. can be configured for the SCA1 SCA6 modes mode Only three of the six total SCA counters within the Osprey can drive outputs signals due to the limited number 3 of available output connectors Only ONE SCA can be selected per output connector PHA ACQ OUT The PHA ACQ OUT output signal is TTL compatible Polarity is fixed at positive logic Any combination of GPIO connectors can be configured for this mode The PHA ACQ OUT mode drives the designated GPIO connector s with the status of the PHA acquisition The output will be driven to logic high when PHA acquisition starts and logic low when PHA acquisition stops The output level is TTL compatible and may be used to drive circuitry for acquisition indicators Latency time of the output signal to reflect a change in acquisition status is typically less than 12 5 ns PHA EXT START STOP OUT The PHA EXT START STOP OUT output signal is TTL compatible Polarity is fixed at positive logic Any combination of GPIO connectors can be configured for this mode When in pulse mode the width is 200 ns In this mode the device drives the designated GPIO connector s with either a pulse or a level when the status of the PHA acquisition changes state The output may be used to synchronize the start stop data acquisition of another device The PHA EXT START STOP OUT mode can be configured for Pulsed mode or Level mode Pulsed mode may be used to Start Stop and Start amp Stop the PHA Acquisition unit L
49. ch as H2OSamp up to a total of eight characters Detector Type Use this drop down list to select the type of detector to be used with this MCA this also assigns appropriate default values to the spectrum display and analysis parameters Five choices are available Gamma or X Ray Ge Gamma or X Ray Nal Gamma or X Ray Si Alpha or Beta Particle Si or Other For additional information please refer to the Genie 2000 Operations Manual Input Size This parameter defaults to 1K the number of channels assigned during Device setup for the MCA To use a different memory size use this control to select the size you want to use For instance for Nal spectra you wouldn t want to use more than 1024 channels Out of Service This check box allows you to place this Input temporarily out of service That is it will remain as an entry in your MCA Definition File but will not be available for data acquisition It is meant to be used when the MCA or its front end electronics are temporarily disconnected Osprey Universal Digital MCA Tube Base Saving and Loading the Input Definition Memory Groups This check box allows you to define up to two memory groups each with an input size equal to the selected number of channels Saving and Loading the Input Definition Having completed a definition the next step is to save the file using the Mid Editor s File Save as or Save command e Save As saves the definition to a user
50. ction from a PoE IEEE 802 3af compliant device To apply power to the device please refer to Applying Power on page 17 Note Do not apply power to the Osprey until you are ready to set it up Communication Ports The Osprey system is accessed through communication with a computer Several communications formats are supported the connectors are listed below Communication port setup commands and options are described in the appendix Communication Setup on page 81 Connect the appropriate communication port to host computer The unused communication port should be left unconnected 10 100 T This port connects the Osprey to an Ethernet IP network or directly to a host computer uses the industry standard RJ45 type network jack and pin layout for a networked device Note The factory default communication is using a static IP network connection to the 10 100 T connector See the Quick IP Setup Summary in appendix Communication Setup on page 81 for details LED indicators There are two LED indicators on the Ethernet connector Osprey Universal Digital MCA Tube Base Controls for the Osprey System e LINK Left Will be on to indicate Link is good and blink to indicate activity is present on either transmit or receive activity Link will be Off when no LINK is present e SPEED Right Indicates 10 or 100 Mb s data rate of the port Will be On for 100 Mb s data rate or USB connection and Off for 10 Mb s data rate USB D
51. ctions as part of a whole which is a work based on the Program the distribution of the whole must be on the terms of this License whose permissions for other licensees extend to the entire whole and thus to each and every part regardless of who wrote it Thus it is not the intent of this section to claim rights or contest your rights to work written entirely by you rather the intent is to exercise the right to control the distribution of derivative or collective works based on the Program In addition mere aggregation of another work not based on the Program with the Program or with a work based on the Program on a volume of a storage or distribution medium does not bring the other work under the scope of this License 3 You may copy and distribute the Program or a work based on it under Section 2 in object code or executable form under the terms of Sections 1 and 2 above provided that you also do one of the following a Accompany it with the complete corresponding machine readable source code which must be distributed under the terms of Sections 1 and 2 above on a medium customarily used for software interchange or b Accompany it with a written offer valid for at least three years to give any third party for a charge no more than your cost of physically performing source distribution a complete machine readable copy of the corresponding source code to be distributed under the terms of Sections 1 and 2 above on a medium cus
52. d level when MANUAL Fdisc Mode is selected The range is 0 to 100 where 100 corresponds to approximately 20 of the full scale energy range FDisc Mode Sets the device s Fast Discriminator threshold mode AUTO allows the threshold to be optimized automatically above the system noise level MANUAL allows the threshold to be manually adjusted LTC Mode Sets the amplifier s Pulse Pileup Rejector and Live Time Corrector LTC When PUR is On the pileup rejector and LTC are enabled Off disables the pileup rejector and LTC User s Manual 7066438 45 Chapter 3 System Setup LLD The digital Lower Level Discriminator LLD sets the minimum input acceptance level active only when Manual LLD mode is selected adjustment range is 0 0 to 100 of the spectrum full scale range LLD Mode This adjustment selects Automatic and Manual LLD modes the digital Lower Level Discriminator selects minimum input acceptance level With AUTO select the LLD cutoff is automatically optimized just above the spectral noise threshold MANUAL allows the LLD cutoff to be set manually using the LLD slider bar as a percentage of the full scale spectral size or range The LLD slider bar does not function when AUTO is selected ULD The digital Upper Level Discriminator ULD sets the maximum input acceptance level Range is 0 to 100 The ULD setting is a percentage of the full scale spectral size or range DSP Filter Parameters The DSP Filter
53. d storage of PHA events prior to reaching the PHA preset condition If no stop pulse occurs acquisition and storage will continue until either a Stop command is received or a PHA preset condition is reached After receiving the first Stop pulse subsequent pulses have no effect Start Stop Once the PHA Acquisition Unit is enabled though a software Start command a pulse on this input begins the acquisition and storage of PHA events A second pulse on this input will stop acquisition and storage of PHA events prior to reaching the PHA preset condition If no second pulse occurs acquisition and storage will continue until either a Stop command is received or a PHA preset condition is reached After receiving the second pulse subsequent pulses have no effect Suspend Resume Once acquisition is enabled though a software Start command the Suspend Resume input can be used to suspend or resume storage of PHA events through a TTL compatible DC level For Start Stop and Start Stop modes acquisition and storage of PHA events is synchronized to the leading edge of the incoming pulse For Suspend Resume mode with positive logic polarity selected a TTL high signal allows storage and a TTL low inhibits storage Negative logic polarity reverses the logic AUX CNTR IN This mode is restricted to a single GPIO connector Minimum pulse duration of 100 nanoseconds Polarity is fixed at positive logic The AUX CNTR IN mode enables external use
54. ddress of the device This is a read only field for information purposes and cannot be changed IP Address Defines the IP address of the device The device s IP address can be changed by typing the desired IP address in the appropriate boxes and pressing the submit button It is required to restart the device for this change to take affect This address must be changed to a unique address if multiple Ospreys are connected to same host PC and or multiple devices will be controlled by same Genie 2000 session Default Gateway The default gateway to be used to route those packets not destined for a subnet that the device is directly connected to and for which a more specific route does not exist Subnet Mask This value specifies the subnet masks to be used with the IP interfaces bound to the adapter This value can be any set of valid IP addresses Device Reset When changes have been made to the USB Network Setup press the Submit button For the changes to take affect the device is required to be reset Press the Device Reset button to reset the device immediately or perform additional device parameter changes and reset the device at a later time When the Device Reset button is pressed the device will reset and the Web Status page will refresh in 60 seconds During this time the links in the web page are disabled Verify the new settings in the Device Information page UPnP Setup Refer to Universal Plug and Play on page 86 for UPnP
55. does not cover damage to equipment which has been altered or modified without our written permission or damage which has been caused by abuse misuse accident neglect or unusual physical or electrical stress as determined by our Service Personnel We are under no obligation to provide warranty service if adjustment or repair is required because of damage caused by other than ordinary use or if the equipment is serviced or repaired or if an attempt is made to service or repair the equipment by other than our Service Personnel without our prior approval Our warranty does not cover detector damage due to neutrons or heavy charged particles Failure of beryllium carbon composite or polymer windows or of windowless detectors caused by physical or chemical damage from the environment is not covered by warranty We are not responsible for damage sustained in transit You should examine shipments upon receipt for evidence of damage caused in transit If damage is found notify us and the carrier immediately Keep all packages materials and documents including the freight bill invoice and packing list Software License When purchasing our software you have purchased a license to use the software not the software itself Because title to the software remains with us you may not sell distribute or otherwise transfer the software This license allows you to use the software on only one computer at a time You must get our written permission for an
56. e pulse Recording of the event is delayed until the qualifying signal occurs or the window time expires External GPIO Configuration Selects the functional assignments of the GPIO connectors Refer to the appendix External GPIO Configuration Matrix on page 97 for GPIO configuration selection chart and descriptions Selects the functional assignments of GPIO connectors Genie supports a subset of the total number of GPIO functions 52 Osprey Universal Digital MCA Tube Base System Connections for a Detector System Connections for a Detector This describes a basic system consisting of an Osprey a standard Nal Tl or LaBr3 Ce detector or an Osprey NAIS 2X2 LED stabilized detector and a PC running Genie 2000 Figure 25 Your configuration may vary Figure 25 Typical Osprey System Basic Detector Setup The Osprey can be connected to a variety of detectors The next sections describe how to set up the probe to the Osprey User s Manual 7066438 53 Chapter 3 System Setup 14 Pin Detector Before connecting the USB or Ethernet connector carefully align the keyway and pins on your photomultiplier tube PMT with the 14 pin tube socket base on the Osprey device To ensure correct alignment the PMT has a key which mates with the Osprey s keyway Figure 26 Push the two parts together in a straight motion which should be snug but not difficult to assemble together y h i i Figure 26 Connecting the Osprey to an 14
57. eady HV On HV Ramping Information Device Information Device Setup PHA Acquisition Status MCS Acquisition Status E Cg Co C4 E Ethernet Network Setup Idle Busy Waiting Idle Busy E E USB Network Setu N A PresetTime Reach Presetintegral Reach Preset Sweeps Reach N A N A UPnP Setup C mua External Stop Manual Stop Overflow Stop External Stop Manual Stop Overflow Stop Device Upgrade pn E FPGA Upgrade Group 1 Active Group 2 Active Ext Trg Event Group 1 Active Group 2 Active Ext Trg Event Firmware Upgrade Security Change Passwords Device Information Serial Number Pilot2 Ethernet MAC Address 00 00 AF 00 20 1E Firmware Version 0 00 0911 20 00 Ethernet IP Address 160 84 36 71 FPGA Version 0327 USB MAC Address 00 00 AF 00 20 1F Web Version 0 00 0911 23 00 USB IP Address 0 0 0 0 Figure 30 Summary of Device Information Serial Number The serial number of the Osprey Firmware Version The version of the microcontroller firmware FPGA Version The version of the FPGA design file Web Version The version of the Web Status page Ethernet MAC Address The network card Media Access Control Address A unique number that identifies the Ethernet hardware interface User s Manual 7066438 63 Chapter 4 Web Based Status Ethernet IP Address A unique address assigned to the device that is used to identify and c
58. eags 34 Step 2 Configuring the MCArte 34 Step 3 Configuring the Detector ooooonoccioconocononoconcconoconocono cono nnnn oran r nan nono rrnn ron croacia 36 A RON 37 AS O NTE 37 Ending the DEMO id EAS E LA AE EE ta ici 37 Acquisition Window Adjust Dialogs with Genie 2000 oooonccnnocinoccnonononocnnonnncnanonanorannonnnonn ccoo 38 AMIA A A a a 0 o O ndiaes 39 High Voltage PAra id 43 DSP Gain Parameters a steven biyavs A gobi easeuaenraca E EE 44 DSP Filter Parametros 46 MGS Parametros 47 Acquire Setup with Genie 2000 ccccccccccssessseeseeessecseeessecnsecesecnsecsseesseesseeseeeseeeeeseeeseeeseeeaeeaaes 48 Counting Mod aia 49 PATTIE A E E ER 49 MES Presets iii lid 49 External Control in aida 49 Osprey Universal Digital MCA Tube Base Tip Si VA A dee tea eee scan eta A e A O edo do e 51 Computational Pres tus data 51 COMCIDENCE nt das 52 External GPIO Configura ii id a A A A AA ib 52 System Connections for a Detector cccecccesccessessseesseeseeeceessecesecesecnsecseeeseeeseneseseeeseeeseecaecseenes 53 Basic Detector Setup audi 53 Communication Interfaces cceceseescesecsseeseesecceeseeseceaecaeseceeaecaeeeaeeseceaeeaeseceaecaeseneeseenaeenees 57 4 Web Based Status occiso dean ii 59 System Statu A A A AA A A A a a U2ee 60 PHA Acquisition SAUS accio De 60 MCS AGquisition Status idas lidia 61 Tm fOT iat ON sees AN 63 Device Setren sedate cnesguancocavved angescan sates sa shacsuan sadaesstens aan gadaeom E cal
59. eas 12 MCS EXT START STOP OUT eceeee 14 PHA ACQ OUT onien aani 13 PHA EXT START STOP OUT eee 13 SCA 126 iain lace ip 12 H High voltage settings ooooonconnonincnnccnocnnonnnnnonos 27 43 Incomming Count Rate ICR oooooconicnnncinno os 8 12 Imput settings ooooocnoccnocononcconconcconoconcon eir iris 32 Installing FPGA Miles tao 69 Gone 2000 tenistas 19 new version of firmware oooccocononnconconnconccnnoo 69 MA vtech eee hs hs taste 87 USB na too aes leet EE 88 L LED indicators BUS e poor 7 ia NVA to it tas tel 7 ERA o o e 8 Stabilized probe oooooconncnincnnonioccconocononnnonnnnnnonos 7 LOGIN OM 0 O 59 M MCA Input Definition ooonocnnonnnocinoncnnninncnnnonnnonnos 20 MEGS settings sevi 27 47 MID editor iia oa 20 114 adding an MCA ceceesecsseesseeseeseeeseeseenseens 22 basic concepts OL ooocooncccccccccccononononnnconoconocn noo 21 defining an MCA coconccconnnonncnncnnnconnonnninnos 21 24 deleting an MCA eeceeceesseerseeseeeeeeseeneeees 23 multiple MCA configurations 0 0 0 0 21 saving the definition ceeeeeeeseeeteeneeeees 33 Starting the a leisure ce S 22 using an MCA defintion 21 MID Wizards ee resort aes 33 configuring the detector ceceeeesseereeeeees 36 configuring the MCA uu ceeceesseeseereeteeeeeees 34 entering the MID file name eee eee 37 selecting the MCA eeeeesceeseeseeseesseeneeenes 34 Multiple MCA configurations cooooccccnoncc
