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sat-nmsACU-ODU-DC Antenna Control Outdoor Unit DC User Manual
Contents
1. Parameter Description Name Axes The ACU knows two axes control modes The PARALLEL mode treats the control azimuth elevation axes independently If a new pointing is commanded both motors are mode activated in parallel the antenna moves to the new location in the shortest possible time In SEQUENTIAL mode the ACU does not move the elevation axis while the azimuth motor is running The antenna movement is done sequentially First azimuth then elevation You should prefer the PARALLEL mode unless special conditions require a sequential antenna movement The performance of the ACU in terms of pointing speed and wind load compensation will be much better in PARALLEL mode Date By changing this value you can set the internal clock of the ACU The clock is set as soon time you click to the Submit button in the data entry dialog The most precise method to set the RS485 address time is to enter atime one or two minutes ahead and click to Submit when this time is reached With this parameter you select the device address used control the ACU through a serial interface See chapter 7 3 The RS232 remote control interface for more information about this At ACU RMU and ACU19 this parameter has to be set to NONE If you use a sat nms Handheld this parameter has to be set to TERM The Handheld function is not implemented in ACU RMU and ACU19 Version Watchdog pulse on AUX8 Display refresh Note The AU
2. Do two steps in direction B WORSE DONE Do another step in direction B WORSE DONE Do a last step in direction B DONE The diagram above shows the sequence of steps the tracking algorithm performs in one cycle on one axis It starts with a depointing step in one direction A If this step lets the signal level decrease the antenna makes a double step in the opposite direction It the first step leads to a better receive level the tracking algorithm adds one or two steps in the same direction For a reliable tracking operation the step size have to be big enought to rech the maximum within the 3dB bandwith within in the entered cycle time This meas for an inclient satellite you need a shorter cycle time than for a geostationary satellite 8 3 2 ACU and Beacon Receiver To perform a step track the ACU requires the actually measured beacon level as a rate of the received C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 52 64 SatService Gesellschaft fiir Kommunikationssysteme mbH signal quality and therefore the closeness of the antenna pointing to the ideal value The sat nms ACU is capable to be operated both with the sat nms LBRX beacon receiver and with third party beacon receiver products With a third party beacon receiver the ACU reads the beacon level from an analog voltage input The beacon receiver therefore must provide a dB linear output voltage preferably in the range 0 10V
3. SatService Gesellschaft fiir Kommunikationssysteme mbH out manner How many days of tracking data fits into the memory depends on the tracking interval The diagram below shows the memory depth vs the tracking interval 12 18 Tracking memory depth days a B 2 4 6 8 18 12 14 Tracking interval minutes The tracking memory is volatile it is erased when the ACU gets reset or switched off Saving the tracking memory in regular intervals to the ACU s flash memory would damage the flash memory quite quickly Memory reset The contents of the tracking memory must be erased when the ACU starts to track a new satellite This is done in the following situations e Astored position target is recalled e The ACU is switched off e CLEAR MEMORY is chosen at the tracking parameters page If a new antenna position is entered by setting the azimuth elevation angles explicitly the ACU does not know the new position is a manually optimized one for the current satellite or the position of another satellite The tracking memory is not erased in this situation If the new position belongs to a new satellite the tracking memory must be erased manually by clicking to CLEAR MEMORY at the tracking parameters page Beside this it is recommended to perform a CLEAR MEMORY about half an hour after tracking a satellite starts the first time This erases the first search steps to the satellite s position and significantly improves the quality
4. reserved for beacon receiver frequency select 30 OUT_AUX7 not used 31 OUT_AUX8 not used The meaning of the FWD REV motor control outputs depend on the motor control mode set for this axis Bit definitions in tflt tracking faults The tflt value is returned as a 8 bit hexadecimal number The bit number 0 means the least significant bit bit number 7 the most significant bit in this number description no name C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 47 64 SatService Gesellschaft fiir Kommunikationssysteme mbH APEAKFLT azimuth peaking fault EPEAKFLT elevation peaking fault MODELFLT model match fault JITTRFLT jitter fault 0 1 2 4 5 6 7 not used not used not used not used Tracking coefficients on acoe ecoe In adaptive tracking mode the acoe ecoe commands may be used to read the coefficients of the actual model The coefficients are returned as a comma separated list of numbers in scientific notation The number o f coefficients returned depends on the size of the model SMALL a0 a1 a2 1 MEDIUM a0 a1 a2 a3 a4 2 LARGE a0 a1 a2 a3 a4 a5 3 If the beacon signal drops below it s theshold the antenna movement is calculated from these coefficients using the formulas shown below Aa aata cos wt a sin wt 1 Qyectium Ay a cos wt a sin ot a
5. SMALL a0 a1 a2 1 MEDIUM a0 a1 a2 a3 a4 2 LARGE a0 a1 a2 a3 a4 a5 3 If the beacon signal drops below it s theshold the antenna movement is calculated from these coefficients using the formulas shown below Aal Zara cosl wt a sin ot Qnedium Ay 4 cos wt a sin wt a cos 2 wt a sin 2 wt Furge Ag a cos wt aysin wt a cos 2 wt a 4sin 2 wt ast Hardware Test Page Example Outputs AZ AZ AZ AZ AZ AZ motor motor motor motor motor motor forward reverse speed 1 speed 2 reset reserve Auxiliary output Auxiliary output motor motor motor motor motor motor forward reverse speed 1 speed 2 reset reserve Auxiliary output Auxiliary output Flags AZ moving EL moving POL moving AZ motor timeout EL motor timeout POL motor timeout AZ coefficients EL coefficients 9 6 Setup 1 2 3 4 2 19094E 02 Outputs POL motor POL motor POL motor POL motor POL motor POL motor Auxiliary Auxiliary Summary OK Tracking O Beacon RX Beacon RX Beacon RX Beacon RX Auxiliary Auxiliary Analog Temperatur Beacon lev Nick Roll forward reverse speed 1 speed 2 reset reserve output output K preset preset preset preset output output e el AZ raw pointing EL raw pointing POL raw pointing 6 On hWN 1 2 3 Inputs LO POL limit switch H HI LO POL limit switch L HI LO POL motor fault HI LO Antenna hub fault HI LO
6. These settings let you limit the adaptive model to a simpler one the ACU EL Maximum model type would choose by itself The maximum model type can be set individually for each axis Normally you will set both axes to LARGE which leaves the model selection fully to the ACU s internal selection algorithms In cases where the ACU seems to be too optimistic about the quality of the step track results the maximum model on one or both axes may be limited toa more simple and more noise resistant model Specially inclined orbit satellites which are located close to the longitude of the antenna s geodetic location may require this limitation for the azimuth axis With such a satellite the elevation may move several degrees while the azimuth shows almost no motion Level threshold If the beacon level falls below this threshold value the ACU does not perform a step track cycle If the level falls below the threshold during the steptrack cycle the cycle gets aborted If the ADAPTIVE tracking is enabled and there is enough data in the tracking memory the ACU computes a mathematical model from the stored data and predicts the antenna pointing position from the extrapolation of the model If the tracking mode is set to STEP the ACU leaves the antenna where it is if the beacon level drops below the limit Adjusting the threshold level that adaptive tracking is switched as expected must be done carefully and may require some iterations specially i
7. 0 000 90 000 PO Step delta 90 000 90 000 E Pol target value 0 32000 PO Motor timeout character string Admin password pwdu character string User password C 2014 SatService GmbH WWWw satnms com ACU ODU DC UM 1411 Page 43 64 SatService Gesellschaft fiir Kommunikationssysteme mbH roll r o 90 0 90 0 2 Roll angle rolo 90 0 90 0 E Roll offset save 0 99 Save target sent r o 0 65535 Save count 0 65535 Sleep time up to the next tracking action srno r o character string Device serial no stim character string Date time 6 character string Smoothing interval Software version HA Tracking model age tdly 100 9999 HH Tracking cycle time msec Recovery delay Temperature 0 99 character string Target description 7 HH Tracking fault bits described below Tracking memory character string Date time 6 Log to tracking memory OFF STEP ADAPTIVE MEMORY PROGRAM trty NEVER ONCE FOREVER Tracking retry on fault tnam character string Target name trst 1 1 Tracking mode 8 Reset tracking C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 44 64 SatService Gesellschaft fiir Kommunikationssysteme mbH memory trty NEVER ONCE FOREVER Tracking retry on fault tsta r o character string Tracking state Tracking st
8. 0 1 rmt levl Will let the ACU reply the actual beacon level in a one line text document levl 52 31 This way all parameters may be queried or set you may use your favorite web browser to try out the remote control of the ACU manually 7 3 The RS232 remote control interface Beside the network interface the ACU also provides an RS232 serial port which can be used to control the device remotely Depending on the device address set the ACU either runs framed protocol with start stop characters and checksum or it provides a dumb terminal interface The RS232 interface always operates at 9600 baud no parity 8 data bits one stop bit This interface is not yet implemented in the ACU19 and ACU RMU At these versions you have to select NONE to enable the function of optional frontpanel display and keyboard If another setting is selected an optional frontpanel and keyboard has no function If an address A G is selected the ACU expects each message it receives to be packed into a frame as described below description start character always device address A G first character of the message body message body last character of the message body end character always checksum The checksum byte is calculated using an algorithm as implemented by the following formula sum 32 3 byte i 32 modulo 95 2 even i 1 This protocol type is known as MOD95 or Miteq
9. 000 90 000 EL Step delta El target value 0 32000 EL Motor timeout 0 99 EL tracking step size Goto target NONE GPS receiver type 3 00000000 FFFFFFFF Input bits described below Inclinometer type 4 Peak jitter threshold Measurement delay 1 stops all motors STOP at the Web UI 0 releases the stop RESET at the Web UD niko 90 0 90 0 90 0 90 0 Nick angle Nick offset C 2014 SatService GmbH WWWw satnms com ACU ODU DC UM 1411 Page 42 64 SatService Gesellschaft fiir Kommunikationssysteme mbH note character string Note obit 00000000 FFFFFFFF Output bits described below orbt 180 000 180 000 E Orbit position pcal 360 000 360 000 s PO Calibration offset pele s Calculate offset from Pol value pent 0 65535 Peak count phys 0 000 10 000 9 PO Pointing hysteresis NORMAL INVERTED PO Sense invert 0 000 180 000 PO Upper limit 180 000 0 000 PO Lower limit DUAL START DIR START NONE PO Motor driver type 90 000 90 000 00000000 FFFFFFFF r o praw r o 0 000000 100000 000000 SSI 19G SSI 20B SSI 20G SSI 24B VOLTAGE NONE SSI 13B SSI 13G SSI 17B SSI 17G SSI 18B SSI 18G SSI 19B PO Pointing PO pointing PO Calibration scale Taw PO Position SSI 24G RESOLVER sensor type PO Low speed threshold pstp