60. ed for MCS IN Refer to the appendix External GPIO Configuration Matrix on page 97 for GPIO configuration selection chart and descriptions The FDisc and ROI selections require that the PHA Acquisition Unit has been setup for the correct input size and energy range ROI Start Sets the start channel of the discrimination window used when ROI mode is enabled as the MCS input signal ROI End Sets the end channel of the discrimination window used when ROI mode is enabled as the MCS input signal Note ROI Start and ROI End values are with reference to the PHA input size User s Manual 7066438 31 Chapter 3 System Setup 32 Input Settings The Input command is used to change the name of the Input and set up the structure of its memory via the Define Input screen Figure 12 Some of these commands are not available in the Acquisition and Analysis application Note This window s initial focus is the Cancel button pressing the keyboard s ENTER key after making changes in this dialog box will cancel the changes Be sure to click on the OK button to accept the changes Define Input Input name DETo2 m Input Size Channels DetectorType Gamma or X Ray Nal y 2048 Out of Service El Le 256 2048 Memory groups 1 OK Apply to All Help Figure 12 Define Input Dialog Input Name The default DETnn name is the name displayed here allowing you to easily change it to a more meaningful name su
61. eeeeeseaeseseeesaeetaeesaees 81 Communication Notes s enaena a e ae aa a aad ae a saae as 81 Quick IP Setup Summary id A ARE Oks was eee ect AAA AE a des 82 Direct Setup Connect to Osprey with your PC cccecsceseceteceseceseceeeceeeeeeeeesseesaecnseenseenseens 82 DHCP Setup Changes Optional for IP Network Use ooooonoconocococococnconnnonnconncon nono nonnonnocnonos 84 Firewall Setup for Genie 2000 iii iii iii dais 86 niversal Plug and Play codec An a T a aoada 86 Adding Universal Plug and Play to Your PC cccccecscecsseeseeeseeeceeseecssecnseceseceaeeeeeesneeeeneeaes 87 Setting Up a USB Connection na e A A A a a a A A S 88 Installing the USB DIV td Ed E LA EEE EE E ETE 88 Configuring Your PC for the Osprey via USB cccccccsccsssceteceseceseceeeeeeeeeeseesaeeeseeeseeeaenseeaes 89 Configuring for Multiple Osprey using USB ocooncccicocicononononononnncon ccoo nonnnoconoconncono con ncnnrnnnnonass 93 Verify the USB CONNECION tai A A 94 C Shape AGjuUStments cocineta 95 Optimizing Process ME iii A iaa e dae dada r dat 95 MAMA A A A E a 95 Rise Time and Flat Top Settings ccccccccssecsseceseceseceeceecseeeseeeeseeceseeeseeeseecseecsaeenaeenaeenaeens 96 D External GPIO Configuration Matrix ssssssssssnssunnnnnnnnunnnnnnnnnnnnn 97 E Installation Consideration cccccccccccccccncccncccnnnnnnnnnnnnnnenenennnnos 105 F RTOS License Agreement ccccccccccccccccccccccncncncncncnonenenenenenennnnnnnos 106 L
62. ener O Simple TCP IP Services Q UPNP User Interface Description Displays icons in My Network Places for UPnP devices detected on the nel Also opens the required Windows Firewall ports Total disk space required 56 5 MB Space available on disk 4740 2 MB Figure 37 Selecting the Subcomponent of Network Services 6 Click OK 7 Click Next to start the installation 8 Click Finish to complete the installation After the UPnP feature has been installed and the Osprey s Web based control application is started the UPnP icon will appear in the Windows computer s system tray e Double click on the icon to access My Network Places e Double click on the Osprey icon to launch your browser and run the Web based status application as described in the chapter Web Based Status on page 59 Setting Up a USB Connection This section describes how to set up a USB PC to Osprey communications via USB connection to a Windows PC Windows XP and Vista are supported Installing the USB Driver To install the USB drive place CD with USB drivers in drive Next plug the Osprey into a USB port then follow the steps below 88 Osprey Universal Digital MCA Tube Base Note Setting Up a USB Connection The Found New Hardware Wizard will start When asked if Windows can connect to Windows Update to search for software select No not this time and click Next Select Install from a list or specific loc
63. ensity of the LED is proportional to the incoming count rate GPIO Connectors Three user configurable General Purpose Input Output connectors labeled GPIO 1 GPIO 2 and GPIO 3 provide access to the device s internal acquisition status counters and start stop control The basic functionalities for the GPIO connectors are summarized here For the connector s technical data refer to the appendix Specifications on page 73 For detailed description of each GPIO functionality and any restriction s that may apply refer to the appendix External GPIO Configuration Matrix on page 97 Input Assignments for GPIO Connectors This section describes the input assignment for the GPIO connectors COINC ANTI COINC This mode is restricted to a single GPIO connector Input signal is TTL compatible with minimum pulse duration of 100 nanoseconds Polarity is software selectable for positive or negative logic The COINC ANTI COINC mode is typically used for coincidence or anti coincidence gating of the energy input signal to the PHA acquisition input The Coincidence Anticoincidence signal input polarity and gate delay are software selectable The gate input can be used as a qualifier for the storage of individual energy events The external gate input signal must occur after the energy signal from the detector crosses its noise threshold but before the energy signal is processed The normal processing time for the energy event is the sum of the sha
64. ents Preface uni is v T o a a aaa AAE Ae Saa EEA Ran 1 About this Mi AS A E R 2 Abbreviations and Acronyms sssssesessseseessessessesstsstesosstessesetsestsstsssttssesresstssssseessesteseseessesreses 3 Acquisition EA 3 PHA Acquisition Unit it cierne e E E a E E E Ea 3 MGS Acquisition Unities a a a a a a a R 3 AUX Acquisition UI oros a E aa n ai 4 SCA Acquisition Unit occ cccecccccscessseesceeseeececseecseecsaecssecesecesecsseesseeseeeseeeeeseeeseeeeeessecsseenseesaees 4 ACQUISITION MODES ii A aii 4 PHA Modena aa a eh Satchels 4 MICS Preset M Ode ii iba ies 4 MSS Mod ivia cis AAA headin eet A eet dean A ates 5 Eist MOS A A a a 5 A xillary Counters niiina eorne e a E a ER onl weak siii drena aR aa 5 Single Channel Analyzer SCA c ccccecccccssessseesseeseeeseeeeecnsecesecesecnsecesecseeeseeeeseecsaecsaeenaeseaeeeaeee 5 2 Controls and Connectors sssssssnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnn mannm nnna 6 Panel dica meieni a a a a a a Ga Satay Pao hn ca eek 6 a DAS raD AAE EE ena 7 GPIO Connectors ie a a a a AEE e i Ao 8 Input Assignments for GPIO Connectors cccccccessesscessceseeeeeeeeseeeseecseecsaecaeceseenseeseeneeeseneeses 8 Output Assignments for GPIO Connectors cccecccesscesseeesceeeeescecaeecsaecaecnsecnseenseeeeeeseneeeneeses 12 Multifunction Assignments for GPIO Connectors cccccesceseceseceeeceeeeeseeeseecsaeesaeeaeenseenseens 14 TUBE Socket A a 16 Osprey System PO Westin a a i it Rit
65. ep 3 screen If the name you entered is the same as the name of an existing MID file the system informs you and goes back to Step 3 to let you enter another name The Step 7 Mid FileName defaults to UNTITLED which you ll probably want to change to something more meaningful If the name you enter is the same as that of an existing MID file the system will ask if you want to overwrite the existing file Acquisition Window Adjust Dialogs with Genie 2000 38 The Adjust dialogs are found under the MCA menu in the Gamma Acquisition and Analysis GAA application The datasource for the specific instrument must be opened To open a datasource select File Open Datasource then select the Detector option in the Source box Next select the datasource file and then Open In the following Adjust Screen discussion the MCS Adjust Screen and the associated selection button are available only if MCS was selected as the Acquisition Mode when setting up the MCA controls in the Devices MCA screen of the MID Editor If MCS was not selected the selection button and adjust screen are hidden from view Notes If you get a Required Hardware Unavailable error likely causes are you may have selected the wrong data source for the instrument there is a problem with the communication interface check the cables the instrument power is off or the instrument IP address was incorrectly entered when configuring the device For this case the problem
66. er Signal shaping filters with appropriate shaping times to support the various detectors over a wide range of count rates Multiple counting modes from traditional Pulse Height Analysis PHA and Multichannel Scaling MCS analysis modes to LIST and Multispectral Scaling MSS modes The latter two are of interest when continuous counting intervals are needed for position or time based analyses SCA counters and a single Auxiliary Counter are also supported vi Multiple computer interfaces with routable TCP IP and DHCP network support e 10 100 Base TX Ethernet for fast network connections over any distance up to 100 meters e USB for fast convenient local connections over any distance up to 5 meters Base Line Restoration and Digital Spectrum Stabilization Adjustable digital signal delay for Coincidence timing applications 0 160 us in 0 1 us steps Three general purpose input output interfaces MCX connection for external control Some interfaces include MCS In PHA and MCS Start Stop MCS Channel and Sweep Advance Coincidence Anticoincidence Gating plus general purpose I O connectors Refer to the appendix External GPIO Configuration Matrix on page 97 for a complete GPIO configuration selection chart and descriptions Osprey Universal Digital MCA Tube Base Important Safety Considerations Read A A cE m a Do NI Carefully Indicates warning of mains or high voltage present at output labeled HV Ris
67. er Canberra MCA s where two user defined regions of interest or windows are used to monitor the count rate and control the stabilization The stabilizer algorithm periodically monitors the count rate at the lower window Ciow and the count rate at the upper window Chien then calculates the ratio between the two as Riemp Chign Ciow Rtemp 18 then compared against a previously established reference ratio Ryef and if a significant difference is found a correction value is applied to the signal gain to compensate for the drift User settings for the spectrum stabilizer algorithm include the width of the sampling windows a centroid channel the spacing a reference ratio and correction divider The relationship between the windows spacing and centroid settings are shown in Figure 18 Spacing Centroid Figure 18 Relationship Between Stabilizer Functions User s Manual 7066438 39 Chapter 3 System Setup Stabilizer Parameters The Stabilizer settings screen Figure 19 for the Osprey contains the following controls a o 1 x Stab C HVPS C Gain Filter C On C Hold Help ain centroid m Gain spacing Gain window Gain mode en 10chs_ Achs Off L _ Prev gt a e A Figure 19 Adjust Screen s Stabilizer Settings Gain Centroid The Centroid parameter sets the centroid in channels of the reference peak at the high end of the spectrum that will be used for gain stabilization
68. es 16 Communication Ports ecceeessesecesesseeeececesseeccaecaececeesecsaeeaeeseceaecaeeeeaecaeeeeeesecaeeaeeeeeeaesaeeaeees 16 TOP OQ E REO 16 USB DA A A A E T 17 Controls for the Osprey MM ooscebsidevdaeed aos caevag E obs ce E EAEE ERSE 17 Applying PO WT nia AA AA AAA AA EE eSvadivute devs E EE 17 Factory Reset Control a e n a Ea EE E AE aE Erana ata AE aaRS 18 DV SUSI SUD iii iio 19 The Osprey Digital MCA Tube Base ccccecccesscesseeeseeeeeeseeescecseecsaecnaeceseseeeeeeeseseseaeeeaeecsaeenaees 19 Genie 2000 Analysis Software ccccecccecsecsseesseeseesseceseceseceseceseeseeseeeseaeeeseeeseecseecsaecaecsseenseenaeees 19 Osprey and MID Piles d 20 MCA Input Definition MID Editor oocooocooccconnnonononononononncon ccoo nono nono nono noc nar n rra r rar rr rran ron 20 LA NO 21 Starting the MID Editor ia suet 22 Addie a MEA NAAA AE RAE E A EA AAA a ata ad 22 Deleting a M CA iria ie 23 Defining AMECA dd bi 24 Interpreting the Definition Entry cccccccccscessecsseceeceseceseeseeeseceeeeeeeseceseecseecsaeesaecnseenaeenaeees 24 Device Setpoint sioe eran n EE O E RA O A EA EA bin 25 Par Mt SUN AA EEE AN EN EEA EEE E E EE 27 Saving and Loading the Input Defimition cece ceccceeceesceseeeseecseeeeecsaeetecnsecnseenseeeeeesereeseeeaes 33 ThSMID Wizard a Ad ae Rab aes 33 sim the Wizard ra E A 34 Step 1 Selecting the MCA ccccccccseessecsteceteceeceecseeeseeeeeaeceseeeseeesaecsaeesaecaeenseeseeseeesene
69. et Seeds see ETAR 16 57 F Firewall setup for Genie 2000 0 0 ceeeeeeeeneees 86 Firmware upgrade ccceccesseesseeceeeeeeseeseeeseeerees 69 FPGA Up Stade inicia 69 G Gamma Acquisition amp Analysis oncncnccc 38 hardware verification error 38 required hardware unavailable error 38 Genie 2000 configuring spectrum refresh rate 19 firewall setup fof oooooocccnicniconocnconoconccnnccnnonnos 86 E i a te Miser cess 19 GPIO CONNECHOLS cccceceesessececeeeceenseaees 8 52 97 input assigments ocoooccocconoconononncnonncononononannninnns 8 multifunction assignments cecceeeeeee 14 Output aSSIQGMMENHS ceceseesseeseereeeeeeeeeees 12 GPIO input assignments 113 AUX GN TRIN sodan ita 11 COINC ANTICO N Coooooonnoncnnonnoncnncnnnncnncnninono 8 EXTSYNCIN tete cin id e ai 11 INPUT LEVEL SENSE eee eerie 12 MCS EXT START STOP IN eee 9 MCS EXT SWP ADV uo iman 10 MES IN coca 9 PHA EXT START STOP IN eee 10 GPIO mulifunction assignments AUX CNTR IN and MCS IN eee 14 MCA PROBE VO nyere aan S ARRE 15 MCS EXT SWP ADV and EXT SYNC IN 14 PHA EXT START STOP IN and MCS EXT START STOP IN ue ceecceccnseteeseneeseeeeneens 15 PHA EXT START STOP IN and MCS EXT START STOP OUT renuncar 15 PHA EXT START STOP OUT and MCS EXT START STOP IN nnn eai 15 PHA TEST INe mne ea iaei 16 GPIO output assignments EXT SYNC OUT neciorerannciarereinn ni 13 Rima sain arte B
70. ev a millisec 4 ile Help C seconds fo A ROI Figure 23 Adjust Screen s MCS Settings Dwell Range Sets the units for the dwell time value The unit s selection can be made for microseconds milliseconds or seconds Dwell Value Sets the dwell time value in units specified by the Dwell Range control The Osprey supports a dwell value ranging from 1 microsecond to 999 seconds in increments of 1 microsecond Disc Mode The Discriminator Mode control establishes the input signal to the MCS Acquisition Unit Selecting FDisc enables the MCS s fast discriminator mode where all incoming events above the Fast Discriminator threshold are counted Selecting TTL enables the MCS s TTL mode where all TTL events as seen at the GPIO connector selected to accept the MCS IN signal to be counted Selecting ROI enables the ROI discrimination mode meaning that all incoming events processed by the DSP that fall within the selected discrimination window are counted If TTL mode is selected then the External GPIO Configuration in the Acquire Setup dialog must have one GPIO connector selected for MCS IN Refer to the appendix User s Manual 7066438 47 Chapter 3 System Setup External GPIO Configuration Matrix on page 97 for GPIO configuration selection chart and descriptions ROI Start Sets the start channel of the discrimination window used when ROI mode is enabled as the MCS input signal ROI
71. evel mode may be used to Suspend Resume the PHA Acquisition unit Latency time of the output signal to reflect a change in acquisition status is typically less than 12 5 ns EXT SYNC OUT The EXT SYNC OUT output signal is TTL compatible Polarity is fixed at positive logic Any combination of GPIO connectors can be configured for this mode The EXT SYNC OUT mode can provide an external signal to synchronize the Osprey s MSS AUX SCA and List TList Acquisition Units to another device See EXT SYNC IN description for more information on synchronization operation for the different Osprey acquisition modes User s Manual 7066438 13 Chapter 2 Controls and Connectors MCS EXT START STOP OUT The MCS EXT START STOP OUT output signal is TTL compatible Polarity is fixed at positive logic Any combination of GPIO connectors can be configured for this mode When in pulse mode the width is 200 ns In this mode the device drives the designated GPIO connector s with either a pulse or a level when the status of the MCS acquisition changes state The output may be used to synchronize the start stop data acquisition of another device The MCS EXT START STOP OUT mode can be configured for Pulsed mode or Level mode Pulsed mode may be used to Start Stop and Start amp Stop the MCS Acquisition unit Level mode may be used to Suspend Resume the MCS Acquisition unit Latency time of the output signal to reflect a change in acquisition status is typ
72. f device during update process This can make the device unusable Directions for FPGA Upgrade To install a FPGA upgrade 1 2 Under Device Upgrade click on the FPGA Upgrade link Click on the Browse button or Choose File and select appropriate file supplied for upgrade Type the checksum value in the checksum box This value will be supplied from the factory with the FPGA file Click the Upload button When the checksum has been verified press the Apply button The installation can take 2 minutes The Web Status page will refresh in 120 seconds During the FPGA upgrade time the links in the web page are disabled Verify new version of FPGA has been installed in the Device Information window Exit web page when complete User s Manual 7066438 69 Chapter 4 Web Based Status 70 Directions for Firmware Upgrade To install a firmware upgrade 9 10 11 12 13 14 15 16 17 Under Device Upgrade click on the Firmware Upgrade link Click on the Browse button or Choose File and select appropriate file supplied for upgrade Type the checksum value in the checksum box This value will be supplied from the factory with the firmware file Click the Upload button When the checksum has been verified press the Apply button The installation can take to 2 minutes The Web Status page will refresh in 120 seconds During the firmware upgrade time the links in the web page are disabled
73. he Osprey s full memory size The memory size settings range from 256 to 2048 channels Computational Preset Computational Presets are available only when MCA Acquisition Mode was previously configured for PHA mode in the MID setup Otherwise this option will be disabled grayed out These presets stop acquisition when a computed value you specify is reached When a computational preset is defined the chosen time preset is still active The Acquire Stop command is issued by the preset that is reached first If you want to use a computational preset alone set the time preset to 0 which means forever This insures that the computational preset will be reached first Computational Presets are mutually exclusive with each other but any one can be combined with either a live time or real time preset None Selecting None disables all computational presets Only the time preset will be used in this case Integral Area and Counts Each of the three computational presets Integral Area and Counts applies to a specified ROI To use any computational preset you must specify its Value the ROI s Start Channel and its Stop Channel The Start and Stop Channel values will default to the current computational preset if there is one otherwise the Start value will be 1 and the Stop value will be the spectrum s highest channel number ROI Selection You can enter the Start and Stop limits manually or by using the Current button in
74. he stabilizer as the ratio to maintain between the two windows ratio upper window lower window For instance a value of 1 000 would be appropriate for a pure Gaussian peak Gain Rate Div The Gain Rate Divider is a factor by which the level of correction applied to the system gain is reduced by This value in effect determines the aggressiveness of the stabilization algorithm The algorithm becomes less aggressive as the correction divider is increased Ratio Mode The Ratio Mode can be set for Manual or Automatic default In Manual mode the reference ratio parameter must be manually entered or supplied by a client application In Automatic mode the reference ratio is calculated and managed automatically by the device For normal operation the Ratio Mode should be set to Automatic Reset During the normal course of operation if the stabilization algorithm attempts to set a correction value that is beyond it s 10 allowable range the device will assert either an over range or under range fault depending on the direction of the correction value Additionally the device will switch the stabilizer mode from On to Hold Such a fault may be an indication of faulty electronics and thus requires operator intervention The fault will remain asserted until a the operator acknowledges the fault by pressing the Reset or the Stabilizer Mode is turned to Off Typical Setup Sequence When the stabilizer in the Osprey is turned On
75. ibes using the Osprey Web Based Status page for configuration using a conventional IP network You must access the Osprey via one of the default methods in order to make parameter changes within the Osprey Factory Settings for the Osprey The factory default settings for each network connection method are Ethernet oc c svexeres 10 0 0 3 USB cascostilia td 10 0 1 4 The subnet mask value for each of the above is 255 255 255 0 In order to access the Osprey for the first time you must decide on which method of network communication you intend to use e Direct Ethernet using the red Crossover cable from your PC to the Osprey e USB Connection Communication Notes If the following parameters are changed the device needs to be restarted for changes to take effect User s Manual 7066438 81 Appendix B Communication Setup 1 TFTP Enable Disable 2 Web Server Enable Disable 3 UPnP Enable Disable 4 UPnP TTL Quick IP Setup Summary Whether your IP network employs DHCP or provides a specific IP address follow these steps to change the factory presets to the IP settings you require CAUTION Due to the nature of configuring Network parameters A on a Windows PC there is no undo for some steps as they will first remove your existing network settings It is suggested that you first write your existing settings down before deleting or changing settings in your efforts to connect with the Osprey This direct c
76. ically less than 12 5 ns Multifunction Assignments for GPIO Connectors To maximize the use of a single GPIO connector the Osprey provides several multifunction assignments in its GPIO configuration Multifunction assignments combine the functionality of two independently configurable functions into a single GPIO connector Multifunction assignments are limited to a single GPIO connector additionally for input type functions neither of the combined function can be selected separately on a different GPIO connector The multifunction assignment is not supported using Genie 2000 software AUX CNTR IN and MCS IN This mode combines the AUX CNTR IN and MCS IN into a single GPIO connector the device internally connects the GPIO connector to the input of the AUX Acquisition Unit and MCS Acquisition Unit to provide a common signal to both acquisition units Refer to the individual functions for more details and any restrictions to may apply This function is limited to a single GPIO connector additionally neither function can be selected again on any other GPIO connector MCS EXT SWP ADV and EXT SYNC IN This mode combines the MCS EXT SWP ADV and EXT SYNC IN into a single GPIO connector the device internally connects the GPIO connector to the input of the SYNC Module and to the external sweep advance logic of the MCS Acquisition Unit Refer to the individual functions for more details and any restrictions that may apply This function is l
77. ication Setup Verify the USB Connection To verify the USB connection and to access the Osprey system 1 Disconnect your Ethernet cable connection if it is connected 2 Connect the USB cable from your PC to the Osprey 3 Open your Internet browser on your PC 4 Inthe URL line type in 10 0 1 4 and press Enter to connect This will open the Osprey Web Status page 94 Osprey Universal Digital MCA Tube Base Optimizing Process Time C Shape Adjustments This appendix describes how to adjust the rise time and the flat top settings Optimizing Process Time The digital filter employed in the Osprey MCA has a Triangular Trapezoidal weighting or shaping function Shaping Shaping is adjusted by selecting the Rise Time and Flat Top which determine the Trapezoid pulse shape and optimizes performance for the specific Scintillator spectral energy range and count rate Note For more information on count rate performance refer to Canberra s Application Note Performance of Digital Signal Processors for Gamma Spectroscopy Please contact your sales representative to request a copy Rise Time The Rise Time sets the noise filtering characteristics of the Digital Filter Flat Top The Flat Top allows for the light collection time of the particular scintillator Independent adjustment of the flat top allows the shaping function to be optimized for scintillator with long light collection time without a large increase in the overal
78. ie C Coincidence 09 PHA Acq Status out pos logic Y LA Counts Stop Chen 1024 of a 10 ICR out pos logic 256 1024 Polarity 0 160 17 Ext PHA Start Stop input ROI Selection z Current Positive J 21 Ext MCS Start Stop input asas 27 Ext Start Stop PHA MCS input Canca Hep Figure 24 Acquisition Setup Controls in Genie 2000 Refer to your Genie 2000 Operations Manual for additional information on these Genie 2000 settings if required 48 Osprey Universal Digital MCA Tube Base Acquire Setup with Genie 2000 Counting Mode Select the radio button for the counting mode desired e PHA mode of Pulse Height Analysis is automatically enabled from the Acquire Setup screen e MCS mode will be available if the MCA Acquisition Mode was previously configured for MCS Input 2 in the MID setup Time Preset For PHA counting mode Live Time and Real Time selections enabled and set in seconds minutes or hours MCS Presets For MCS counting mode Preset Sweep Counts External Control External Start and Stop signals arriving at the GPIO connector selected to accept the signal can be used to control data acquisition Four modes of External Start Stop control are supported plus None and the polarity of the control input is selectable A fifth option None is provided which disables External Start Stop control Initially External Start Stop control is disabled Channel Advance and Sweep Advance options for MCS c
79. igure 7 MID Plug and Play Discovery of Osprey 26 Osprey Universal Digital MCA Tube Base Defining an MCA Parameter Settings This section discusses the specific settings for the Osprey in the MCA Definition You can change any of them from the MID Editor via the Settings menu Note MCS will be available only if the MCA Acq Mode under Devices was previously configured for MCS otherwise it is grayed out MCA Settings This device has no adjustable controls in MID editor Stabilizer Settings This device has no adjustable controls in MID editor High Voltage Settings The High Voltage command opens a screen that allows you to adjust the High Voltage Power Supply settings Figure 8 High Voltage Supply for input DETO1 Range Voltage limit Voltage 1300v y 1300 0v oov Ok 44 posta ca Pe gt 0 1300 0 1300 x seo e Figure 8 The High Voltage Settings Note This window s initial focus is on the Cancel button pressing the keyboard s ENTER key after making changes in this dialog box will cancel the changes Be sure to click on the OK button to accept the changes Range The Osprey supports a voltage range of 1300 volts This setting is not adjustable Voltage Limit The Voltage limit control establishes the HVPS s maximum output voltage within the selected range It must be set before the Voltage control is adjusted User s Manual 7066438 27 Chapter 3 System Setup
80. imited to a single GPIO connector additionally neither function can be selected again on any other GPIO connector Osprey Universal Digital MCA Tube Base GPIO Connectors PHA EXT START STOP IN and MCS EXT START STOP IN This mode combines the PHA EXT START STOP IN and MCS EXT START STOP IN into a single GPIO connector to provide a common signal that can be used to synchronize the Start Stop Start amp Stop and Suspend Resume capabilities of the PHA and MCS Acquisition units Refer to the individual functions for more details and any restrictions that may apply This function is limited to a single GPIO connector additionally neither function can be selected again on any other GPIO connector PHA EXT START STOP OUT and MCS EXT START STOP IN This mode combines the PHA EXT START STOP OUT and MCS EXT START STOP IN functionality into a single GPIO connector to provide a synchronization signal from the PHA Acquisition Unit into the external start stop logic of the MCS Acquisition Unit When this mode is selected the signal at the designated GPIO connector can further be used to drive other logic such as the counter logic or external start stop logic of other Osprey devices Refer to the individual functions for more details and any restrictions that may apply This function is limited to a single GPIO connector additionally the MCS EXT START STOP IN cannot be selected again on any other GPIO connector PHA EXT START STOP IN and MC
81. indow shown in Figure 2 Ba MCA Input Definition Editor local Untitled xl File Database Edit Devices Settings Summary Help MCA Input Size ADC MXR Stab Amp HY Gain Figure 2 The MID Editor Window To use the MID Editor you build the MCA Definition list and you may then add to or delete the desired MID files from the list Note The phrase local Untitled in the title bar means that the MID Editor is connected to the local VDM and that no file is currently open this is the default condition in a non networked environment Adding an MCA The Edit menu at the top of the MCA Input Definition Editor s main window is used to add MCA hardware to or delete MCA hardware from an MCA Input Definition To add an MCA 22 Osprey Universal Digital MCA Tube Base MCA Input Definition MID Editor 1 From the Edit menu select Add MCA 2 The Add MCAs to Definition Table dialog box opens This dialog contains all available MCAs 3 Select Osprey MCA from the list of available MCAs by clicking on the symbol next to Network MCAs Figure 3 Use this selection for both Ethernet and USB connections 8H Network MCAs SY AM EF AM DSP E DSA net 38 DS4 2000 8 Falcon 5000 using 12K F5K EF Lynx MCA 8 Multiport ll Net amp USB MCAs A R5232 MCAs m Plug in Board MCAs IFFF AAR EA 00 48 Figure 3 Adding an Osprey MCA 4 Click on Add to add an Osprey MCA to the MCA I
82. ing power User s Manual 7066438 105 Appendix F RTOS License Agreement F RTOS License Agreement The FreeRTOS org source code is licensed by the modified GNU General Public License GPL text provided below The FreeRTOS download also includes demo application source code some of which is provided by third parties AND IS LICENSED SEPARATELY FROM FREERTOS ORG For the avoidance of any doubt refer to the comment included at the top of each source and header file for license and copyright information This is a list of files for which Richard Barry is not the copyright owner and are NOT COVERED BY THE GPL 1 Various header files provided by silicon manufacturers and tool vendors that define processor specific memory addresses and utility macros Permission has been granted by the various copyright holders for these files to be included in the FreeRTOS download Users must ensure license conditions are adhered to for any use other than compilation of the FreeRTOS demo application The uIP TCP IP stack the copyright of which is held by Adam Dunkels Users must ensure the open source license conditions stated at the top of each ulP source file is understood and adhered to The lwIP TCP IP stack the copyright of which is held by the Swedish Institute of Computer Science Users must ensure the open source license conditions stated at the top of each IwIP source file is understood and adhered to All files contained within the Free
83. ing the logic status at the respective MCX connector through the GPIO1_ Input GPIO2 Input or GPIO3 Input parameters This feature is available regardless of the function selected and will reflect the state of the GPIO pin whether it is configured as an output or input Any GPIO pin can be configured for INPUT LEVEL SENSE mode The INPUT LEVEL SENSE function should also be selected when not using the respective MCX connector to conserve power OUTPUT LEVEL 0 01 GPIO OUT 0 Function 01 configures the connector pin for output mode and drives the output to logic 0 Any GPIO pin can be configured for OUTPUT LEVEL 0 function OUTPUT LEVEL 1 02 GPIO_OUT_1 Function 02 configures the connector pin for output mode and drives the output to logic 1 Any GPIO pin can be configured for OUTPUT LEVEL 1 function AUX CNTR IN 03 AUXCNT_IN Function 03 configures the connector pin for input mode The AUX CNTR IN function directs the respective GPIO connector to accept an external user supplied input pulse to the AUX counter The Osprey supports a single AUX counter Polarity is fixed to active high The AUX CNTR IN selection is limited to a single GPIO connector Minimum pulse width is 100 ns This function is not supported in Genie 2000 MCS EXT SWP ADV 05 MCSEXTSWP_IN Function 05 configures the connector for input mode The MCS EXT SWP ADV function directs the respective GPIO connector to accept
84. irmware Upgrade Security Change Passwords Figure 29 Osprey s Web Based Status Page User s Manual 7066438 59 Chapter 4 Web Based Status Username and Password To log on to the device you will need a user name and password The default Osprey Username is administrator and the default password is password This log on provides administrative privileges and allows changes to all functions Click on the Login button to begin Refer to Security on page 71 for directions on changing the administrator password System Status The System Status indicators provide status of Osprey NAIS 2X2 LED stabilized detector if installed and high voltage power supply Stb Probe Connected and Stb Probe Ready The status indicators of the CANBERRA NAIS 2x2 temperature stabilized detector if installed e Stb Probe Connected Green indicates the CANBERRA NAIS 2x2 LED stabilized detector is connected to the Osprey e Stb Probe Ready Green indicates the CANBERRA NAIS 2x2 LED stabilized detector is stabilized and within its stabilization range If the indicator is white when the detector is connected the detector is not within its range and acquisition will be inhibited by the Osprey H V On and H V Ramping The status indicators of the high voltage power supply e H V On Green indicates the high voltage power supply is on e H V Ramping Green indicates the high voltage power supply is either ramping up or down