10. Collect Mode Help E Cont Halted Sorted by Snr Open popup menu with right mouseclick at table rows 5 The serial number of the core module shown in the first column of the list If the list stays empty the ACU is not connected properly If there are more entries in the list the configuration program has found other devices in this network segment which use the same technology 6 Now open with a right click the sub menu IP configuration to open the IP configuration window of the program In this form the ACU s MAC address is shown on top below you find the fields to configure the new IP address and network mask If the ACU later shall be operated through a router enter the address of the router on the gateway field otherwise leave this field blank Be sure that the DHCP mark is unchecked the other values have to be set as shown on the picture Finally click to the Yes button to set the new parameters at the ACU IP configuration by serial number or MAC ID Serial number or MAC ID 003056806914 Chip IP AA Help IP Address 192 168 2 81 Network mask 255 255 255 0 Gateway 192 168 2 254 Interface 2 Index jo f Use DHCP Configure default ethernet interface Now the IP configuration of the ACU is completed You may finally want to test if the ACU is reachable now Start your web browser and type the ACU s IP address into the URL field of the browser The ACU should reply with it s main page provi
11. For using the sat nms ACU ODU in very hot regions it is possible to equip the sat nms ACU ODU with an optional temperature controlled fan By this way it is possible to ensure the availability of the sat nms ACU ODU in hot ambients ATTENTION If the unit is equipped with an optional air ventilation avoid contact with jets of water rain is no problem Through the build in ventilator the protection class is only IP54 The thermostat for the fan is normally set to 40 C that means the fan switches on as soon as the temperature of the cabinet raises above 40 C We strongly recommend not to set this threshold below 40 C The reason for this is that in the winter the heater and the fan work against each other In worst case the fan and the heater run parallel over a longer time This behavior is avoided through setting the fan threshold to 40 C C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 10 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 4 Installation The following chapter describes how to install the ACU ODU mechanically and electrically Additional a detailed start up procedure is given in this chapter 4 1 Mechanical installation The sat nms ACU ODU is integrated into an outdoor cabinet that could be mounted outside directly at the antenna There are 2 possibilities to mount the sat nms ACU ODU e If you mount the sat nms ACU ODU to a plain wall make sure that the cabinet has a minimum distance of
12. PO Upper limit Beacon RX IP address Beacon RX O level Antenna longitude Antenna latitude Antenna abs altitude Inclinometer type Roll offset SNMP system name SNMP system location SNMP system contact MIB File SNMP trap IP 2 SNMP trap IP 4 Admin password 2011 05 16 12 30 56 TERM SatService GmbH ACUODM MIB 192 168 2 14 0 0 0 0 BARRERA SatService Gesellschaft fiir Kommunikationssysteme mbH The antenna may be moved by means of the optional handheld controller The Handheld function is not yet available at ACU RMU and ACU19 Version Startup Set parameter RS485 address on the ACUs Setup page to TERM This enables communication between the ACU and the sat nms handheld Connect the Handheld with the provided cable Handheld 9pol DSUB Power supply ACU Cabinet 15pol DSUB After connecting the Handheld push the Redraw button once The start up screen that shows the C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 34 64 SatService Gesellschaft fiir Kommunikationssysteme mbH installed software version is displayed for a few seconds After that the menu for controlling the antenna is displayed automatically Operation 1 START STOP RESET REDRAW POL STEP POL CCW SIZE cw sat nms ACU Handheld www satnms com STOP Emergency STOP stops all Motors immediately it has to be released by pushing the button RESET Releases the
13. a significant degradation of the resolver s accuracy CON18 CON19 CON20 SSI Positional Encoder Interface Below the pinout of a SSI type positional encoder interface board is shown The ACU is available with resolver SSI or analog position sensor interfaces You have to select type of interface when you order the ACU The SSI positional encoder may be powered from the ACU internal power supply 5V and 24V clamps are provided at the connector To avoid ground loops the cable shield should be connected either to pin 1 at the ACU or to the ground at the encoder housing never at both ends pin signal description type GND SSI Data SSI data IN SSI Data SSI data IN SSI CLK SSI clock OUT SSI CLK SSI clock OUT 5V encoder power supply 24V encoder power supply CON18 CON19 CON20 Analog Angle Sensor Interface C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 12 64 SatService Gesellschaft fiir Kommunikationssysteme mbH Below the pinout of an analog type positional sensor interface board is shown The ACU is available with resolver SSI or analog position sensor interfaces You have to select type of interface when you order the ACU pin signal AGND INPUT REF reference voltage OUT AGND analog ground OUT 15V opt optional DC out OUT 15V opt optional DC out OUT 9V opt optional DC out OUT GND digital ground OUT description type analog groun
14. air ventilation 20 to 55 C with optional air ventilation IP66 without optional air ventilation IP54 with optional air ventilation 380x235x680mm width x depth x height including roof depending on power supply approx 22kg SatService Gesellschaft fiir Kommunikationssysteme mbH C 2014 SatService GmbH Wwww satnms com ACU ODU DC UM 1411 Page 64 64
15. chapter 5 6 Setup 4 3 4 Motors Before you connect the motors to the sat nms ACU ODU take care that the circuit breakers for the frequency inverters motor drivers or conductors are in off position before connecting the motors 1 Connect the motors to the sat nms ACU ODU as described in chapter 4 2 3 2 Connect the emergency stop button to its terminals see chapter 4 2 2 If you do not have one take care that these terminals are bridged Without a connection between these pins the power supply of the motors is disabled 3 Press the STOP button on the sat nms ACU ODMs website By this you can be shure that no motor movement will occur by switching on the circuit breakers 4 Turn on circuit breakers of the frequency inverters they have to run now 5 Check the motor rotating directions if necessary change it by interchanging the power wires of the motor cable 6 Drive the antenna in every direction AZ EL and POL until the limit switches stop the motor movement to ensure that the limit switches work well ATTENTION While doing this test it is absolutely necessary to be very mindful to check if nothing collides 7 Set the soft limits to the desired values e g 1 before the hardware limit switch is activated If you need more detailed informations about the motor drivers please refer to chapter 3 4 4 3 5 Pointing Tracking Now the setup of all interfaces to the antenna is done By this everything is prepared to configure th
16. coupling and Accuracy alignment error should not exceed 0 003 to achieve the specified tracking accuracy The influence of antenna structure thermal error is not considered System Interfaces to M amp C and ACU IDU 4 6 drive limit switches angle detectors and Emergency Stop DSub9 female limit switches DSub9 male MNC RJ45 analog beacon SMA female Mains UPS HAN A 3pol PE male Motor mains HAN B 6pol PE male AZ EL Motors HAN B 6pol PE female POL Motor HAN A 3pol PE female Ethernet Azimuth Elevation and Polarization Emergency stop terminals and motors off switch 2 3 angular Azimuth Elevation and Polarization detectors Motor driver DC motor drivers depending on power supply up to 35VDC 15A optional 48VDC 15A standard power supply is 24VDC 10A optional local Handheld with display and keyboard operation M amp C Interface Specification Ethernet interface for M amp C and user interface 10 Base T Via http GET requests RS232 RS422 M amp C Interface Mini Combicon MCV1 Summary fault indication Relay contact Mini Combicon MCV1 Electrical and Mechanical Specification Environmental Conditions Supply voltage mains 230V AC 3A with standard motor power supply C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 63 64 Temperature range Humidity protection class dimensions cabinet Weight 20 to 35 C without optional
17. fault flags All target angles are set to the actual value to suppress an immediate movement of the antenna If a TIMEOUT or FAULT occur during a tracking cycle in one axis and the cycle is canceled the ACU will retry after 2min again according to the setting of Retry after motor fault NEVER ONCE FOREVER The retry is a RESET which activates the MOTOR RESET outputs of all three axes for a quarter second and delete the fault flags All target angles are set to the actual value to suppress an immediate movement of the antenna This is also valid for tracking faults like a PEAKING FAULT If a fault stay active in one axis and don t disappear during a RESET the tracking stops the operation For example if the polarisation have a fault azimuth and elevation stop the tracking operation C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 62 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 9 Specifications Technical Specification Position Encoding with three different interfaces via daughter boards Resolver digital SSI and potentiometer Quantization Error Resolver 16bit 0 0055 SSI 13bit 0 044 16bit 0 0055 17bit 0 0028 19bit 0 0007 Display Position resolution Interface to beacon receivers selectable 0 001 sat nms LBRX or analog voltage input Analog voltage 0 to 10V input Option Tracking Better than 5 of receive 3dB beamwidth RMS The encoder
18. level range to the scale and offset provided by the beacon receiver If at the beacon receiver these values may be adjusted too a preferable scale is 0 5V dB for 20dB usable range The offset should be adjusted that the receive level at clear sky conditions leave a headroom of 3dB at the top end of the range The analog voltage never should reach the physical limit of 0V 10V under normal conditions Clamping the level voltage probably will misslead the tracking 8 3 3 Smoothing The peak positions found by the step track may jitter due to noise Specially if an almost stable positioned satellite is tracked with a relatively small antenna this jitter may be more than the real movement of the satellite To stabilize the tracking in such situations the sat nms ACU provides a smoothing function which lets you reduce the pointing jitter The smoothing function is based in the fact that most satellites specially that ones which are on a stable C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 53 64 SatService Gesellschaft fiir Kommunikationssysteme mbH orbit position require the antenna to follow a small amplitude sine function with 24 hours cycle time in order to track the satellite optimally If you activate smoothing by setting the smoothing time to a non zero value all peak positions of the last n hours get averaged by a sine function which matches the measured peaks at the best After each step track cycle the anten
19. like shown on the following picture On the left side you see the computers file system GACHIPTOOL FTP Client File View Connection PRO RBA an o Drive Ic y NRPN FB HOME Filename Size Time Fiename DIRECTORY 30 05 2011 15 2 DIRECTORY 30 12 1899 00 0 IMAGES DIRECTORY 01 01 2006 00 0 ACUODM MIB 32756 20 05 2011 12 4 app dat 25 05 2011 15 4 HELP HTM 23092 01 01 2006 00 0 INDEX HTM 396 01 01 2006 00 0 info htm 617 20 05 2011 12 4 KEYS GIF 3752 01 01 2006 00 0 NAVBAR HTM 2547 01 01 2006 00 0 NAVBARBG GIF 268 01 01 2006 00 0 STOP GIF 347 01 01 2006 00 0 target txt 241 01 01 2006 00 0 target 0 txt 245 24 05 2011 14 0 target 1 txt 240 01 01 2006 00 0 target2 txt 214 25 05 2011 09 3 target28 txt 241 25 05 2011 09 4 target3 txt 214 25 05 2011 09 4 TB ERASE GIF 190 01 01 2006 00 0 TB GO GIF 70 01 01 2006 00 0 TB SATEL GIF 108 01 01 2006 00 0 TB SAWE GIF 143 01 01 2006 00 0 Connected to 192 168 2 77 C 2014 SatService GmbH WWww satnms com ACU ODU DC UM 1411 Page 18 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 6 Browse on the left side to the desired location to which you like to save the backup 7 Right click the app dat file and choose copy in the drop down list The file will immediately be copied to the location shown on the left side If you have saved targets you might backup them in the same way They are named tar
20. make ACU and beacon receiver work together you should take care of the following e ACU and beacon receiver must be connected to the same Ethernet segment e Both devices must have assigned IP addresses in the same subnet e The LBRX beacon receiver must be configured for the correct LO frequency The displayed receive frequency must be the true RX frequency rather than the L band frequency e At the sat nms LBRX the ACU s IP address must be set as the UDP destination address The setting VOLTAGE is used with any other type of beacon receiver or with a sat nms LBRX beacon receiver which has no TCP IP connection to the ACU When operating in SATNMS mode the ACU will automatically determine the beacon frequency from the sat nms beacon receiver Also the beacon receiver s background activities like frequency tracking and noise reference measurements get synchronized to the step track sequence in this mode These features are not available in the VOLTAGE operating mode Beacon RX IP address You need to enter the beacon receiver s IP address in dotted quad notation here if the receiver tape is set to SATNMS Beacon RX voltage scale These parameters define the slope and offset of the beacon level voltage The Beacon RX OV level values must be set to match settings of the beacon receiver With the sat nms LBRX beacon receiver you can set these parameters there as well chapter C 2014 SatService GmbH www satnms c
21. of web pages which make up the ACU user interface and elaborately describe the meaning of each alterable parameter e Frontpanel Operation The sat nms ACU19 and the sat nms ACU RMU optionally are equipped with a frontpanel Human Machine Interface This chapter describes how to use this interface e Remote Control The ACU outdoor module provides a versatile remote control interface A monitoring amp control software may fully operate the ACU either through a TCP IP network connection or through the RS232 interface of the ACU This chapter describes the communication protocol used for remote control and lists all parameters accessible through the remote interface e Theory of Operation This chapter gives a short overview how the ACU works It also describes the different tracking algorithms and their parameters The interaction with a beacon receiver is described as well Knowing about the theory regarding this functions helps to find the best parameter settings for a given application e Specifications At the end of the document the specifications applicable to the sat nms ACU are summarized in this chapter Support and Assistance If you need any assistance regarding our ACU don t hesitate to contact us We would be pleased to help you by answering your questions SatService GmbH phone 49 7738 9700 3 or 4 Hardstrasse 9 fax 49 7738 97005 78256 Steisslingen www satnms com 2 Germany satnms support satservicegmbh de Ver
22. of the first adaptive model which will be calculated 6 hours later Saving the memory contents The ACU provides one persistent memory location where the tracking memory may by saved into on an operators request This may be useful to track another satellite for a couple of hours and then to return to the first satellite If the tracking memory has been saved before the antenna has been moved to the second satellite it may be restored after the antenna returned to the old position To use this feature store the ACU settings to the target location 0 Target memory page This saves the tracking parameters and the tracking memory as well When this memory location is recalled later on the C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 59 64 SatService Gesellschaft fiir Kommunikationssysteme mbH parameters and the memory contents are restored With this function you should keep in mind that the tracking memory contents becomes useless after about 24 hours 8 4 3 Adaptive Tracking Parameters The behaviour of the adaptive is adjustable with a couple of parameters First adaptive tracking also is a step track algorithm The parameters described in chapter 8 3 4 Steptrack Parameters therefore apply to the adaptive tracking as well The parameters concerning the adaptive tracking in particular are discussed in the table below All parameter described here are to be set at the Tracking page AZ Maximum model type
23. of the software Help Clicking to this button shows the on line version of this user manual Step Move Clicking to the buttons in this area moves the antenna a small step to the indicated direction For azimuth and elevation small step and large step buttons are provided A small step is the angle defined with the XX step delta parameters at the Setup page a large step is ten times this value With the polarization axis steps always are 1 STOP Clicking to the STOP button immediately stops all motors The ACU indicates a fault A click to the RESET button releases this fault C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 20 64 SatService Gesellschaft fiir Kommunikationssysteme mbH RESET The RESET button lets the ACU acknowledge any motor diver faults by activating the reset circuit to the motor drivers for 800 msec All faults internally latched by the ACU are cleared and the target pointing values are set to the values actually read from the position sensors 5 2 Antenna Pointing The Pointing page is the main page of the ACU user interface which shows the actual antenna pointing and some status information The Pointing page automatically refreshes once a second The refresh rate may be adjusted on the setup page from software version 2 1 007 or higher The table below describes the information shown by this page Parameter Description Name Azimuth The bold printed figures s
24. second sine wave with the double frequency two cycles for one sidereal day The model matches very good for almost all stationary satellites It however requires more and also more precisely measured data points to give reliable results The MEDIUM model is fully compatible to the SMALL one this means that also satellites for which the antenna must follow a plain sine function may be tracked with the MEDIUM model The amplitude of the double frequency sine simply is near zero in such a case Finally the LARGE model adds a linear movement to the components of the MEDIUM model This is required to track significantly inclined satellites over a period of several days Such satellites tend to drift in their position the linear movement component can compensate this effect for a couple of days The LARGE model is the most demanding one concerning the step track data it is based on Mo del selection The ACU normally by itself selects the adaptive tracking model for each axis individually The decision which model will be used in case of a beacon drop out is made based on the amount and quality of the data in the tracking memory The quality of the recorded data mainly depends on the amplitude of the antenna movement If the satellite moves only a small amount in 24 hours the uncertainty of the step track peaks is quite high compared to this amplitude The ACU compares the movement amplitude to the antenna s half 3dB beam width to evaluate this measur
25. which matches the polarity the motor driver expects Very important is how the direction of movement is wired The proper direction depends on if the antenna is operated on the northern or on the southern hemisphere axis northern hemisphere southern hemisphere azimuth FWD moves the antenna to the right FWD moves the antenna to the left westward westward elevation FWD moves the antenna up FWD moves the antenna up polarization FWD turns the feed clockwise FWD turns the feed counterclockwise Look through the antenna to the satellite for the correct orientation of the left right clockwise directions The sense of the position sensors must set that the sensors give increasing values while the antenna moves FWD 8 3 Steptrack sat nms ACUs having the ACU ODM Software Upgrade Step Track installed are capable to track a satellite s position The following paragraph describes how the sat nms steptrack algorithm works Beside plain step track this option includes the so called adaptive tracking and a file program tracking facility as well While step track and adaptive tracking require a beacon receiver to be connected to the ACU the file program tracking works without any beacon measurement 8 3 1 The sat nms Steptrack Algorithm The principle of satellite step tracking is quite simple For each axis move the antenna a small amount away from the satellite move it a small amount to the other site and final
26. 2 The TCP IP remote control interface 2 2 eeeeeecececceccecececeeecececececeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeee ss 37 1 3 The RS232 remote control interface nisc onionenn g on aK RO O EEA OKS aE aan 38 TA Parameter list tacita aa a Sumas a a a sh e e a ae aiaa wks aa a E aai a 39 Ty On line read via TCP IP m e eea E are nenn ale ent es 48 C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 1 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 8 Pheory Of Operation ns tddi lbs 48 8 1 Angle Measurement u akeraltilestinehtiiieilbeltinlunttleihin Shall 49 8 2 Pointing Motor Control u 2 ed 50 8 3 Ste pirack O nated eit 51 8 3 1 The sat nms Steptrack Algorithm serseri iie a a E E E EE T E 51 8 3 2 ACU and Beacon Receiver 0082 sn E Sa 52 OEE i010 01n aiT o E E EEEE E E A ET 53 8 3 4 Steptrack Parameters eslora di ii ts 54 8 4 Adaptive Tracking siciliana 56 8 4 1 The sat nms Adaptive Tracking Algorithm 0oooooononononononononanononononononononononononononononononnnonnnnnnnnnos 56 8 4 2 The Tracking Memoria ee Saas ee i ae eee bos i 58 8 4 3 Adaptive Tracking Parameters ceeeeeeeeececececececccececeeecececeeceeeeeccceeececeseeeeeeeeeeeeeeeeeeeserees 60 8 5 Program Tracking ans r 20a nokia HR an 61 8 3 1 Practical US a ge iieii ssvoess O etsene dobvossbisevoess obedesk 6 61 8 9 2 Pile Format ns O E 61 6 Faults and Tracking 2 0 0 ev un een eh cede ee ea all ea 62 OSPSCHIC