85. is powered on and in the process of initialization This state occurs when power is first applied Blinking Green Instrument is acquiring data Steady Green Instrument is powered on and ready for data acquisition Steady Red Signals a self diagnostic error occurred during initialization and the Osprey is not ready for data acquisition Blinking Red Signals a factory default operation in process LED is Off Instrument is not receiving power HV Stabilized Probe A multicolor LED indicating the state of the high voltage power supply or NAIS 2X2 LED stabilized detector if such detector is connected to the Osprey Off High voltage supply is Off Blinking Green High voltage supply is On and ramping up to its programmed voltage When an NAIS 2X2 LED Stabilized Detector is connected indicates the detector is performing its internal calibration and therefore not ready to acquire data Steady On Green High voltage supply is On and has reached its programmed voltage When an NAIS 2X2 LED stabilized Probe is connected indicates that the detector is operating properly Steady On Red An error such as a HVPS fault has occurred or a fault condition exists within an NAIS 2X2 LED stabilized detector User s Manual 7066438 7 Chapter 2 Controls and Connectors ICR A green LED for Incoming Count Rate llluminates each time the instrument processes an incoming signal through the PHA acquisition unit The int
86. ise that contradict the conditions of this License they do not excuse you from the conditions of this License If you cannot distribute so as to satisfy simultaneously your obligations under this License and any other pertinent obligations then as a consequence you may not distribute the Program at all For example if a patent license would not permit royalty free redistribution of Osprey Universal Digital MCA Tube Base Optimizing Process Time the Program by all those who receive copies directly or indirectly through you then the only way you could satisfy both it and this License would be to refrain entirely from distribution of the Program If any portion of this section is held invalid or unenforceable under any particular circumstance the balance of the section is intended to apply and the section as a whole is intended to apply in other circumstances It is not the purpose of this section to induce you to infringe any patents or other property right claims or to contest validity of any such claims this section has the sole purpose of protecting the integrity of the free software distribution system which is implemented by public license practices Many people have made generous contributions to the wide range of software distributed through that system in reliance on consistent application of that system it is up to the author donor to decide if he or she is willing to distribute software through any other system and a licensee canno
87. iting for the stabilized detector to become ready if one is present or 2 waiting for the external suspend resume signal to resume PHA acquisition if the external start stop logic has been configured for level mode Multiple GPIO connectors can be configured for the PHA ACQ OUT function to extend the same output to multiple connectors User s Manual 7066438 99 Appendix D External GPIO Configuration Matrix Function Name Description ICR 10 ICR_OUT Function 10 configures the connector for output mode Selecting ICR function directs the Osprey device to drive the GPIO connector output with its Incoming Count Rate pulses The ICR pulses are derived from the raw PHA energy events processed by the Fast Discriminator hardware and are not affected by the LLD ULD window settings The approximate ICR count rate can also be read by client applications through the Input_CountRate parameter Multiple GPIO connectors can be configured for the ICR output function to extend the same output to multiple connectors SCA1 SCA2 SCA3 SCA4 SCAS SCA6 11 SCA1_OUT 12 SCA2 OU 13 SCA3_OU 14 SCA4 OU 15 SCAS_OU 16 SCA6_OU T T T T T Functions 11 through 16 configures the respective GPIO connector for output By selecting SCAn function on a GPIO connector pulses from energy events that falls within an SCA s energy window and counted by the internal SCA counter are also exposed extern
88. k of electrical shock if covers are removed Caution risk of danger Refer to documentation for detailed explanation of caution symbol wherever marked Product complies with appropriate current EU directives Example of Cue mark Product complies with appropriate current FCC UL CSA 61010 1 directives User s Manual 7066438 vii Note viii Osprey Universal Digital MCA Tube Base 1 Introduction The Osprey is a high performance fully integrated multi channel analyzer MCA tube base that contains everything needed to support scintillation spectrometry Designed for both laboratory and field use this one compact unit contains a high voltage power supply HVPS preamplifier and a full featured digital MCA Osprey can be controlled through either USB or Ethernet with no need to purchase two separate units an industry first USB or Ethernet there is only one cable connecting the Osprey to the control and data acquisition system For desk top applications power and all communications are handled by a USB 2 0 port In situations where networking and or remote access are desired the Ethernet 10 100T port can be used which provides power and communications via power over Ethernet PoE An example of using Osprey s networking capabilities is setting up a radiation monitoring system with multiple unattended detectors in remote locations Ethernet can also be used in desk top applications instead of USB if desired Cou
89. l processing time Guard Time The Guard Time GT multiplier rejects trailing edge pileup in the event of detector preamp signal anomalies The PUR guard sets the pileup reject interval which is defined by GT x Trisetime Trlattop User s Manual 7066438 95 Appendix C Shape Adjustments Rise Time and Flat Top Settings Table 1 lists Osprey rise time and flat top settings for common scintillators Table 1 Settings for Other Common Detectors Detector Rise Time Flat Top us Scintillation Nal T 1 0 1 0 LaBr 1 0 1 0 Refer to the specific Scintillation Detector User s Manual for the recommended shaping time 96 Osprey Universal Digital MCA Tube Base Optimizing Process Time D External GPIO Configuration Matrix Three user configurable General Purpose Input Output connectors labeled GPIO 1 GPIO 2 and GPIO 3 provide access to the device s internal acquisition status counters and start stop control The detailed description of the GPIO functionality and any restriction s that may apply are described in this appendix Each GPIO connector has an internal 10K ohms pull up resistor that becomes enabled when the connector is configured for input mode Table 2 below describes all user configurable functions Some functions are available through client applications such as Genie 2000 while others are only accessible through custom applications Please refer to the mcaSDK Communication Software Development Kit documentation
90. lied external coincidence or anti coincidence signal for gating the energy input signal to the PHA channel Coincidence or Anti coincidence mode in the device must be selected through Input_CoincGateMode parameter polarity through the Input_CoincGatePolarity and delay through the Input_CoincGateDelay parameters The COINC ANTI COINC function is limited to a single GPIO connector MCS IN 08 MCSTTL_IN Function 08 configures the connector for input mode The MCS IN function directs the respective GPIO connector to accept a user supplied external TTL signal for MCS counting The MCS Channel in the device must be configured to accept external TTL signals through the Input_DiscMode parameter to enable counting of external pulses Logic polarity of the MCS IN signal is fixed at Active High Counting takes place on the leading edge of the pulse The MCS IN function is limited to a single GPIO connector PHA ACQ OUT 09 PHAACQ OUT Function 09 configures the connector for output mode Selecting PHA ACQ OUT function directs the Osprey device to drive the GPIO connector logic output to active high when the device s PHA acquisition is enabled and inactive low when the device s PHA acquisition is disabled Logic polarity for PHA ACQ OUT is fixed at active high The PHA ACQ OUT signal will remain active as the PHA acquisition becomes temporarily suspended by either of the following conditions 1 wa
91. lizer The window width should provide for sufficient counting statistics but exclude interference from adjacent peaks The spacing should provide sufficient separation between the sampling windows to strategically position the windows on the peak where a change in data rate will result in maximum effect detected by the algorithm such as on the shoulders of the peak Spacing values that are approximately 50 of the FWHM and window width that are approximately 80 of the FWHM are typical settings If Using Canberra s Genie Gamma Analysis application the FWHM can be read directly from the Marker Info page provided that the left and right markers surround the reference peak Please note that the value reported by Genie is in energy units and manual conversion to channels is necessary For most applications the Ratio Mode should be set to Auto The Auto mode directs the stabilization algorithm to automatically calculate the reference using the given parameters Manual mode should be used to allow a client application to calculates the reference and pass it to the Osprey The Rate Divider in most cases can be set to 2 or 4 for a typical Nal detector Default setting is 2 which translates to a correction step size of approximately 0 6 volts Each step increase of the Rate Divider setting will reduce the size of the correction by half and each step decrease will increase the size of the correction by two Please note that if the correction step size is
92. logs with Genie 2000 Coarse Gain This adjustment sets the device s coarse gain It s best to choose the highest Fine Gain which combined with the Coarse Gain will produce the total desired gain The Coarse gain allows selections of x1 through x8 The Coarse Gain cannot be adjusted when the Spectrum Stabilizer is active Fine Gain This adjustment sets the device s Fine Gain multiplier The adjustment range is x1 to x5 The combination of Coarse and Fine Gain sets the overall system gain to match the requirements of the detector and energy application overall gain is continuously variable from x1 to x40 The Fine Gain cannot be adjusted when the Spectrum Stabilizer is active PUR Guard Sets the device s Guard Time GT multiplier to reject trailing edge pileup in the event of detector preamp anomalies The PUR guard sets the pileup reject interval which is defined by GT x Trisetime T fattop Offset The Offset adjustment sets the device s digital offset in channels The digital offset shifts the memory assignment of the device s conversions either up or down depending on the sign and value of the offset A positive offset value shifts the spectrum by the amount of the offset in upward direction A negative offset value shifts the spectrum by the amount of the offset in downward direction The Offset cannot be adjusted when the Spectrum Stabilizer is active FDisc Setting Sets the device s Fast Discriminator threshol
93. luded only once in a given definition file and each MCA in that file must have a unique name and or IP address Building an MCA Definition Building an MCA Definition means e Selecting the MCA to be used for each input through the Device Menu To do so you ADD the MCA to the MID Editor e Defining the operating characteristics and modes for each MCA through the Settings Menu e After your desired settings for this MCA Definition have been achieved Saving the MCA Input Definition as a MID file We ll discuss how to add and delete the MID editor s MCA entries and will explain what the definition entry consists of and how to build an MCA Definition list User s Manual 7066438 21 Chapter 3 System Setup Using the MCA Definition Files To use an MCA Definition first load that MID file into the VDM s internal MCA Runtime Configuration Database From that point on all MCA operations will use the configuration information that was stored in the Definition File To change to a new configuration all you have to do is replace the database s contents with a new file Starting the MID Editor You will use the MID Editor to work with at least one definition file for your device Start the MID Editor by double clicking on its icon in the Genie 2000 Program Group or by selecting the desktop icon if provided or from the Start menu select Programs GENIE 2000 MCA Input Definition Editor The result will be the application w
94. mum pulse width for inputs gt 50 ns all inputs have software selectable polarity e Coincidence Anti coincidence e PHA External Start Stop Start Stop Mode Start Only Stop Only and Start and Stop or Suspend and Resume Mode can also be an output to control other devices User s Manual 7066438 73 Appendix A Specifications 74 MCS External Start Stop Start Stop Mode Start Only Stop Only and Start and Stop or Suspend and Resume Mode can also be an output to control other devices External Time Sync can be an input or an output to control other devices for the following modes List Sync rate from external source or master to sync time stamps of events MSS Sync from external source or master to advance to next spectral group Aux Counters and SCA Counters Sync can be used to control the start of interval timer and synchronize the interval timer at each sync event Aux Counter In Auxiliary Counter Input MCS Input External MCS input TTL pulse MCS Channel Advance External MCS Channel Advance TTL pulse MCS Sweep Advance External MCS Sweep Advance input TTL pulse SCA Outputs Up to three each of these outputs can be selected from one of the six internal SCAs ICR Out Incoming count rate output Acquisition Out Acquisition status General Purpose Input Output output signal to drive external devices or input signal to monitor external device s status Elect
95. n and the ADC Reference Control x1 to x40 ADC ADC 14 Bit 20 MHz Sampling LLD 0 to 100 of Full Scale software programmable ULD 0 to 100 of Full Scale software programmable Detector Voltage HVPS 0 to 1300 V dc 100 V s ramping on power up and down Shaping DSP Based Trapezoidal shaping filter operating at 80 MHz Rise Time 0 2 us to 5 us in 200 ns steps Default 1 us for Nal detector Flat Top 0 to 3 us in 100 ns steps Default 1 us for Nal detector Digital Spectrum Stabilization Support for a stabilization source for non stabilized detectors Support of CANBERRA NAIS 2x2 temperature stabilized Nal probe BASE LINE RESTORER Automatic with provision for adjustable BLR Fast Discriminator Threshold Automatic with provision for adjustable FDisc PUR GUARD Programmable guard time 1 1 to 2 5 times shaping High Voltage Power Supply Output is current limited and short circuit protected HVPS OUTPUT 0 1300V at 300 HA max RIPPLE 1 mV ACCURACY 3 Full Scale User s Manual 7066438 77 Appendix A Specifications SETTING RESOLUTION 14 bit 1 16 384 Indicators Three indicators e BUSY e Status HV Stabilized Probe e ICR Detectors e 14 pin scintillation detector e CANBERRA NAIS 2x2 temperature stabilized Nal probe Power e Main power will be supplied by either the USB port or IEEE 802 3af compliant Power over Ethernet PoE e Power consum
96. ncononccononinonccnnons 57 USB 57 Communication ports 10100 Dir 16 USB Dil 17 Connecting directly t d PC is sick coi eR es 57 82 multiple Osprey s using USB 93 to a L4 pin probe ee ceeceseeeeeseeeeeeeeeeeeees 54 tO a 8 pin probe ooooonoccnoconononccconccononnnononinnonanonos 56 to a ethernet netwo TKk oooooconcnnnnincnincnncncnnnnnnnnos 57 toa USB Bubs vise teee Ts testi elie trans 57 Correcting a fault cece ceecescceseeeteeesecseeeeeeees 18 User s Manual 7066438 D Data acquisition controlling 49 Default username and password ceee 59 Defining ME Arean a A 21 24 Deleting an MCA estate 23 Device setup ethernet ieonta O ken 65 for th MCAS Sormenean ana naa 25 PLP to da te Ln dd Do 65 USB metWorkasiinioo rosa 65 Device stetup Web page ooooocccnoonocccocnooncnnncanocnnoo 65 Device upgrade Web pag oooooonccincnionnoonconnconocnnoo 68 DEC PeSCtupis td eta 84 Digital dl A iii 95 flat top SEtLIMBS oooooconocnoccnonnononcnncnononacnnonn nos 96 rise time settings ooooononnoonnonnonnconcconoconcnnnnn noo 96 E EN 95 Discovering the Osprey ooooooccncnncnincnocnnnnnnno 26 34 DSP filter settings ceceeseesceeseeereeeeeeereees 30 44 DSP gain settings 28 44 E Entering detector input NAME eeeeeeseeteeeeeeeees 36 IP address UPnP name cccceeeeee 26 34 MID file name ee eeeecseeeeceeeeeeeeeeeeneees 37 password and username c ceceeeseeeeeeeees 59 Ethern
97. network connections and other system affecting concerns are also introduced in this section Specific Osprey setup parameters settings and details are provided in the Web Based Status Spectral analysis is performed using the Genie 2000 system Acquiring input data using the Osprey can be controlled from the Genie 2000 or from your PC using the programming libraries The Osprey Digital MCA Tube Base The Osprey is a low power solid state device that does not employ a fan so it operates silently Its location is likely dictated by the placement of other detection equipment The Osprey unit is controlled by another device using one of several communication methods or options In addition to the Osprey Digital Tube Base you ll receive e Single port PoE injector This provides power to device when operating over Ethernet e This user s manual e Ethernet and USB communications cables e MCX to BNC cables for GPIO use Genie 2000 Analysis Software The Osprey requires Genie 2000 Basic Spectroscopy Software version 3 2 1 or later for analyzing spectra Refer to the Genie 2000 Operations Manual for operating information Installing Genie 2000 on Your PC To install the optional Genie 2000 software on your PC refer to the documentation provided with the Genie 2000 software Genie 2000 software installation is covered in the appendix Software Installation of the Genie 2000 Operations Manual User s Manual 7066438 19 Chapter
98. nput Definition Editor list Y ou can add as many MCAs to the definition as are necessary for your system highlight each MCA and then click the Add button to add them to the MCA Input Definition Editor list 5 When you ve finished adding MCAs click on the Done button Deleting an MCA If you want to remove an MCA that you have added to the definition you can do it easily by 1 Selecting the table entry you want to delete 2 Select Edit Delete MCA to open the Delete MCA dialog box Figure 4 Click on OK or click twice on the entry in the table to remove the entry User s Manual 7066438 23 Chapter 3 System Setup Delete MCA Delete the following MCA and its inputs MCA Input Size ADC MXR Stab Amp HY Gain Figure 4 The Delete MCA Dialog Defining an MCA 24 This section discusses setting up an Osprey MCA which has a fully programmable front end That is its DSP Gain DSP Filter Digital Stabilizer MCS and High Voltage Power Supply are all controlled from the host computer To begin click on the Osprey MCA entry in the Definition Table Figure 5 that you want to set up Ed MCA Input Definition Editor local Untitled xi File Database Edit Devices Settings Summary Help MCA Input Size ADC MXR Stab Amp HY Gain Osprey MCA DETO1 Figure 5 Selecting the MCA to Set Up Interpreting the Definition Entry As you can see in Figure 5 adding the entry put more than just the name of the M
99. nt password in the Current Password text box The factory default password is password 4 Type the new password in both the New Password and Confirm New Password text boxes 5 Press the Submit button User s Manual 7066438 71 Chapter 4 Web Based Status Web Update Utility A Web Update utility is supplied with the Osprey on the enclosed CD This utility is used to transfer files to the device via TFTP to update the web status page and other files The folder location of the update utility file is lt Drive gt Osprey Device Files WebUpdate The folder location of the website files is lt Drive gt Osprey Device Files WebUpdate Website To run this utility open a command window Verify the command prompt is configured for the proper directory See above folder location for update utility The general syntax to run the utility is oWebUpdate ipAddress FolderPath An example is oWebUpdate 10 0 0 3 website where oWebUpdate is the update utility file name 10 0 0 3 is the IP address of the device and website is the folder that includes all the web files to update to the device This example is shown in Figure 34 Cycle power to the Osprey once the web update is complete cx Command Prompt C Osprey Device Files WebUpdate gt oWebUpdate 18 0 6 3 websites Figure 34 Folder Location for Web Update Utility 72 Osprey Universal Digital MCA Tube Base Inputs Outputs A Specifications Inputs Outputs PMT
100. ogram or any derivative work under copyright law that is to say a work containing the Program or a portion of it either verbatim or with modifications and or translated into another language Hereinafter translation is included without limitation in the term modification Each licensee is addressed as you Activities other than copying distribution and modification are not covered by this License they are outside its scope The act of running the Program is not restricted and the output from the Program is covered only if its contents constitute a work based on the Program independent of having been made by running the Program Whether that is true depends on what the Program does 1 You may copy and distribute verbatim copies of the Program s source code as you receive it in any medium provided that you conspicuously and appropriately publish on each copy an appropriate copyright notice and disclaimer of warranty keep intact all the notices that refer to this License and to the absence of any warranty and give any other recipients of the Program a copy of this License along with the Program You may charge a fee for the physical act of transferring a copy and you may at your option offer warranty protection in exchange for a fee 2 You may modify your copy or copies of the Program or any portion of it thus forming a work based on the Program and copy and distribute such modifications or work under the terms of Section 1 ab
101. oltage limit y Woltage Status E pa 1300 0v Cow ok E On xit 5 EA UTE mj 1300 0 1300 Figure 20 Adjust Screen s HVPS Settings Stabilized The Osprey NAIS 2X2 LED stabilized detector has no A Detector user adjustable HVPS parameters Attempting to change any voltage parameters when a stabilized detector is attached to the Osprey will generate the Invalid Operation error from the device The only control on this screen that can be used with the stabilized detector is the HVPS Reset button for clearing an error state Status This control allows you to turn the HVPS On Off When turned On the high voltage output will ramp to the current High Voltage setting and when turned Off will ramp to zero The high voltage indicator LED will turn On when the high voltage power supply is switched to On and will turn Off when the high voltage power supply has been switched to Off and the output voltage has decayed to approximately 10 of full scale or 130 volts WARNING When turned Off as the voltage output approaches zero its decay becomes exponential This means that a residual voltage may still be present at the detector User s Manual 7066438 43 Chapter 3 System Setup 44 socket after the high voltage power supply has been switched Off To avoid shock use extreme care when plugging or un plugging detectors with power applied to the Osprey Range The Osprey supports a single voltage range of 1300 volts
102. ommunicate with devices on a network This address can be changed on the Ethernet Network Setup page USB MAC Address The network card Media Access Control Address A unique number that identifies the USB hardware interface USB IP Address A unique address assigned to the device that is used to identify and communicate with devices on a network This address can be changed on the USB Network Setup page 64 Osprey Universal Digital MCA Tube Base Device Setup Device Setup The Device Setup menu group Figure 31 allows the user to perform changes to device parameters when logged in with administrative privileges CANBERRA Information Device Information Help Username administrator Password Logoff System Status a mu E co Stb Probe Connected Stb Probe Ready HN On H V Ramping Default Gateway Subnet Mask Assigned Address 160 84 36 IP Address 10 o o 5 aa PHA Acquisition Status MCS Acquisition Status ua mua n E Ethernet Network Setup Idle Busy Waiting Idle Busy Waiting ma USB Network Setu NA PresetTime Reach Preset Integral Reach Preset Sweeps Reach NA NA UPnP Setu co m L c i External Stop Manual Stop Overflow Stop Extemal Stop Manual Stop Overflow Stop Device Upgrade Pg E man E m FPGA Upgrade Group 1 Active Group 2 Active Ext Trg Event Group 1
103. on Setup on page 81 describes the initial setup and basic operation of each of these interfaces Ethernet Osprey supports 10 100 Base T Ethernet auto sensing connecting to an Ethernet network PoE IEEE 802 3af compliant using an Ethernet patch cable or directly to a host computer through a single port PoE injector One 3 m 10 ft 10 100 Base TX UTP Ethernet patch cable and one 3 m 10 ft 10 100 Base TX UTP Ethernet Crossover cable Red in color are supplied User s Manual 7066438 57 Chapter 3 System Setup USB USB 5 pin Mini B is for connecting the Osprey as a Device to a USB hub or directly to a host computer The USB Host will be required to supply 2W of power One 3 m 10 ft USB A B cable is supplied e Before you can use the USB interface you ll have to set up your PC for this USB setup instructions are found in the appendix Communication Setup on page 81 GPIO Connections Several GPIO connections may be required Figure 28 shows a GPIO MCX cable Refer to GPIO Connectors on page 8 and to the appendix External GPIO Configuration Matrix on page 97 for GPIO configuration selection chart and descriptions Figure 28 Sample GPIO MCX Cable 58 Osprey Universal Digital MCA Tube Base System Connections for a Detector 4 Web Based Status A web based status page Figure 29 is supplied with the Osprey providing MCA and detector status information network setup and firmware upgrade functionalities The statu
104. on developing an application to access specific functions or other device parameters There are several cases in the GPIO configuration matrix where selecting a GPIO function alone is not sufficient to achieve the desired operation for these cases the setup of additional parameters is required Where applicable the Description column in the matrix will identify the other parameters involved Applications such as Genie 2000 will expose all relevant parameters through its user interface but if developing a custom application please refer to the mcaSDK Communication Software Development Kit documentation on accessing all user parameters in the device All GPIO signals are TTL compatible Refer to the Specifications on page 73 of this manual for actual voltage levels and other electrical characteristics of input and output signals into and out of the GPIO connectors Unless specifically noted in the description all signal polarities are active high To maximize the use of a single GPIO connector functions 23 through 30 actually combine multiple functions into a single selection Refer to the individual descriptions for more specific information on combinational functions User s Manual 7066438 97 Appendix D External GPIO Configuration Matrix Function Name Description INPUT LEVEL SENSE 00 GPIO_IN Function 00 configures the connector pin for input mode The INPUT LEVEL SENSE function should be selected when read
105. onnection method also may be used for an Osprey application in a non networked site such as a PC to Osprey stand alone system Direct Setup Connect to Osprey with your PC This procedure allows you to connect to and operate the Osprey using your PC without other network equipment Use this if you do not yet have an IP Network connection either a static address or DHCP configured for your new Osprey system and you choose to set it up before that network connection is available Later after your network connection is available you will make a few network settings changes to connect the Osprey to your network 82 Osprey Universal Digital MCA Tube Base Quick IP Setup Summary Note there is no Undo Record any existing IP address settings in your PC before you change it in the event you must return this PC to its original settings Figure 35 Connecting the Osprey to a PC Connections To begin perform the following connections 1 Place the Osprey near your PC Connect the AC power to the single port PoE injector provided with the Osprey 2 Disconnect your PC s network adapter from the existing connections 3 Connect the IP crossover cable Red cable provided with Osprey from your desktop PC s network adapter to the IN connector on the single port PoE injector 4 Connect the yellow Ethernet cable IP straight through supplied with the Osprey from the OUT connector on the single port PoE injector to the Netwo
106. onoccnnnons 21 O Osprey accessories included 19 applying POWET eecceeceseeeseeseeeteeeseeeeeeeeeees 17 communication ports sesseseeseeseeeesseeeesseeee 16 connecting directly to a PC essees 57 82 correcting a fault 0 0 0 eeeeseeseeseeeeeeeeeeeeees 18 default network connection settings 81 digital lr a keane 95 fault condition indicators eceeeeseeteeeee 17 front panel lt a een ias 6 Initilizing the unit 17 Teset Dutti ais hoa hot 18 SYSTEM SlALUS ae a i i eiia 60 tube base socket cee eeceseeeeeeeceeeeecneeeeeaees 16 typical system annene e ai 53 P Password CHANGING sisesma Ri 71 A a alerts hala wicca RRAS 59 Power On Self Test POST oooconccncnincnicnconncnnoo 17 Probe setup for 14 pin probe oooooocciccnccnoonconnconcconccnnonnnonnos 54 for a 8 pin stabilized probe 0 0 eceeceeeeeee 56 R Resetting the OSprey cccecsesceeseeteereeeeeseenees 18 Runtime configuration database eeeee 37 S Saving the MID definition eceeeeseereee 33 Security settings nehne aneii 71 Setting up firewall for Genie 2000 oooonconnniconinnionconnonnos 86 multiple USB comnecti0M oooooccnncnnnnninnincos 93 PE for USB pirionoecirriecin ieem 89 PC to connect directly to Osprey 83 PC to utilize DHCP reoriemiininenie iei 85 Settings Osprey Universal Digital MCA Tube Base DSP Teri ira 30 46 PTA esd ceuesnegahtentes 28 44 high vol
107. ons window click on the Advanced menu and select the Advanced Settings menu item This will bring up the Advanced Settings dialog window Figure 40 Adapters and Bindings Provider Order Connections are listed in the order in which they are accessed by network services Connections Local Area Connection bo Remote Access connections las Bindings for Local Area Connection 3 M a File and Printer Sharing for Microsoft Networks M7 Internet Protocol TCP IP mi E Client for Microsoft Networks Mm Internet Protocol TCP IP ENE Figure 40 Advanced Settings for the Osprey 9 Inthe Connections list highlight the topmost Local Area Connection that was created by the Osprey USB driver refer to the step 4 to determine the actual connection name 10 Click on the down pointing arrow next to the Connections list to move the Osprey USB connection below the default network connection Yov re done and may close any open windows 92 Osprey Universal Digital MCA Tube Base Setting Up a USB Connection Configuring for Multiple Osprey using USB Setup for Multiple USB Connections Note When connecting two or more Osprey devices to the same host computer via USB it is recommended to use a 4 port self powered USB hub If it is necessary to control more than four devices with one host computer it is recommended to use the Ethernet connection When configuring your PC for multiple Osprey devices foll
108. or User s Manual 7066438 75 Appendix A Specifications MSS e Data acquired into two memory groups alternating between the two in a ping pong fashion when a preset time parameter or preset count parameter is reached e Ability to use External Sync to switch between groups List Time Stamped List e Latency 100 ms Only when streaming mode is supported e External time base support Use of External Sync e Time stamp resolution 1 us and 100 ns e Maximum event rate 100 000 pulses sec AUX Counters e TTL compatible minimum pulse width for input gt 50 ns e AUX Counter Modes Automatic Manual AutomaticEx External Sync Performance Channel Configurations Total channels 8192 Configurable as two groups of 2048 1024 512 or 256 channels for PHA and MCS Bits per channel 32 Integral Non linearity 0 025 of full scale over the top 99 of the selected range Differential Non linearity 1 over the top 99 of the range including the effects from integral non linearity Gain Drift lt 75 ppm C after 15 minutes of operation Zero Drift lt 3 ppm C after 15 minutes of operation Incoming Count Rate ICR gt 250 K cps ICR if not limited by probe detector 76 Osprey Universal Digital MCA Tube Base Programmable Controls Programmable Controls Coarse Gain x1 x2 x4 x8 software programmable Fine Gain x1 to x5 software programmable Total Gain Product of Fine Gain Coarse Gai
109. ounting mode only are grouped with the Start Stop options Select the proper GPIO for the External Control input using the External GPIO Configuration Refer to the appendix External GPIO Configuration Matrix on page 97 for GPIO configuration selection chart and descriptions The external controls are used as follows External Start Stop Four active external Start Stop control options are offered plus none The Polarity of each of the external input signals is set using this area of the setup page e Start Only Stop Only and Start and Stop allow an external signal pulse to change the state of an acquisition once acquisition is enabled subsequent external signal inputs are ignored User s Manual 7066438 49 Chapter 3 System Setup e Suspend amp Resume will toggle the state of the acquisition upon receipt of an external level Start Only An External Start Stop pulse starts acquisition Acquisition is first armed by pressing the Acquire Start button in Genie Then an external pulse triggers the start of acquisition Once acquisition is active subsequent pulses are ignored Stop Only An External Start Stop pulse stops acquisition While Acquisition is active an external pulse triggers the stop of acquisition Once acquisition is stopped subsequent pulses are ignored Start and Stop If acquisition is inactive but armed an External Start Stop pulse starts acquisition Once acquisition is active an External Start Sto