27. 5mm to the wall to ensure that the rain roof will not be damaged through mounting the cabinet e If you mount the sat nms ACU ODU to an antenna mast first fix 2 strong metal bars e g C Bars in horizontal direction to the mast After that fix the sat nms ACU ODU to these metal bars Use at least M8 or comparable screws to fix the sat nms ACU ODU On the following picture you can see an example where the sat nms ACU ODU is fixed to the antenna mast with C Bars and according special nuts These C Bars can optionally be ordered at SatService i mounting gif 4 2 Interfaces to the Antenna Pin descriptions ATTENTION Electrical installation shall be carried out only by qualified personnel who are instructed and aware of hazards of electrical shocks The terminals of the sat nms ACU ODU are located at the lower side of the case The angle encoders and limit switches have to be connected directly at the sat nms ACU ODM the core module of the ACU ODU The Motors have to be connected directly to the motor drivers Please refer to the schematic of the sat nms ACU ODU that has been delivered to you It shows you where to connect all the units and the mains 4 2 1 Angle encoder connection The angle encoders have to be connected directly to the core module of the sat nms ACU ODU which is called sat nms ACU ODM Inside the sat nms ACU ODM consists of a main board and two or three interface boards with the circuitry for the position sensors These bo
28. ACU ODU DC UM 1411 Page 13 64 SatService Gesellschaft fiir Kommunikationssysteme mbH Z Z El High upper limit Elevation I I IN polarization right limit view from behind antenna polarization left limit view from behind antenna 4 2 3 Motors connection Connect the azimuth elevation and if available polarisation motors directly to the motor drivers Use shielded cable only Take care that the shield is connected to the PE terminal of the motor driver and is NOT connected to the crankcase Please refer to the schematics shipped together with your sat nms ACU ODU for more detailed informations and pin descriptions The ACU knows two different configuration modes to control a motor driver They are called DIR START and DUAL START In DIR START mode the FWD signal switches the motor on off the REV signal controls the motor direction This is the configuration many frequency inverters use In DUAL START mode the FWD signal switches the motor on in forward direction REV activates the motor in reverse direction This configuration mode is convenient to control a motor with relays At sat nms ACU ODU it has to be configured as DUAL START for AZ EL and if available for POL drive 4 2 4 Mains connection Connect mains to the terminals at the lower side of the cabinet Please refer to the schematics shipped with your sat nms ACU ODU for detailed pin description 4 2 5 Ethernet connec
29. AUONS ic ee EE A E td ita 62 C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 2 64 SatService Gesellschaft fiir Kommunikationssysteme mbH C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 3 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 1 Introduction The sat nms Antenna Control Unit is an antenna controller positioner with optional satellite tracking support It may be operated as a standalone unit or in conjunction of the sat nms ACU IDU a PC based indoor unit which offers extended tracking capabilities and a full featured visualization interface The sat nms ACU is available as e sat nms ACU ODM only the core module integrated in a compact case prepared for mounting on a 35mm DIN rail e sat nms ACU ODU complete antenna controller system for AC or DC Motors integrated in an outdoor cabinet that could be mounted directly to the antenna By mounting a sat nms LBRX beacon receiver into this cabinet you have a complete antenna tracking system in a compact cabinet directly at your antenna e sat nms ACU RMU complete antenna controller system for AC Motors integrated in a 6RU 19inch rack mount case for indoor use e sat nms ACU19 complete antenna controller system for DC Motors integrated in a 1RU 19inch rack mount case for indoor use For detailed description please refer to the sat nms documentation CD or www satnms com doc Main benefits of the sat nms ACU are e The ACU
30. Auxiliary input 1 LO HI Auxiliary input 2 LO LO Auxiliary input 3 LO LO Auxiliary input 4 LO HI AZ limit switch H HI HI AZ limit switch L HI LO AZ motor fault HI LO Emergency stop HI LO EL limit switch H HI LO EL limit switch L HI LO EL motor fault HI HI Cabinet door open HI 36 7 C 82 53 dBm BIn2 90 0 1D1A0000 84660000 E3840000 1 21731E 02 2 26467E 02 2 75028E 01 4 54165E 02 2 37250E 02 The page Setup contains the ACU s installation parameters The page displays a table with the parameters actually set Each parameter value is a hyper link to a separate page which lets you change this parameter This parameter change page shows the actual parameter setting either in an entry field or in a drop down box You may change the parameter to the desired value and then click to the Submit button to pass the changed value to the ACU ODM The ACU automatically returns to the setup page when the parameter has been changed To cancel a parameter modification you already started either use the Back button of you web browser or click to the Setup button on navigation bar Both returns to the setup page without changing the parameter you edited C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 28 64 SatService Gesellschaft fiir Kommunikationssysteme mbH The table below lists the settings provided by this page General This section of the setup page contains some general setup parameters
31. CU Without a crossover cable you need to connect both the computer and the ACU to the same network hub using two standard network cables It is essential that the computer and the ACU are connected to the same network segment the configuration program is not able to find the ACU through routers or network switches 2 Now power on your computer and connect the ACU to the UPS power supply Take care that circuit breaker for the ACU inside the sat nms ACU ODU is switched to on state the other ones have to be switched off 3 Insert the CD ROM into the computer s drive and inspect it s contents through the My Computer icon on your desktop Double click to the ChipTool exe program in the ChipTool directory 4 When the ChipTool program is running the program shows a list containing at least one entry describing the actual network parameters of the sat nms ACU RMU C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 15 64 SatService Gesellschaft fiir Kommunikationssysteme mbH CHIPTOOL lui xj File Flash CHIP Tools Info Scan for IPC CHIPs atthe network O04DE3 192 168 2 88 255 255 255 0 192 168 2 254 003056804DE3 2 0 OO5F9E 10_FEP No 192 168 2 70 255 255 255 0 192 168 2 254 SC13 003056805F9E 20 ETH 006902 192 168 265 255 255 255 0 192 168 2 254 003056806902 2 0 ETH 192168281 255 255 2550 192 168 2 254 ETH 012490 BCNRX No 192 168 2 72 255 255 255 0 192 168 2254 F
32. EP and ADAPTIVE the ACU performs steptrack Level averaging When measuring the beacon level the ACU takes a number of samples and averages them The standard value of 5 samples normally should not be changed Larger values will slow down the ACU execution cycle Level threshold If the beacon level drops below this value the ACU raises a fault signal Steptrack is inhibited while the beacon level is too low the antenna position freezes Recovery delay After the the ACU has done the tracking steps for the elevation axis it waits C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 55 64 SatService Gesellschaft fiir Kommunikationssysteme mbH some time before it starts tracking the azimuth axis This is to let the beacon level settle after the final position has been found A typical value for this parameter is 4000 msec Measurement delay During a steptrack cycle the ACU positions the antenna to a certain offset and then measures the level Between the moment when the antenna reached commanded position and the beacon level measurement the ACU waits some time to let the beacon level settle The optimal delay value depends on the beacon receiver s averaging post detector filter setting and is a quite critical for the steptrack performance If the delay is too short the beacon voltage does not reach its final value the steptrack does not properly recognize if the signal gor better or worse after a tes
33. If the sat nms beacon receiver is used then the beacon level is sent from the beacon receiver to the ACU via UDP packets on the LAN 3rd party beacon receiver beacon level voltage sat nms beacon receiver beacon level via UDP packets sat nims ACU ODM sat ninms ACU ODM indoor control indoor control computer computer If asat nms LBRX beacon receiver is used with the ACU it additionally gets connected to the ACU through an Ethernet cable Usually an Ethernet hub is used to connect the ACU the LBRX and the controlling computer With a sat nms LBRX beacon receiver some additional features are available for the tracking e The beacon receiver sends the actual level as UDP packets over the LAN The ACU ODM receives this value without any accuracy degrading due to cascaded digital to analog analog to digital conversions e The ACU reads the beacon frequency from the LBRX at the start of each tracking cycle The value read from the receiver overwrites the value set by the operator and is used to calculate the antenna s beamwidth e The ACU informs the sat nms LBRX when a tracking cycle starts and when it ends The LBRX suspends any background activities like noise reference measurements or frequency tracking This ensures that the beacon receiver recognizes level differences without a delay during the tracking cycle For a well functioning step track with a third party receiver it is important to adjust the voltage
34. OM GND for control voltage IN control L left apply 24VDC here to drive motor right IN power input DC power input 15 35VDC IN power input DC power input GND IN power input DC power input GND IN M1 motor Motor power output OUT protective connect cable shield here OUT ground motor Motor power output OUT 3 5 Circuit breakers The circuit breakers disconnect the mains from the units build to the control cabinet Every circuit breaker is labeled with the unit it is connected to Warning In case of switching off all the circuit breakers it is still voltage available at the mains terminals 3 6 Contactor The contactor disconnects the motor s mains when the emergency stop contact is open Please refer to the schematics shipped together with the sat nms ACU ODU to see how to connect the emergency stop switch 3 7 Terminals Here the mains and emergency switch and are connected Please refer to the schematics shipped together with the sat nms ACU ODU to see how to connect them The limit switches and angle encoders are connected directly to the ACU ODM 1 the motors have to be connected directly to the motor drivers 4 3 8 Heater The sat nms ACU ODU is equipped with a temperature controlled heater In delivery state the thermostat is set to 10 C that means as soon as the temperature in the cabinet falls below 10 C the heater switches to on state 3 9 Optional air ventilation
35. R MEMORY Clicking to this mark clear the tracking memory You should do this when you start to track a new satellite Clearing the tracking memory about half an hour after tracking started significantly improves the quality of the first adaptive tracking model which will be evaluated after 6 hours of tracking This is because the model does not get disturbed by the first search steps the C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 24 64 SatService Gesellschaft fiir Kommunikationssysteme mbH antenna does until the optimal pointing to the satellite is found Tracking step size The tracking step size is a very important parameter for the performance of the tracking It defines the size of every depointing step the ACU makes in order to find out where the optimal antenna pointing is Setting too high values will cause significant signal degradations during the step track cycle because the antenna moves a too large amount away from the satellite Setting the value too small will let the beacon level jitter mask the level differences caused by the test steps the antenna will not track the satellite properly The step size is specified as a percentage of the antenna s half 3dB beamwidth The ACU calculates the beamwidth from the antenna diameter and the beacon frequency Expressing the step size in this relative way keeps the value in the same range regardless of the type of antenna The recommended value for this p
36. U concatenated the fault descriptions More detailed information about faults are available in chapter Faults and Tracking If one axis stops operation due to a fault the step tracking also stopps operation Possible faults are EMERGENCY Someone opened the emergency stop circuit The ACU stopped all STOP motors and stays in this state until the RESET button at the navigation bar is clicked HUB FAULT The ACU detected a hub fault condition CABINET The ACU detected a cabinet open condition OPEN BCRX If the ACU reads the beacon level via TCP IP from a sat nms LBRX TIMEOUT and the latter does not respond a BCRX TIMEOUT fault is reported Tracking If the ACU has the tracking option installed any faults of the tracking module are shown Faults in this field With tracking option this field is always empty AZ EL If the ACU has the tracking option installed and ADAPTIVE tracking is selected these Tracking give some information about the modelof antenna satellite movement the ACU has State calculated from the step track data M model The complexity of the model the ACU uses small medium large With a small amount of tracking data available the ACU uses a smaller less complex model than with a completely filled tracking memory A amplitude The amplitude of the antenna movement in this axis expressed as a percentage of the full 3dB beamwidth J jitter The jitter of the antenna movement in this axis expressed as a percen
37. X 8 output may be configured to act as a heartbeat output If enabled the output switches every 1000 ms between on off If using this signal for an external watchdog circuit be aware that in adaptive tracking mode delays of some seconds are possible while the acu calculates the orbital model With this parameter you select the refresh rate of the ACU s main window This parameter is available from software version 2 1 007 or higher The ACU s pointing page by default shows the title Antenna pointing By entering a different text here you can make the ACU show a customized title Azimuth Elevation Polarization The Azimuth Elevation Polarization sections contains the parameters which are specific to the individual axis They are the same for each axis Parameter Description Set this parameter to the dish diameter Units with the tracking function installed use this value to estimate some tracking parameters With offset antennas the diameter settings are different for the azimuth elevation axes This lets the ACU calculate suitable tracking step sizes individually for each axis This parameter defines size of a step the antenna moves when you click to the arrow buttons on the ACU main page If you are using the arrow buttons to fine tune the antenna pointing manually the best value is the pointing hysteresis described below This lets you move the antenna the smallest possible step when you click to an arrow but
38. a measure of the step track quality This is because the step track measurement uncertainty is an constant angle which primarily depends on the antenna size Beside the amplitude the ACU evaluates for each axis a figure called jitter The jitter value describes standard deviation of the measured peak positions with respect to the positions calculated from the model The figure is also expressed as a percentage of the antenna s beamwidth low values indicate that the model ideally describes the antenna s path High values indicate that s something wrong The step track results may be to noisy at low amplitudes or the model does not fit at all This may be the case if a satellite gets repositioned in the orbit You may set a threshold value for the jitter The ACU raises a fault if at least one axis exceeds the threshold value If this happens three consecutive times the models gets reset all data in the tracking memory gets marked invalid 8 4 2 The Tracking Memory In the tracking memory the ACU records all steptrack peak positions The tracking memory is used as a data source for the adaptive tracking and for the smoothing function as well Each record contains a time stamp the azimuth elevation values and the beacon level measured after the peaking The tracking memory has a fixed size 1000 entries Once 1000 records are stored the memory works in a first in first C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 58 64
39. arameter is 15 20 You may want to start with 20 and try to reduce down to 15 if the signal degradation during tracking becomes too high The tracking step size is a common parameter for both axes If both axes behave differently you can tweak the antenna diameter settings in the setup Specifying a larger diameter makes the ACU using a smaller step size for this axis If the tracking step seems to be completely out of range you should check if the beacon frequency is set properly The frequency must be the true receive frequency at the antenna entered in MHz not an L band frequency or other IF Tracking cycle time The cycle time specifies how often the ACU shall perform a step track cycle The value is to be entered in seconds In fact the parameter does not specify a cycle time but the sleep time between two tracking cycles This means the true cycle time is the time the ACU needs to perform one step track cycle plus the time entered here 300 seconds 5 minutes is a good starting value for this parameter Inclined orbit satellites probably will require a shorter cycle time very stable satellites can be perfectly tracked with one step track cycle every 15 minutes 900 seconds The maximum cycle time accepted by the ACU is 1638 seconds Measurement delay During a steptrack cycle the ACU positions the antenna to a certain offset and then measures the level Between the moment when the antenna reached commanded position and the
40. ards are different for each type of position sensor Actually interfaces for three types of position encoders are available with the sat nms ACU e resolvers e SSI digital position encoders e analog voltage based sensors depending on the interface type you use different pinouts are used The following tables show you detailed the pin descriptions CON18 CON19 CON20 Resolver Interface Below the pinout of a resolver type interface board is shown The ACU is available with resolver SSI or analog position sensor interfaces You have to select type of interface when you order the ACU description 2 SIN resolver SIN IN C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 11 64 SatService Gesellschaft fiir Kommunikationssysteme mbH resolver SIN resolver COS resolver COS IN drive signal to resolver OUT drive signal to resolver OUT The ACU resolver interface is designed for resolvers with an impedance of 100 Ohms or more and transfer factor 0 5 The interface applies 4Veff 2000Hz to the resolver drive coil It expects 2Veff at the sine cosine inputs at the maximum positions When connecting a resolver to the ACU please consider the following e Use a shielded twisted pair cable e Connect the cable shield either to pin 1 8 at the ACU or to the ground at the resolver housing Never connect the shield at both ends this will introduce a ground loop and cause
41. beacon level measurement the ACU waits some time to let the beacon level settle The optimal delay value depends on the beacon receiver s averaging post detector filter setting and is a quite critical for the steptrack performance If the delay is too short the beacon voltage does not reach its final value the steptrack does not properly recognize if the signal goes better or worse after a test step If the delay is too long the impact of fluctuation to the measures level grows and may cover the small level difference caused by the test step With the sat nms LBRX beacon receiver best results are achieved if the receiver is set to 0 5 Hz post detector filter bandwidth and a measurement delay of 1500 msec Recovery delay After the ACU has done the tracking steps for the elevation axis it waits C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 25 64 SatService Gesellschaft fiir Kommunikationssysteme mbH some time before it starts tracking the azimuth axis This is to let the beacon level settle after the final position has been found A typical value for this parameter is 4000 msec Level averaging When measuring the beacon level the ACU takes a number of samples and averages them The standard value of 5 samples normally should not be changed Larger values will slow down the ACU execution cycle Level threshold If the beacon level falls below this threshold value the ACU does not perform a step track cy
42. bit number 0 means the least significant bit bit number 31 the most significant bit in this number no name description C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 45 64 N_PLHLM polarization hi limit tt N_PLLLM polarization lo limit N_PLFLT polarization motor fault N_HBFLT antenna hub fault N_AUX1 reserved N_AUX2 reserved n coe cs cee cas N_AUX3 reserved N_AUX4 reserved N_AZHLM azimuth hi limit 9 N_AZLLM azimuth lo limit O IN_AZFLT _ azimuth motor fault 11 IN_EMERG emergency stop 12 IN_ELHLM elevation hi limit 13 IN_ELLLM elevation lo limit rm E p N_ELFLT elevation motor fault 5 IN_COPEN cabinet open AZMOV azimuth moving ELMOV elevation moving PLMOV polarization moving moving summary bit azimuth timeout elevation timeout PLTOT polarization timeout TIMEOUT timeout summary bit 2 TRKPEAK peaking in progress LOWBEAC low beacon signal BCRXFLT beacon receiver fault limit switch summary azimuth stopped 29 ELSTOP elevation stopped 30 PLSTOP polarization stopped 31 GPSFLT GPS receiver fault Bit definitions in obit output bits SatService Gesellschaft f r Kommunikationssysteme mbH The obit value is returned as a 32 bit hexadecimal number The bit number 0 means the least significant bit bit n