110. ove provided that you also meet all of these conditions Osprey Universal Digital MCA Tube Base Optimizing Process Time a You must cause the modified files to carry prominent notices stating that you changed the files and the date of any change b You must cause any work that you distribute or publish that in whole or in part contains or is derived from the Program or any part thereof to be licensed as a whole at no charge to all third parties under the terms of this License c Ifthe modified program normally reads commands interactively when run you must cause it when started running for such interactive use in the most ordinary way to print or display an announcement including an appropriate copyright notice and a notice that there is no warranty or else saying that you provide a warranty and that users may redistribute the program under these conditions and telling the user how to view a copy of this License Exception if the Program itself is interactive but does not normally print such an announcement your work based on the Program is not required to print an announcement These requirements apply to the modified work as a whole If identifiable sections of that work are not derived from the Program and can be reasonably considered independent and separate works in themselves then this License and its terms do not apply to those sections when you distribute them as separate works But when you distribute the same se
111. ow these steps 1 Change the USB IP address of each additional Osprey a Ifthis is the first time a device is connected to the host PC there will be a prompt to install the USB drivers Follow the steps provided in Installing the USB Driver on page 88 b Connect to each Osprey separately at the default address 10 0 1 4 using the web based status page and login as administrator c Select USB Network Setup link under Device Setup d In the boxes for IP Address enter a unique IP address for the device and hit Submit Use 10 0 X 4 where the X is a number other than 1 Each Osprey requires a different number for X Record the IP address for use in setting up the Network adapter in the PC step below Cycle power to the device for the change to take effect 2 When the IP address changes have completed connect each Osprey to the host PC through a self powered USB hub Connect one Osprey at a time to properly keep track of the correct IP address After each device is connected to the host PC there will be a prompt to install the USB drivers Follow the same steps provided in Installing the USB Driver on page 88 3 Follow the same steps as in Configuring your PC for the Osprey via USB on page 89 with the only change being instead of using 10 0 1 10 for the IP address of the USB network adapter use 10 0 X 10 where the X is the same number used when changing the IP address in the Osprey device User s Manual 7066438 93 Appendix B Commun
112. p and the preset sweep counter has been reached After receiving the second pulse subsequent pulses have no effect Suspend Resume Once acquisition is enabled though a software Start command the Suspend Resume input can be used to suspend or resume storage of MCS events through a TTL compatible DC level For Start Stop and Start Stop modes acquisition and storage of MCS events is synchronized to the leading edge of the incoming pulse User s Manual 7066438 9 Chapter 2 Controls and Connectors For Suspend Resume mode with positive logic polarity selected a TTL high signal allows storage and a TTL low inhibits storage Negative logic polarity reverses the logic MCS EXT CHN ADV This mode is restricted to a single GPIO connector Minimum pulse duration of 100 nanoseconds Polarity is software selectable for positive or negative logic The MCS EXT CHN ADV mode can be used to enable an external user supplied pulse to control the dwell time of the MCS Acquisition Unit When operating in MCS mode and configured for external channel advance this input will advance counting from the current to the next dwell channel Minimum dwell time must be microsecond or greater MCS EXT SWP ADV This mode is restricted to a single GPIO connector Minimum pulse duration of 100 nanoseconds Polarity is software selectable for positive or negative logic The MCS EXT SWP ADV mode can be used to enable an external user supplied pulse to s
113. p pulse stops acquisition Subsequent pulses are ignored Suspend amp Resume In this mode when the acquisition is enabled by pressing the Acquire Start button in Genie storage of events will occur when the External Start Stop input is active TTL high and acquisition storage will be suspended when the External Start Stop input is inactive TTL low Polarity Select the External Start and Stop input signal active polarity Positive or Negative logic can be selected Channel Advance An external Channel Advance signal arriving at the configured GPIO connector will advance the MCS channel ending in the current dwell Channel Advance will be available if the MCA Acquisition Mode was previously configured for MCS in the MID setup Otherwise this option will be disabled grayed out Polarity Select the Channel Advance input signal active polarity Positive or Negative logic can be selected Sweep Advance An external Sweep Advance signal arriving at the configured GPIO connector will advance the MCS Sweep This returns the current dwell to the first channel in the group Sweep Advance will be available if the MCA Acquisition Mode was 50 Osprey Universal Digital MCA Tube Base Acquire Setup with Genie 2000 previously configured for MCS in the MID setup Otherwise this option will be disabled grayed out Polarity Select the Sweep Advance input signal active polarity as either Positive or Negative Input Size Select t
114. pend resume signal to resume MCS acquisition if the external start stop logic has been configured for level mode Logic polarity for MCS EXT START STOP OUT is fixed at active high Multiple GPIO connectors can be configured for the MCS EXT START STOP OUT function to extend the same output to multiple connectors This function is not supported in Genie 2000 AUX CNTR IN 03 and MCS IN 08 23 AUXCNT_IN MCSTTL_IN Function 23 configures the connector for dual input mode with fixed active high polarity for both modes Selecting this function internally configures the GPIO connector for dual input mode where the same external user supplied input signal is routed to the AUX CNTR IN see Function 03 and MCS IN see Function 08 effectively combining two functions into a single selection The selection for this function is limited to a single GPIO connector Please refer to the individual function description for any additional information that may apply This function is not supported in Genie 2000 MCS EXT SWP ADV 05 and EXT SYNC IN 19 25 MCSEXTSWP_IN EXTSYNC_IN Function 25 configures the connector for dual input mode with fixed active high polarity for both modes Selecting this function internally configures the GPIO connector for dual input mode where the same external user supplied input signal is routed to the MCS EXT SWP ADV see Function 05 and EXT SYNC IN see Function 19
115. per s rise time and flat top settings The gating signal can occur after this time if the gate delay feature is used The Gate Delay feature will delay the decisions regarding the storage of individual energy events by the programmed amount of time The Gate Delay feature allows for the coincidence anticoincidence qualification to be made later if the gate qualifying signal is provided by a mechanism slower than the processing time in the Osprey Energy events that have passed the Coincidence Anticoincidence qualifications must still meet the conditions of additional qualifiers such as LLD ULD etc before they can be processed by the PHA acquisition unit 8 Osprey Universal Digital MCA Tube Base GPIO Connectors MCS IN This mode is restricted to a single GPIO connector Input signal is TTL compatible with minimum pulse duration of 100 nanoseconds Polarity is fixed at positive logic The MCS IN mode is used to supply external TTL pulses to the MCS Acquisition Unit When configured for TTL input the MCS Acquisition Unit counts the number of pulses present on the designated GPIO connector for the duration of the dwell timer and accumulates the count value into the current channel of the histogram MCS EXT START STOP IN This mode is restricted to a single GPIO connector Minimum pulse duration of 100 nanoseconds Polarity is software selectable for positive or negative logic The MCS START STOP IN mode can be used to enable an external
116. pled with the powerful Genie 2000 software suite the Osprey takes scintillation spectrometry to a new level Just connect the detector and Osprey connect the Osprey to an available USB or Ethernet port start the Genie 2000 software and you are ready to acquire the spectrum making this a true plug and play solution The Genie 2000 software suite is a comprehensive environment for MCA control data acquisition display and analysis It provides independent support for multiple detectors extensive networking capabilities advanced data analysis and comprehensive batch procedure capabilities With the Genie 2000 programming libraries the advanced user can develop custom applications using all available Genie 2000 features and user interfaces An OS independent software development kit SDK with examples is included with every Osprey and can be used without Genie 2000 The SDK is similar to the comprehensive set of programming tools distributed with CANBERRA s Lynx MCA It allows expert users to develop platform independent applications for instrument control and data acquisition In addition a diagnostic web graphical user interface GUI application is supplied with the Osprey providing MCA and detector status information network setup and firmware upgrade functionalities The Osprey features support for all commonly used spectrometry modes PHA MCS SCA Aux Counter MSS List and Time stamped List unmatched by any othe
117. pter also reviews the interaction with the Genie 2000 Basic Spectroscopy software which is required for spectral analysis Chapter 4 Web Based Status describes how to use a web browser to view device status set IP address update firmware and FPGA files and change user passwords of the Osprey Appendices The appendices offer useful information not usually needed in day to day operation 2 Osprey Universal Digital MCA Tube Base Abbreviations and Acronyms Abbreviations and Acronyms The following abbreviations and acronyms used throughout the manual are listed below AUX Auxiliary DHCP Dynamic Host Configuration Protocols FPGA Field Programmable Gate Array GPIO General Purpose Input Output Connectors ICR Incoming Count Rate MCA MultiChannel Analyzer MCS Multichannel Scaling MID MCA Input Definition MSS Multi spectral Scaling PHA Pulse Height Analysis PoE Power over Ethernet SCA Single Channel Analyzer USB Universal Serial Bus UPnP Universal Plug and Play Acquisition Units The Osprey contains four acquisition units PHA Acquisition Unit The PHA acquisition unit converts energy signals from a radiation detector into a digital value The digitized value could be accumulated by the device to form a histogram or stored with a time stamp and supplied to a client application for analysis MCS Acquisition Unit The MCS acquisition unit sequentially accumulates data pulses into each of the config
118. ption USB lt 2 Watt e Power consumption PoE lt 3 Watt Physical SIZE 62 x 108 mm 2 44 x 4 25 in D x L WEIGHT 280 g 9 9 oz Environmental Temperature Range 10 to 50 C 14 to 122 F Humidity 85 non condensing Meets the environmental conditions specified by EN 61010 Installation Category I Pollution Degree 2 78 Osprey Universal Digital MCA Tube Base Compliance Compliance EMC Emissions and Immunity e EN61326 2006 e EN61000 3 2 2008 e EN61000 3 3 2008 e EN61000 4 2 2008 e EN61000 4 3 2008 e EN61000 4 4 2004 e EN61000 4 5 2005 e EN61000 4 6 2008 e EN61000 4 11 2004 e EN61000 4 8 2001 NRTL LISTED Safety e CAN CSA C22 2 No 61010 1 04 e UL61010 1 2004 e IEC61010 1 2001 2nd edition e EN61010 1 2001 2nd edition RoHS DIRECTIVE 2002 95 EC Software Genie 2000 Spectroscopy Software Genie 2000 Programming Libraries SDK OS independent distributed with the device independent of Genie 2000 programming libraries Genie 2000 not required Diagnostic Web GUI OS and browser independent Genie 2000 not required User s Manual 7066438 79 Appendix A Specifications Computer Requirements The minimum computer requirements are those specified for the current version of the Genie 2000 software See the Genie 2000 data sheet for more details Ordering Information 80 OSPREY Digital tube base MCA with 3 m 10 ft USB cable 3 m 10 ft crossover
119. r 1 us resolution Client applications can be developed using methods from the supplied Software Development Kit to extract List data from the Osprey Once extracted both the energy and time components become available to the client application where real time analysis can be performed energy time correlated spectrums can be produced etc Auxiliary Counters A single Auxiliary Counter is supported by the Osprey to count externally supplied TTL pulses The counter s acquisition can be set for manual automatic or dependent on the PHA acquisition unit or synchronized to an external event Single Channel Analyzer SCA The Osprey supports up to six programmable SCA s each with its own independent window setting within the PHA spectrum In addition to providing a numeric value each counter can also be programmed to provide a TTL output pulse to one or more GPIO connectors to drive external counters The SCA s acquisition can be set for manual automatic dependent on the PHA acquisition unit or synchronized to an external event User s Manual 7066438 5 Chapter 2 Controls and Connectors 2 Controls and Connectors Osprey has several functional indicators and a number of connectors on its front panel This chapter includes a brief description of each one With the exception of a recessed reset button there are no other user controls on the unit itself The indicators show status and some indications that may be used to verify a setup
120. r for Osprey MCA reads important metadata information from the device using network TCP port 8080 If you have the stock Windows Firewall enabled or use a third party firewall software ensure that the port 8080 is not blocked for inbound traffic CAUTION Genie 2000 will not be able to communicate with Osprey MCA if port 8080 is blocked on your PC Universal Plug and Play The Osprey device registers for Universal Plug and Play UPnP during start up This means that once a device in this case the Osprey is running and plugged into your network other computers on the network are informed that it s present and running Note In order to use the UPnP feature it must first be set up and active on your Windows XP or newer PC operating system Earlier versions of Windows do not support this protocol For a networked computer to detect the Osprey when it is connected to the network your PC must have UPnP services installed 86 Osprey Universal Digital MCA Tube Base Universal Plug and Play Adding Universal Plug and Play to Your PC If not installed you can add UPnP by following the steps below on a Windows XP PC Note Note Adding or enabling UPnP support varies on each operating system Refer to the operating system documentation for additional help 1 Press the Start button on Windows XP Select Settings and then select the Control Panel 2 Select the Add or Remove Programs icon This brings up the Add or Remove Programs
121. r supplied pulses to be counted in the AUX Acquisition Unit EXT SYNC IN This mode is restricted to a single GPIO connector Minimum pulse duration of 100 nanoseconds Polarity is software selectable for positive or negative logic The EXT SYNC IN mode enables an external user supplied signal to synchronize the Osprey s MSS AUX SCA and List TList Acquisition Units The external signal can be from a second Osprey MCA or from other electronic equipment The Osprey s acquisition units make use of the external sync signal as follows PHA does not make use of the external sync signal User s Manual 7066438 11 Chapter 2 Controls and Connectors MSS The external sync signal synchronizes individual MSS acquisitions An external sync pulse on this signal will initiate the next MSS cycle if the PHA preset condition has already been reached If the pulse occurs prior to the preset then the Osprey will terminate the current cycle and begin the next MSS cycle AUX The external sync signal synchronizes the operation of the auxiliary counter SCA The external sync signal synchronizes the operation of the SCA counter operation with an external signal Time Stamped List The external sync signal synchronizes the internal timer stamp of the Osprey with an external device such as another Osprey This mode can be used to acquire data which can later be utilized for coincidence and or multiparameter experiments List The e
122. r tube base MCA on the market The Osprey provides a level of performance superior to many available desk top MCAs The Osprey will accommodate standard 14 pin scintillation detectors It also supports a temperature stabilized Nal detector designed specifically for the Osprey The CANBERRA NAIS 2x2 temperature stabilized detector uses a patented LED stabilization technique and features a robust locking mechanism for increased US Patents 7 005 646 B1 and 7 049 598 B1 User s Manual 7066438 1 Chapter 1 Introduction reliability In all configurations the Osprey is compatible with Canberra Model 727 laboratory lead shield This manual describes the capabilities of the Osprey MCA Setup and interaction with the Genie 2000 software is reviewed as it relates to the Osprey MCA System setup details for the Osprey system are provided and User instructions for data acquisitions are also described About this Manual This manual is a reference to the capabilities and operation of the Osprey MCA Each of its chapters covers specific functions The Chapters are divided into the following arrangement Chapters Chapter 1 Introduction is an introduction to the manual s contents and an overview of the Osprey s features Chapter 2 Controls and Connectors includes a brief description of each LED indicator and each panel connector Chapter 3 System Configuration includes instructions for setting up a typical system This cha
123. rical Specifications Input TTL compatible 10 KQ pull up resistor to 3 3V volts software selectable logic low lt 0 8 V logic high gt 2 0V Minimum pulse width gt 100 Output TTL compatible Logic low lt 0 55 V logic high gt 2 4V Output current 24mA Osprey Universal Digital MCA Tube Base Acquisition Modes Acquisition Modes PHA PHA Channels 256 to 2048 Channels Supports two memory groups of up to 2048 channels each Preset ROI Counts Integral Real or Live Time timers Real and Live Time Resolution 0 01 s Preset Time 0 to gt 4 x 107 s Control Internal or External Start Stop control LTC accuracy 5 3 typical up to 50 kcps LTC method proprietary Dwell range 1 us to 999 seconds in 1 us steps Sweep range 1 to 27 1 Preset Sweep Counter 0 to 221 0 implies Forever MCS input selection PHA ROL external TTL or Fast Discriminator Dwell selection internal or external MCS Channels 256 to 2048 Channels Supports two memory groups of up to 2048 channels each The following advanced modes of operation are accessible through the SDK SCA Channels 6 Preset Modes Live Time Real Time SCA Modes Automatic Manual AutomaticEx External Sync Size of Counter for each SCA Channel 32 bits LLD and ULD for each SCA Channel 0 to 100 Full Scale Software Programmable SCA Signal Output for selected channel 200 ns output pulse for each event can be mapped to a GPIO connect
124. rk jack 10 100 on the Osprey It will take approximately 15 seconds for Osprey to boot Setup on your PC Setup you desktop s network adapter to use a Static or alternate network address 1 Right click on the My Network Places icon then select Properties 2 Right click on the appropriate Network Adapter icon then select Properties User s Manual 7066438 83 Appendix B Communication Setup Note On the General tab select Internet Protocol TCP IP then select Properties Select the General or Alternate Configuration tab and then select the Use the following IP address option Enter the following settings IP 10 0 0 10 Subnet 255 255 255 0 All other entries are blank Press OK Use any number other than the factory default IP address used by the Osprey unit 10 0 0 3 Ethernet You are now able to access the Osprey directly from your PC in a computer to computer network configuration Access the Osprey Web Status Page To access the Web Status Page 1 Open your Internet browser on your PC In the URL line enter 10 0 0 3 and press Enter This will open the Osprey Web Status page Enter administrator for the Username and password for the Password Click the Login button to connect to the Osprey This provides administrative privileges to allow parameter changes Make any changes using instructions provided the chapter Web Based Status on page 59 Save your changes when done
125. rs with long light collection time without a large increase in the overall processing time The Flat Top setting ranges from 0 0 to 3 0 ps BLR Mode Sets the Baseline Restorer mode When set to AUTO the baseline restorer is automatically optimized as a function of trapezoid shaping time and count rate With settings of SOFT MEDIUM and HARD the baseline restorer is set to fixed rates as selected 30 Osprey Universal Digital MCA Tube Base Defining an MCA MCS Settings The MCS settings screen Figure 11 for the Osprey contains the following controls MCS for input DETO1 Disc Mode ROI Start ROI End FDisc ich Ok 2048ch Se FEE a ja C ROI 2048 1 2048 OK Apply to All Cancel Help Figure 11 MCS Settings Disc Mode The Discriminator Mode control establishes the input signal to the MCS Acquisition Unit Selecting FDisc enables the MCS s fast discriminator mode where all incoming events above the Fast Discriminator threshold are counted Selecting TTL enables the MCS s TTL mode where all TTL events as seen at the GPIO connector selected to accept the MCS IN signal to be counted Selecting ROI enables the ROI discrimination mode meaning that all incoming events processed by the DSP that fall within the selected discrimination window are counted If TTL mode is selected then the External GPIO Configuration in the Acquire Setup dialog must have one GPIO connector select
126. s page is accessible from most web browsers Internet Explorer version 7 and higher is supported Version 6 has limited support Firefox 3 0 and higher is supported Java script and Cookies must be enabled in the browser for proper operation To learn how to allow Java Script and Cookies see online help in your web browser It is recommended to close the web browser when all tasks are completed in the web based status page When using IE7 or IE8 there is a known issue of excessive memory usage when the browser is open for extended periods The following three Status Page sections include status indicators The indicators are rectangular boxes with text beneath describing their function A white indicator denotes the function is inactive and a green indicator denotes the function is active Username Password Login System Status Co Co Stb Probe Connected Stb Probe Ready HV On HV Ramping CANBERRA Information Device Information PHA Acquisition Status MCS Acquisition Status Ethernet Network Setup Idle Busy Waiting Idle Busy uu a E E Device Setup USB Network Setu N A Preset Time Reach Preset Integral Reach Preset Sweeps Reach N A N A UPnP Setup E External Stop Manual Stop Overflow Stop External Stop Manual Stop Overflow Stop PES C E C mu FPGA Upgrade Group 1 Active Group 2 Active Ext Trg Event Group 1 Active Group 2 Active Ext Trg Event F
127. ses for most software are designed to take away your freedom to share and change it By contrast the GNU General Public License is intended to guarantee your freedom to share and change free software to make sure the software is free for all its users This General Public License applies to most of the Free Software Foundation s software and to any other program whose authors commit to using it Some other Free Software Foundation software is covered by the GNU Library General Public License instead You can apply it to your programs too When we speak of free software we are referring to freedom not price Our General Public Licenses are designed to make sure that you have the freedom to distribute copies of free software and charge for this service if you wish that you receive source code or can get it if you want it that you can change the software or use pieces of it in new free programs and that you know you can do these things To protect your rights we need to make restrictions that forbid anyone to deny you these rights or to ask you to surrender the rights These restrictions translate to certain responsibilities for you if you distribute copies of the software or if you modify it For example if you distribute copies of such a program whether gratis or for a fee you must give the recipients all the rights that you have You must make sure that they too receive or can get the source code And you must show them these terms
128. settings screen Figure 22 for the Osprey contains the following controls x C Stab C H PS C Gain Filter Rise Time Flat Top BLR mode gt 1 000us 1 0 v Auto y al Prey al F gt Help 0 2 5 Figure 22 Adjust Screen DSP Filter Settings Rise Time Symmetrically sets the rise time and fall time of the digital filter time response As with conventional Gaussian shaping the degree of noise filtering is proportional to the rise time selection The Rise Time setting ranges from 0 2 to 5 0 us Flat Top The Flat Top allows for the charge light collection time of the particular scintillator Independent adjustment of the flat top allows the shaping function to be optimized for scintillators with long light collection time without a large increase in the overall processing time The Flat Top setting ranges from 0 0 to 3 0 us 46 Osprey Universal Digital MCA Tube Base Acquisition Window Adjust Dialogs with Genie 2000 BLR mode Sets the baseline restorer mode With a setting of AUTO the baseline restorer is automatically optimized as a function of trapezoid shaping time and count rate With settings of SOFT MEDIUM and HARD the baseline restorer is set to fixed rates as selected MCS Parameters The MCS settings screen Figure 23 for the Osprey contains the following controls x MCS N Dwell Range Dwell Value m Disc Mode E C microsec OK C FDisc Exit Pr
129. setup directions UPnP Friendly Name This defines the name of the device You can use this name to identify the device using a UPnP browser such as Windows XP My Network Places applet UPnP TTL The network Time To Live value TTL is the number of hops an IP packet may make across the network The default number is 4 This value can be changed from 1 to 255 It is required to restart the device for this change to take affect User s Manual 7066438 67 Chapter 4 Web Based Status Enable UPnP This check box enables or disables this service When enabled you will be able to discover this device on your network using any UPnP browser such as Windows XP My Network Places applet Device Reset When changes have been made to the UPnP Setup press the Submit button For the changes to take affect the device is required to be reset Press the Device Reset button to reset the device immediately or perform additional device parameter changes and reset the device at a later time When the Device Reset button is pressed the device will reset and the Web Status page will refresh in 60 seconds During this time the links in the web page are disabled Verify the new settings in the Device Information page Device Upgrade The Device Upgrade menu group Figure 32 allows the user to update the FPGA files or the firmware when logged in with administrative privileges Username administrator Password Logoff CANBERRA Sys
130. start the device for this change to take affect This address must be changed to a unique address if multiple Ospreys are connected to same host PC and or multiple devices will be controlled by same Genie 2000 session Default Gateway The default gateway to be used to route those packets not destined for a subnet that the device is directly connected to and for which a more specific route does not exist Subnet Mask This value specifies the subnet masks to be used with the IP interfaces bound to the adapter This value can be any set of valid IP addresses Device Reset When changes have been made to the Ethernet Network Setup press the Submit button For the changes to take affect the device is required to be reset Press the Device Reset button to reset the device immediately or perform additional device parameter changes and reset the device at a later time When the Device Reset button is pressed the device will reset and the Web Status page will refresh in 60 seconds During this time the links in the web page are disabled Verify the new settings in the Device Information page USB Network Setup Refer to the appendix Communication Setup on page 81 for network setup directions for USB connection MAC Address The network card Media Access Control Address This is a read only field for information purposes and cannot be changed 66 Osprey Universal Digital MCA Tube Base Device Setup Assigned Address The current IP a
131. t impose that choice This section is intended to make thoroughly clear what is believed to be a consequence of the rest of this License 8 If the distribution and or use of the Program is restricted in certain countries either by patents or by copyrighted interfaces the original copyright holder who places the Program under this License may add an explicit geographical distribution limitation excluding those countries so that distribution is permitted only in or among countries not thus excluded In such case this License incorporates the limitation as if written in the body of this License 9 The Free Software Foundation may publish revised and or new versions of the General Public License from time to time Such new versions will be similar in spirit to the present version but may differ in detail to address new problems or concerns Each version is given a distinguishing version number If the Program specifies a version number of this License which applies to it and any later version you have the option of following the terms and conditions either of that version or of any later version published by the Free Software Foundation If the Program does not specify a version number of this License you may choose any version ever published by the Free Software Foundation 10 If you wish to incorporate parts of the Program into other free programs whose distribution conditions are different write to the author to ask for permission For
132. tage oooooonoonoccnoconononononononnnonnnonnnnos 27 43 INPUt SettINGS R EE E 32 MGS TEE do cinta ba 31 47 Stabilizer mese ee eee 27 40 Specifications ceecesccesecseeseeeeeseeeneeeeeeseeeeeeens 73 Stabilizer SCLIN GS is ide 27 40 spectrum stabilizer algorithm 39 U Univeral Plug and Play UPnP eeeeeeenee 86 intalling cocina seinen 87 USB ad A e 17 57 USB driver installid8 ooooonnnnnnnncninnnmmmmmmmmso 88 Using an MID definition ooocococnccnoncnccononnnananuninnon 21 V Verifying the USB connection coocococncnoccnononccnnon 94 W Web base status page accessing the Page ceccssecssesseeseeseeeteeereees 84 device Setup end 65 device upgrade esseni pnie 68 O A een ee neeeeee de 59 MCS acquisition Status c ceceeseeseereeeeeees 61 PHA acquisition StatUS oooooononnonincnocnncnonnnnnos 60 A au auntie Aun ae e Ee 71 SYSUSMISLALUS asesinato ted e E E E 60 User s Manual 7066438 115 116 Note A CANBERRA Warranty Canberra we us our warrants to the customer you your that for a period of ninety 90 days from the date of shipment software provided by us in connection with equipment manufactured by us shall operate in accordance with applicable specifications when used with equipment manufactured by us and that the media on which the software is provided shall be free from defects We also warrant that A equipment manufactured by us shall be
133. tart a new acquisition sweep in the MCS Acquisition Unit When operating in MCS mode and configured for external sweep advance this input will advance counting from the current to the next MCS sweep This allows for either partial or full sweeps to be acquired Note that if the internal sweep completes before the EXT SWP ADV signal occurs then the accumulation of events stops until the EXT SWP ADV signal occurs PHA EXT START STOP IN This mode is restricted to a single GPIO connector Minimum pulse duration of 100 nanoseconds Polarity is software selectable for positive or negative logic The PHA EXT START STOP IN mode can be used to enable an external user supplied signal to start or stop data acquisition of the PHA Acquisition Unit Once the acquisition unit has been configured for external start stop control it can further be configured to accept pulses to Start Stop or Start amp Stop or DC level to Suspend amp Resume acquisition Start Once the PHA Acquisition Unit is enabled though a software Start command a pulse on this input begins the acquisition and storage of PHA events Acquisition continues until either a Stop command is received or a PHA preset Osprey Universal Digital MCA Tube Base GPIO Connectors condition time or counts has been reached After receiving the first Start pulse subsequent pulses have no effect Stop While PHA acquisition is in progress a pulse on this input will stop acquisition an
134. tem Status Stb Probe Connected Stb Probe Ready co HV On Co H V Ramping Information Device Information PHA Acquisition Status Busy MCS Acquisition Status Busy E N A Device Setup Idle E USB Network Setu N A Ethernet Network Setup iting Idle Preset Time Reach PresetIntegralReach Preset Sweeps Reach NIA Manual Stop l i i External Stop Manual Stop Overflow Stop UPnP Setup External Stop Device Upgrade FPGA Upgrade ii Overflow Stop co Group 2 Active co Ext Trg Event Group 1 Active Co Group 2 Active Co Ext Trg Event Firmware Upgrade Security Change Passwords Firmware Upgrade File Brows Checksum Upload Figure 32 Device Upgrade Parameters 68 Osprey Universal Digital MCA Tube Base Device Upgrade Installing the Firmware and FPGA Files Use these steps only if a new version of firmware has been recommended for your Osprey by an authorized Canberra service center These steps are abbreviated here as you will receive more detailed instructions with any updates from the Canberra service center product support personnel Note If a datasource is open in Genie it must be closed prior to performing any device upgrades CAUTION Do not power of