43. cation methods use the same commands and parameters However there are different frames around each message depending communication method used Controlling the device from the web interface the TCP IP remote control interface or via the serial interface is completely equal commands may sent to any interface at any time the ACU will use the parameter it receives last 7 1 General command syntax The ACU knows a number of parameters each identified by a parameter name To set a certain parameter to a new value a message name value has to be sent to the ACU The ACU interprets this command checks the range of value sets the internal parameter and then answers name value The value in the reply is the value actually recognized by the ACU For instance if the requested value was out of range the replied and internally used value is limited to the applicable minimum or maximum To read a parameter from the ACU instead of a new parameter value a question mark is sent name The ACU replies the actual value in a complete message name value A complete list of the parameter the ACU knows is shown later in this document in chapter Parameter list Below some common rules applying to the remote control message syntax are summarized e Parameter names always are of lower case letters most of them are four characters long e Non numeric parameter values always are written in upper case e Numeric floating point values may be
44. cle If the level falls below the threshold during the steptrack cycle the cycle gets aborted If the ADAPTIVE tracking is enabled and there is enough data in the tracking memory the ACU computes a mathematical model from the stored data and predicts the antenna pointing position from the extrapolation of the model If the tracking mode is set to STEP the ACU leaves the antenna where it is if the beacon level drops below the limit Adjusting the threshold level that adaptive tracking is switched as expected must be done carefully and may require some iterations specially if the beacon is received with a low C N A good starting value for the threshold is 10 dB below the nominal receive level or 2 dB above the noise floor the beacon receiver sees with a depointed antenna whatever value is higher To turn off the monitoring of the beacon level this in fact inhibits the adaptive tracking simply set the threshold the a very low value e g 99 dBm Smoothing interval This parameter controls the smoothing function Setting it to zero disables smoothing Smoothing lets the ACU point the antenna to positions evaluated from a simple model calculated from the step track peaks of the recent few hours A detailed description of this function you find at chapter 8 3 3 Smoothing Peak jitter threshold If the jitter value of at least one axis exceeds this threshold the ACU raises an model fault If this happens three consecutive time
45. cos 2 wt a sin 2 wt 2 arg Ag a COS wt aysin wt a cos 2 wt a 4sin 2 wt ast 3 7 5 One line read via TCP IP For compatibility with the sat nms power sensor the ACU also may be polled for an automated monitoring by the requesting the position document with a HTTP GET command Assuming the ACU listens to the IP address 10 0 0 1 the complete URL for the request is http 10 0 0 1 point fmt txt The fmt txt parameter forces the power sensor to reply a one line text document rather than the HTML coded page which is normally displayed by the web browser The ACU answers a text plain type document which consists of one line As shown in the example below the line consists of a set of keyword value pairs separated by amp characters Within each pair keyword and value are separated by the character apos 174 688 amp epos 31 456 amp ppos 34 5 amp atar 174 700 amp etar 31 500 amp ptar 34 5 amp blev 64 33 amp temp 63 5 amp o0 bit FFFF0000 amp ibit FFFF0000 amp The format does not use fixed column widths for the values however the precision of floating point values is always as shown in the example An application which parses this string should not rely on the order of the values in the line Future version of the ACU may provide additional values which not necessarily will appear at the end of the line A description of the parameters is given in the chapter Parameter list above C 2014 SatService G
46. d OUT A D converter input IN 4 2 2 Limit switch and emergency switch connection Limit switches have to be connected directly to the sat nms ACU ODM emergency switch has to be connected to the terminals bottom right of the cabinet Please refer to the schematics for the exact cabling The ACU treats a closed contact as OK contacts have to be opened to indicate the limit reached or emergency stop condition Opening the emergency stop contact disconnects the frequency inverters motor drivers or conductors from mains supply immediately The pinout of limit switch connector is as follows CON16 Limit Switches The limit switch inputs internally are connected to the external 24V GND rails The switches are connected directly to the input pairs without any external ground or supply cabling The ACU treats a closed contact as OK contacts have to be opened to indicate the limit reached condition 24V EXT Example for wiring the limit switches Ev CON16 Pin 1 3 5 7 9 11 CON17 Pin 1 3 5 a2 FE 2 a CONI6 Pin 2 4 6 8 10 12 CONI Pin 2 4 6 GND EXT Please note that the left right azimuth and polarization limit switches have to be swapped when the antenna is operated at the southern hemisphere pin signal description azimuth right limit view from behind antenna azimuth left limit view from behind antenna C 2014 SatService GmbH www satnms com
47. de PARALLEL Azimuth AZ Antenna diameter 37m AZ Position sensor type RESOLVER AZ Sense invert NORMAL AZ Pre scale offset FEICESSE calc AZ Calibration scale 0 000000 AZ Lower limit 148 000 Elevation EL Antenna diameter 3 7m EL Position sensor type RESOLVER EL Sense invert INVERTED EL Pre scale offset AF2IESSE calc EL Calibration scale 0 000000 EL Lower limit 8 000 Polarization PO Position sensor type RESOLVER PO Sense invert NORMAL PO Pre scale offset 00000000 calc PO Calibration scale 0 000000 PO Lower limit 80 000 Beacon Receiver Beacon RX type SATNMS Beacon RX voltage scale n a Beacon RX frequency 11450 529 MHz Location GPS receiver type NONE Antenna course 180 000 Orientation Compass type NONE Nick offset n a SNMP Control SNMP read community public SNMP write community private SNMP trap community public SNMP traps ENABLED SNMP trap IP 1 192 168 218 SNMP trap IP 3 0 0 0 0 Access Control User password a Setup Page Example 5 7 Handheld Terminal Date time RS485 address Az step delta AZ Motor driver type AZ Motor timeout AZ Post scale offset AZ Pointing hysteresis AZ Low speed threshold AZ Upper limit El step delta EL Motor driver type EL Motor timeout EL Post scale offset EL Pointing hysteresis EL Low speed threshold EL Upper limit PO Motor driver type PO Motor timeout PO Post scale offset PO Pointing hysteresis PO Low speed threshold
48. ded that the ACU and your computer are configured for the same subnet 4 3 2 Limit switches Connect the limit switches to the sat nms ACU ODU as described in chapter 4 2 Pin description 1 Switch on circuit breaker for the ACU ODM to on state take care that the other ones are in off C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 16 64 SatService Gesellschaft fiir Kommunikationssysteme mbH position The ACU should be reachable via Ethernet now 2 Check the function and correlation of all limit switches manually On the sat nms ACU ODMs main website a limit fault is shown as soon it occurs On the test page every single limit switch is displayed For more detailed informations see chapter 5 Operation 4 3 3 Angle detectors Connect the angle detectors directly to the sat nms ACU ODU as described in chapter 4 2 1 Pin description 1 Configure the desired type of detector on the setup page 2 Set the soft limits to the expected values at first it is ok if you do this approximately later on you need to type in here the exact values 3 Check the rotational direction of the resolvers If possible do this by turning the resolver axis directly otherwise you have to move the antenna by hand Maybe you have to invert the rotational direction on the setup page 4 Set the offset of the angle detectors to the desired values by using the calc function If you need more detailed information please refer to
49. difference If the difference is less than the hysteresis value the ACU leaves the motor switched off This prevents the antenna from oscillating around the target value Motor The ACU monitors the position readings while the motor is running If there is no change in timeout the position readings for some time the ACU assumes to motor to be blocked and switches it off This motor timeout fault must be reset by the operator to release it A timeout value 0 disables the timeout Lower The minimum target value accepted at the user interface and via remote control This limit software limit prevents the ACU from running the antenna to the limit position under normal conditions Upper The maximum target value accepted at the user interface and via remote control This limit software limit prevents the ACU from running the antenna to the limit position under normal conditions Beacon Receiver Parameter Description Name C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 31 64 SatService Gesellschaft fiir Kommunikationssysteme mbH Beacon Selects the source of the beacon level the ACU shall use Available options are SATNMS and RX type VOLTAGE In SATNMS mode the ACU reads the beacon level from a sat nms beacon receiver via UDP in VOLTAGE mode the A D converter input of the ACU is read Please mention that in SATNMS mode the beacon receiver must be set to send UDP datagrams to the ACU ODM B
50. e The ACU presents this figure as a percentage value C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 57 64 SatService Gesellschaft fiir Kommunikationssysteme mbH SMALL MEDIUM amplitude 6 12 18 24 30 36 42 45 hours memory depth The ACU selects the adaptive tracking model following a scheme as illustrated in the diagram above Below 6 hours data in the tracking memory there is no adaptive tracking possible at all With at least 6 hours of data and 18 valid samples the ACU uses the SMALL model If the movement amplitude is above 30 and there are at least 12 hours with 36 valid samples of data available the ACU uses the MEDIUM model The LARGE model requires 48 hours of data with 144 valid samples and an amplitude value of 30 Beside the recorded hours of steptrack the ACU also watches the number of samples With a tracking interval of more than 15 minutes the required times may be longer than shown in the diagram The ACU provides a max model parameter for each axis You may limit the model size to a smaller one than the ACU would choose by itself The other way round it is not possible to force the ACU to use a model it has not enough data for If the tracking results are bad the ACU will not be able to calculate a model and set the model to NONE This occurs also if only one axis have bad tracking results Quality information As mentioned above the amplitude of the satellite s movement is used as
51. e ACU RMU to the desired operation mode to save targets and finally to set the sat nms ACU RMU into service In chapter 5 Operation you find a detailed description of the pointing and tracking parameters To use the function pointing by stating an orbit position you have to configure the Location parameters on the setup page to the geodetic location of your antenna Take care to type in position with enough accuracy 0 001 For further informations please refer to chapter 5 6 Setup for location parameters and 5 3 Target Memory for using this pointing function 4 3 6 Backup of ACU settings C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 17 64 SatService Gesellschaft fiir Kommunikationssysteme mbH The last step that is recommended to be done is the backup of ACU settings By this way an easy replacement of the ACU ODM could be performed The following step by step description shows how to do this 1 Open the chiptool 2 Right click to the desired unit A drop down list will open choose FTP 3 A small window like shown on the following picture will be opened Please double check the displayed IP you might adjust it in the drop down list here Connect service Password MV Save User and Password Binary Image ASCII Bepresentation Type F Use passive mode coca 4 Login with username service and password service 5 Now you see on the right side the file system of the ACU
52. e ACU wants to run the motor slowly C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 50 64 SatService Gesellschaft fiir Kommunikationssysteme mbH This signal is active while the ACU wants to run the motor fast The ACU activates this signal for 800 msecs if the operator clicks RESET The signal may be cabled to an input of the motor driver which resets latching faults The ACU monitors this signal all the time The signal is low active i e the ACU expects current flowing through the optocoupler while the driver is OK if the circuit is opened the ACU signals a fault and stops the motor If the motor driver does not provide a fault signal the clamps of the FAULT input must be wired to 0V 24V otherwise the ACU will not move the motor The ACU knows two different configuration modes to control a motor driver They are called DIR START and DUAL START In DIR START mode the FWD signal switches the motor on off the REV signal controls the motor direction This is the configuration many frequency inverters use In DUAL START mode the FWD signal switches the motor on in forward direction REV activates the motor in reverse direction This configuration mode is convenient to control a motor with relays The speed select signal SP1 and SPD2 actually are the same signal but with different logical polarity For most motor drivers it is sufficient to connect one of these two signals select the one
53. e default is public community SNMP This parameter decides if the SNMP traps are enabled or disabled traps SNMP The ACU replies to MIB II sysName requests with the text entered at this place system name SNMP The ACU replies to MIB II sysLocation requests with the text entered at this place system location SNMP The ACU replies to MIB II sysContact requests with the text entered at this place system contact MIB File click here to download the MIB file SNMP trap Enter up to 4 trap destination IP addresses dotted quad notation to make the ACU sending IP 1 4 traps by UDP to these hosts Setting the parameter to 0 0 0 0 disables the trap generation Access Control User Here you can define the password for the user login Default password is user When you password are logged in as user you can command the antenna pointing set the tracking parameters if applicable and store recall targets You can t modify the setup parameters or issue low level commands on the test page while logged in as user Admin Here you can define the password for the admin login Default password is admin When password you are logged in as admin you have full access to all parameters of the ACU including the setup and the tweaks on the test page C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 33 64 General Note 3 7m Antenna Display refresh 1sec Axes control mo
54. e following types of positional sensors SSI SSI type digital position encoders are the first choice for antennas which are setup from scratch They are precise reliable and provide a standardized interface The ACU supports types from 13 to 24 bit resolution both gray coded and binary variants The ACU provides 5V and 24V supply voltages 200mA max for the encoders so external power supplies may be omitted in most cases RESOLVER Many existing antennas are equipped with resolvers The resolver interface module permits to re use these ready mounted and cabled sensors when an old antenna controller is to be replaced by a sat nms ACU The resolver interface board is optimized for the use with 2V type resolvers which are very common The interface board drives the resolver with 4Veff 2000Hz and expects 2Veff at the sin cos inputs The resolver interface has 16 bit binary resolution ANALOG For small antennas with reduced accuracy requirements using analog angle to voltage sensors in fact precision potentiometers is an inexpensive alternative The analog sensor interface board may be set up for several voltages to connect to the commonly used sensor types The analog interface board uses a 16 bit precision ADC with a temperature compensated voltage reference Angle calibration Analogous to the modular position interface hardware concept the ACU software uses configurable drivers to read the different types of position int
55. eacon The IP address of the beacon receiver Applicable only in SATNMS mode Beacon The scale factor for the analog beacon level input The value must match the scaling of the RX beacon level signal Beacon The beacon level which is displayed if the ACU recognizes OV beacon level input Location Parameter Description Name GPS Defines the type of GPS receiver the ACU uses to read its geodetic location receiver type NONE tells the ACU that no GPS receiver is connected The geodetic position of the Antenna has to be entered manually The ACU synchronized its internal clock to the CMOS clock chip on the board NMEA tells the ACU to expect messages from a NMEA GPS receiver connected to the serial interface at CON8 pins 1 3 The ACU automatically sets the antenna s geodetic location to the values received and synchronizes the clock to the GPS timestamps If no NMEA messages are received the ACU states a fault Antenna The Antenna course is an additional offset which is included into the azimuth calibration It is course used for mobile antennas to set the orientation of the antenna without recalibrating it For stationary antennas this value always should be set to 180 Antenna The geodetic longitude of the antenna For a precise orbit to pointing calculation this value longitude should be entered with 0 001 accuracy Antenna The geodetic latitude of the antenna For a precise orbit to pointin
56. ements The coefficients of the elements are evaluated from the step track data recorded for several hours or days by means of the least square fit method The more elements are included to a model the better approximation of the true motion is possible On the other hand the number of data points used to evaluate a model is limited the measurements values are distorted due to inaccuracy and noise The more complicated a model is the more susceptible it is to noise For practical usage there have to be used varying models depending on the amount and quality of the recorded steptrack data Models The ACU uses three different mathematical models to describe the movement of the antenna while it tracks the satellite All models are based on sinusoidal functions with a cycle time on an sidereal day The models called SMALL MEDIUM and LARGE differ in their complexity C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 56 64 SatService Gesellschaft fiir Kommunikationssysteme mbH MEDIUM ml The SMALL model the simplest one emulates the true antenna movement with a plain sine function There are only three parameters with this model the nominal antenna pointing and the amplitude phase values of the superposed sine This model is very stable gives reliable results even with only a few measured step track peaks Unfortunately the SMALL model does not fit optimally for all satellites The MEDIUM model superposes a
57. ensate this difference It makes no difference if a new target value has been commanded or if the antenna has moved a little bit due to a squall Hysteresis To avoid that the motor is switched forth and back all the time the ACU tolerates small differences between measured and target value within a hysteresis value This hysteresis is individually configurable for each axis at the Setup page To ensure that the motor stands still when the target position is reached twice the resolution step size of the position sensor encoder must be set Common values are bit resolution angular resolution recommended hysteresis 13 bit 0 0442 0 0902 16 bit 0 0052 0 0122 17 bit 0 0039 0 006 If the motor control loop still oscillates with the recommended hysteresis values this is due to the off carriage of the antenna drive Either turn down the motor speed at the motor driver unit or enlarge the hysteresis value in this case Motor drive signals The sat nms ACU ODM the core module provides a number of output signals to control a motor driver unit These signals they are available for all three axes are Depending on the motor driver type configured this signal generally switches the motor on for both directions or for the forward direction only Depending on the motor driver type configured this signal reverses the motor direction or it activates the motor in reverse direction This signal is active while th
58. ep size wdog OFF ON ON Sends a heatbeat to the AUX 8 output Remarks 1 Software capabilities are summed from the following values 1 step track amp adaptive tracking included 2 polar mount antennas supported 4 memory tracking ingluded 2 ACU variants with compass support provide other choices beside NONE for this parameter 3 ACU variants with GPS support provide other choices beside NONE for this parameter 4 ACU variants with inclinometer support provide other choices beside NONE for this parameter 5 for single step move use following commands description Azimuth large step left Azimuth small step left Azimuth small step right Azimuth large step right Elevation large step down small step down small step up large step up Polarisation clockwise step Polarisation counter clockwise step 6 Use the time parameter to read the actual time used by the ACU Use the stim parameter to set the time 7 This parameter reports the description name and pointing angles for a given target number tdsc 12 e g is interpreted by the ACU as a request to report the target description for target no 12 The reply to this command is something like tdsc ASTRA 19 2 167 335 43 412 15 455 8 ACU variants without tracking support only accept NONE for this parameter Bit definitions in ibit input bits and flags The ibit value is returned as a 32 bit hexadecimal number The
59. er supplies for sat nms ACU ODM In the ACU ODU you find 2 power supplies one is for the core processor of the ACU ODM it is labelled with PS ODM The other one supplies the external contacts of the ACU e g the control signals for the POL drivers relais This one is labelled with PS EXT By this the core processor of the sat nms ACU ODM will not break down if something externally happens e g overload short circuit 3 3 Power supply for motor drivers As standard type a 24VDC 10A power supply is installed for the motor drivers On demand versions with up to 48VDC 15A are available To provide enough power for starting up the motors there is an additionally 15000uF capacitor integrated 3a 3 4 Motor drivers Depending on your requirements up to 3 motor drivers are integrated into the ACU ODU These are DC power drivers with power rating of 15A The standard version has a voltage rating of 35VDC an extended version for 48VDC is available on demand The standard power supply integrated into the sat nms ACU ODU is 24VDC 10A so this is the limiting value On demand the sat nms ACU ODU is available with a power supply that provide higher current the following picture shows a DC driver C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 8 64 SatService Gesellschaft fiir Kommunikationssysteme mbH On the upper side you see the control inputs on the lower side the power input and motor output terminals are loca