135. termined by the Input_ExternalSyncPulse parameter In MasterB mode the output will be a fixed 1 0 microsecond pulse rate Logic polarity of the EXT SYNC OUT signal is fixed at active high Multiple GPIO connectors can be configured for the EXT SYNC OUT function to extend the same output to multiple connectors IMPORTANT NOTE The EXT SYNC OUT function should be selected only to distribute the Sync Module s signal to other devices externally connected to this device via the respective GPIO connector The Sync Module s output within the device is always distributed internally to other acquisition units such as Aux Counter SCA Counters MSS unit and List TList unit whether or not the EXT SYNC OUT function has been selected Each acquisition unit within the device has an associated parameter to enable or disable external sync operation This function is not supported in Genie 2000 MCS EXT START STOP IN 21 MCSEXTSS_IN Function 21 configures the connector for input mode The MCS EXT START STOP IN function directs the GPIO connector to accept an external user supplied signal to synchronize the start or stop of the Osprey s MCS acquisition The Osprey supports both pulsed and level modes of external acquisition control The MCS input s external start stop logic must be enabled and configured for either pulsed DSA2K or level Lynx control mode through the Input_McsExternalControlMode parameter The pulsed mode behavior must
136. tes with the Osprey s keyway 2 Push the two parts together in a straight motion the mating parts should be snug but not difficult to assemble together Align the locking pin on the Osprey with the slot on the locking collar of the stabilizer detector 3 Slide the locking collar up so the locking pin meets the bottom of the slot 4 Twist the locking collar to the right until the locking pin comes to the end of the slot Note The stabilized detector will enter the internal calibration mode during the initial power up and at any time when the outside temperature changes significantly This state is indicated by the blinking Green HV LED on the Osprey s front panel If the stabilization occurs while the device is in active acquisition mode then the acquisition will become suspended until the detector has stabilized If the device is opened by Genie during this time then Genie will display Wait state in the datasource status area window and the acquisition elapsed time will stop advancing The acquisition will resume and proper elapsed time adjustments will be performed after the detector is stable again Refer to the NAIS 2X2 Nal Tl LED Temperature Stabilized Scintillation Detector User s Manual for the tube base pin configuration Communication Interfaces To use any of Osprey s communications interfaces connect the supplied cable between the Osprey and another device such as a hub or the host computer The appendix Communicati
137. the stabilization algorithm establishes a reference by taking a snapshot of the data relationship between the upper and lower sampling windows Thereafter the algorithm is designed to maintain the data relationship between two windows as close to the reference as possible by manipulating the internal high voltage control within an allowable range The stabilizer should be turned On after all other adjustments have been made A typical sequence for setting up the spectrum stabilizer is as follows 1 Adjust the coarse gain fine gain and detector s high voltage to select the desired energy range The detector high voltage must be On to activate the stabilizer User s Manual 7066438 41 Chapter 3 System Setup 42 With the Osprey acquiring data in PHA mode and a sample on the detector select the energy peak to be used as a reference by the stabilizer For best results the peak should be located in the upper half of the spectrum Enter the reference peak s centroid channel into the stabilizer s Centroid control If using Canberra s Genie Gamma Analysis application the Centroid channel can be read directly from the Marker Info page provided that the left and right markers surround the reference peak For best results the reference peak should be well defined with sufficient count rate to provide at least 2 1 peak to background ratio The selection for the Spacing value and Window width largely determine the effectiveness of the stabi
138. to its target voltage Once the target voltage has been reached it will change to white PHA Acquisition Status The following indicators provide status of the PHA acquisition of the Osprey The descriptions below describe the active state of the indicators Idle The device is not in acquire 60 Osprey Universal Digital MCA Tube Base MCS Acquisition Status Busy The device is in acquire or armed and waiting to start acquire Waiting Acquisition is armed but has not started because waiting for one of several events External Start External Sync or CANBERRA NAIS 2x2 LED stabilized detector performing internal calibration Preset Time Reach Acquisition has stopped due to preset time being reached Preset Integral Reach Acquisition has stopped due to computational preset being reached based on Integral value only The Manual Stop indicator will activate if Computational Preset was reached due to Area or Counts presets External Stop An external event has stopped acquisition Manual Stop Acquisition was stopped by pressing Acquire Stop in Genie 2000 The Manual Stop indicator will also activate if Computational Preset was reached due to Area or Counts presets Overflow Stop Acquisition was stopped due to PHA channel overflow counts Group 1 Active Device is in acquisition and group 1 is active Group 2 Active Device is in acquisition and group 2 is active Ext Trig Event An external event such
139. tomarily used for software interchange or User s Manual 7066438 109 Appendix F RTOS License Agreement 110 c Accompany it with the information you received as to the offer to distribute corresponding source code This alternative is allowed only for noncommercial distribution and only if you received the program in object code or executable form with such an offer in accord with Subsection b above The source code for a work means the preferred form of the work for making modifications to it For an executable work complete source code means all the source code for all modules it contains plus any associated interface definition files plus the scripts used to control compilation and installation of the executable However as a special exception the source code distributed need not include anything that is normally distributed in either source or binary form with the major components compiler kernel and so on of the operating system on which the executable runs unless that component itself accompanies the executable If distribution of executable or object code is made by offering access to copy from a designated place then offering equivalent access to copy the source code from the same place counts as distribution of the source code even though third parties are not compelled to copy the source along with the object code 4 You may not copy modify sublicense or distribute the Program except as expressly provided
140. under this License Any attempt otherwise to copy modify sublicense or distribute the Program is void and will automatically terminate your rights under this License However parties who have received copies or rights from you under this License will not have their licenses terminated so long as such parties remain in full compliance 5 You are not required to accept this License since you have not signed it However nothing else grants you permission to modify or distribute the Program or its derivative works These actions are prohibited by law if you do not accept this License Therefore by modifying or distributing the Program or any work based on the Program you indicate your acceptance of this License to do so and all its terms and conditions for copying distributing or modifying the Program or works based on 1t 6 Each time you redistribute the Program or any work based on the Program the recipient automatically receives a license from the original licensor to copy distribute or modify the Program subject to these terms and conditions You may not impose any further restrictions on the recipients exercise of the rights granted herein You are not responsible for enforcing compliance by third parties to this License 7 If as a consequence of a court judgment or allegation of patent infringement or for any other reason not limited to patent issues conditions are imposed on you whether by court order agreement or otherw
141. ured channels for the specified dwell time When the dwell time of the last User s Manual 7066438 3 Chapter 1 Introduction configured channel expires the acquisition will end if the sweep count has been reached or restart with the first channel if the sweep count has not been reached Pulses could be internally supplied by the PHA Acquisition Unit or from an external source via the external GPIO connectors AUX Acquisition Unit The AUX acquisition unit consists of a single programmable counter that counts externally supplied TTL pulses The counter may be programmed for manual or automatic operation or externally synchronized to other acquisition units SCA Acquisition Unit The SCA acquisition unit consists of six synchronized programmable counters each with independent energy windows that count events processed by the PHA Acquisition Unit The counters may be programmed for manual or automatic operation or externally synchronized to other acquisition units Acquisition Modes The Osprey supports the following acquisition modes PHA Mode The PHA Pulse Height Analysis mode acquires energy correlated data from a radiation detector to produce a histogram of 256 512 1024 or 2048 channels Each channel defined as an energy window is incremented by one for each event that falls within the window producing a spectrum which correlates the number of energy events as a function of their amplitude MCS Preset Mode The MCS
142. user supplied signal to start and or stop data acquisition of the MCS Acquisition Unit Once the acquisition unit has been configured for external start stop control it can further be configured to accept pulses to Start Stop Start amp Stop or DC level to Suspend amp Resume acquisition Software selectable modes are as follows Start Once the MCS Acquisition Unit is enabled though a software Start command a pulse on this input begins the acquisition and storage of MCS events Acquisition continues until the end of a sweep and the preset sweep counter is reached After receiving the first Start pulse subsequent pulses have no effect Stop While MCS acquisition is in progress a pulse on this input will immediately abort the acquisition and storage of MCS events prior to reaching the end of the current sweep If no stop pulse occurs acquisition and storage will continue until either a Stop command is received or the end of a sweep and the preset sweep counter has been reached After receiving the first Stop pulse subsequent pulses have no effect Start Stop Once the MCS Acquisition Unit is enabled though a software Start command a pulse on this input begins the acquisition and storage of MCS events A second pulse on this input will immediately abort the acquisition and storage of MCS events prior to reaching the end of the current sweep If no second pulse occurs acquisition and storage will continue until the end of a swee
143. way gt Ml Obtain DNS server address automatically s Use the following DNS server addresses Preferred DNS server A Alternate DNS server a ox Carcel Figure 39 IP Parameters for USB Setup IP 10 0 1 10 Subnet 255 255 255 0 All other entries are blank Note The 10 0 1 10 IP address setting assumes that you don t have any other device on your network currently set to this address If you do choose any other valid setting within your subnet mask range 1 255 but use 11 or higher as the lower numbers are most likely already assigned for some purpose For example if 10 0 1 10 conflicts change your entry to 10 0 1 11 or 10 0 1 15 or 10 0 1 27 etc 7 Press OK when done When the address has been assigned you ll be able to access the Osprey using the USB connection s static address 10 0 1 4 from Genie 2000 or your Internet browser User s Manual 7066438 91 Appendix B Communication Setup Note The next few steps are necessary to restore the default order of the local area connections in Windows When Osprey USB connection installs a new Local Area Connection in your system with a device name Canberra Osprey MCA Windows automatically puts this connection to the front of the network adapters binding order order in which all Windows applications will enumerate the local area connections This may cause problems for local VDM and other network dependent services 8 Inthe Network Connecti
144. with the functionality of the MCS EXT START STOP IN see Function 21 where the signal generated by the PHA s acquisition status changing state feeds the MCS start stop input logic to synchronize the MCS acquisition activity with the PHA s Polarity is fixed at active high for both functions The selection for this function is limited to a single GPIO connector Please refer to the individual function description for any additional information that may apply This function is not supported in Genie 2000 PHA EXT START STOP IN 17 and MCS EXT START STOP OUT 22 30 PHAEXTSS_IN MCSEXTSS_ OUT Function 30 combines the functionality of the PHA EXT START STOP IN see Function 17 with the functionality of the MCS EXT START STOP OUT see Function 22 where the signal generated by the MCS s acquisition status changing state feeds the PHA start stop input logic to synchronize the PHA acquisition activity with the MCS s Polarity is fixed at active high for both functions The selection for this function is limited to a single GPIO connector Please refer to the individual function description for any additional information that may apply This function is not supported in Genie 2000 STB PROBE I O 31 SPROBE IO Function 31 on GPIO 1 is a special case function that overrides the present GPIO configuration and redefines the GPIO connectors as follows GPIO 1 Probe RXD GPIO 2 Probe
145. xternal sync signal synchronizes the processing of PHA events with an external device such as another Osprey INPUT LEVEL SENSE The INPUT LEVEL SENSE mode can be used to detect the logic level on the designated GPIO connector The logic level is reported through the GPIO1_ Input GPIO2_ Input or GPIO3 Input parameter Any of the GPIO connectors can be configured for the INPUT LEVEL SENSE mode Output Assignments for GPIO Connectors This section describes the output assignment for the GPIO connectors The Incoming Count Rate pulse duration is 200 nanoseconds Polarity is fixed at positive logic Any combination of GPIO connectors can be configured for this mode Provides a positive output pulse to the designated GPIO connector s for each incoming event above the instrument s noise threshold setting The pulse width is 200 nanoseconds The noise threshold is selectable as automatic determined by the Osprey or manual set to a value selected by the user SCA 1 6 The Single Channel Analyzer pulse duration is 200 nanoseconds Polarity is fixed at positive logic Osprey Universal Digital MCA Tube Base GPIO Connectors The SCA1 SCA6 modes direct output pulses generated from energy events that fall within the respective SCA s energy window to the selected GPIO connector s Pulses occur if the events have energy between the SCA s upper and lower level discriminator ULD and LLD setting Any combination of GPIO connectors
146. y e g OSPREY 01 up to 8 contiguous characters maximum verify Enable UPnP check box is selected and press Submit 3 Under Device Setup click on Ethernet Network Setup Select the DHCP option then press Submit to save this change Once this has been performed log off the Osprey unit 4 Now change the Ethernet cable on the Osprey from the Red Cross over CATS cable to the Yellow CATS cable to the standard IP network connection Set your PC to utilize DHCP via its NIC This requires using a standard Ethernet cable 1 On your PC right click the My Network Places icon then select Properties 2 Right click on the Network Adapter icon then select Properties 3 On the General tab select Internet Protocol TCP IP then select Properties 4 Select the General Configuration tab select the Obtain an IP Address Automatically option Press OK to keep this setting User s Manual 7066438 85 Appendix B Communication Setup 5 In My Network Places if UPnP has been installed you will see the Osprey unit as a peripheral similar to a printer connected to the network with the name Osprey or the new name if changed Double clicking or selecting this unit or name will start your browser and open the Osprey Web Status page If not start your browser and type in the IP address of your Osprey instrument in the URL section you should then see the Osprey Web Status page Firewall Setup for Genie 2000 Genie 2000 drive
147. y exception to this limited license BACKUP COPIES Our software is protected by United States Copyright Law and by International Copyright Treaties You have our express permission to make one archival copy of the software for backup protection You may not copy our software or any part of it for any other purpose Revised 1 Apr 03
Download Pdf Manuals
Related Search