60. erfaces From the user s point of view the ACU accepts and displays pointing angles as floating point numbers with 0 001 resolution Internally the software treats angles C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 49 64 SatService Gesellschaft fiir Kommunikationssysteme mbH as 32 bit integer numbers where the full 32 bit range corresponds to 360 This is equivalent to a resolution of 0 000000084 When the software calculates the pointing angles from the sensor readings it includes some calibration parameters configurable at the Setup page The steps of calculating a pointing angle are as follows Get the raw value Extend left shift the value to 32 bits Reverse the sign if this option is set in the setup Apply add the pre scale offset Convert to degrees If the calibration scale is nonzero multiply by the calibration scale Add the post scale calibration offset For the azimuth axis add the antenna course too 0 XI NU hh YN RP The angle calculated this way may exceed a full circle of 360 if the scaling ensures that there is no overflow of the encoder reading itself The value displayed as raw reading at the test page is the result of step 2 8 2 Pointing Motor Control The sat nms ACU performs the pointing motor control as a closed control loop independently for each axis If the measured position value differs from the target value the motor is activated to comp
61. es where the ACU seems to be too optimistic about the quality of the step track results the maximum model on one or both axes may be limited to a more simple and more noise resistant model Specially inclined orbit satellites which are located close to the longitude of the antenna s geodetic location may require this limitation for the azimuth axis With such a satellite the elevation may move several degrees while the azimuth shows almost no motion Please refer to chapter 8 3 Steptrack 8 4 Adaptive Tracking and 8 5 Program Tracking for more detailed informations about the tracking algorithms Tracking Parameters Page Example Tracking mode OFF CLEAR MEMORY Tracking step size 15 Tracking cycle time 180 sec Measurement delay 1500 msec Recovery delay 4000 msec Level averaging 5 samples Level threshold 75 00 dBm Smoothing interval Eh Peak jitter threshold 0 AZ Maximum model type LARGE EL Maximum model type LARGE 5 0 Test Page The page Test displays the electrical logical level of all inputs and outputs of the ACU This helps you to install the ACU or to identify a malfunction of peripheral components Below some information how to interpret the values in this page are given Electrical I O Levels The electrical state of an input or output is indicated by the HI LO label displayed with the signal HI means that current is flowing through the optocoupler for this input or output LO means that no current flows As some si
62. ess to the tracking mode and the fine tune parameter which lets you adapt the tracking to the individual requirements of the antenna and the satellite you are tracking to ACUs without tracking function show an empty page at this place Tracking mode The tracking mode parameter selects the tracking method the ACU actually uses Possible selection are OFF No tracking is performed STEP Step track mode In regular intervals the antenna performs small search steps to optimize the pointing Chapter 8 3 0 Step Track gives more information about this mode ADAPTIVE The adaptive tracking mode works the same way as step track but it additionally is capable to predict the satellite s position when the beacon reception fails It computes mathematical models of the satellites motion from the step track results recorded over a certain time Details about this tracking mode are given in chapter 8 4 0 Adaptive Tracking PROGRAM The program tracking mode is different from the modes above The ACU moves the antenna along a path which is described in a data file No beacon reception is required for this You have to create such a data file and copy it with FTP to the ACU before you can use this mode SatService GmbH provides a PC software which lets you easily create data files for program track from commonly used ephemeris data sets for geostationary satellites Chapter 8 5 0 Program Tracking describes this tracking mode more detailed CLEA
63. f the beacon is received with a low C N A good starting value for the threshold is 10 dB below the nominal receive level or 2 dB above the noise floor the beacon receiver sees with a depointed antenna whatever value is higher To turn off the monitoring of the beacon level this in fact inhibits the adaptive tracking simply set the threshold the a very low value e g 99 dBm Peak jitter threshold If the jitter value of at least one axis exceeds this threshold the ACU raises an model fault If this happens three consecutive times the ACU resets the models of both axes Adaptive tracking will be possible not until 6 hours after this happens During adaptive tracking the ACU evaluates for each axis a figure called jitter The jitter value describes standard deviation of the measured peak positions with respect to the positions calculated from the currently selected model The figure is also expressed as a percentage of the antenna s beamwidth low values indicate that the model ideally describes the antenna s path High values indicate that s something wrong The step C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 60 64 SatService Gesellschaft fiir Kommunikationssysteme mbH track results may be to noisy at low amplitudes or the model does not fit at all This may be the case if a satellite gets repositioned in the orbit A typical threshold value is 20 this will detect very early that a model does n
64. g calculation this value latitude should be entered with 0 001 accuracy Antenna The absolute altitude over sea of the antenna location Orientation Parameter Name Description Compass type Applicable only for car mobile variants of the ACU Inclinometer type Applicable only for car mobile variants of the ACU Nick offset Applicable only for car mobile variants of the ACU Roll offset Applicable only for car mobile variants of the ACU C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 32 64 SatService Gesellschaft fiir Kommunikationssysteme mbH SNMP Control From Software version 2 1 007 or higher the sat nms ACU contains an SNMP agent listening at UDP port 161 The SNMP agent provides a common subset of the MIB II system interface parameters and gives full access to the remote control capabilities of the sat nms ACU with a number of MIB objects placed in the private enterprises tree The actual MIB file defining the ACU s private MIB may be downloaded from the ACU itself by FTP user service password service The file ACUODM MIB contains all necessary information Parameter Description Name SNMP Sets the SNMP community string expected for read access The default is public read community SNMP Sets the SNMP community string expected for write access The default is public write community SNMP trap Sets the SNMP community string sent with traps Th
65. getXX txt XX represents the number of the target 8 To copy a backup file to the ACU browse on the left side if the window to the desired app dat file and copy this file to the ACU in the same way right click gt copy 9 After copying an app dat file to the ACU you have to reboot the unit power off By next starting up the new app dat file will be used C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 19 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 5 Operation The sat nms ACU outdoor module is designed to be controlled over a network link using a standard web browser This means in practice that the user interface to the ACU appears in your browser window after you type in the ACU s IP address in the address field of the browser program Operating the ACU is mostly self explanatory 5 1 The Web based User Interface After having connected the ACU to a power supply and set the ACU s IP address you can access the ACU s user interface To do this start your favorite web browser program Internet Explorer Netscape Navigator Opera or what else program you prefer At the address field where you normally enter the URL of a web page you want to see type in the IP address of the sat nms ACU you want to control The ACU shows a web page consisting of a navigation bar at the left side of the browser window and the actual antenna pointing in the main part of the window The readings automatically ref
66. gnals are defined to be true when a switch is opened the electrical level of the signal not necessarily describes the logical level of this signal too Logical I O Levels The logical level of an input or output is described by it s color Green means this signal is inactive OK or false Read means the signal is active or true Toggling output levels manually The Test page also lets you toggle the actual state of each output signal simply by clicking to the underlined HI LO mark of the signal If you do this you should consider the following e The ACU sets the motor driver outputs eight times a second for each axis having the motor driver type set to DIR START or DUAL START This immediately will overwrite any change you make If you want to test if the motor driver outputs command the motor driver as expected switch the motor driver type for this axis to NONE at the Setup page before you set the outputs manually e The Test page is re read by the Web browser about once a second Some browsers seem to ignore mouse clicks occasionally due to the screen refresh Adaptive tracking coefficients C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 27 64 SatService Gesellschaft fiir Kommunikationssysteme mbH In adaptive tracking mode the ACU displays the coefficients of the actual model in two lines at the bottom of the text page The number of coefficients displayed depends on the size of the model
67. how the actual antenna pointing angles as read from the position Elevation sensors If the polarization axis is not controlled by the ACU is displayed in the Polarization polarization field Below the measured angles the ACU displays the target values of the antenna pointing The target values are the angles which have been commanded to the ACU You may click to a target angle in order to change the pointing manually The ACU display a dialog page where you can enter the new pointing angle If you click to the SUBMIT button in this dialog page the antenna immediately moves to the new position To go back to the main page without changing the pointing click to the Back button of your Web browser Below the target values for each axis there is a field reserved which contains some state information for this axis While the motor is running MOVING is displayed at this place If the motor has been stopped due to a fault or an emergency stop request a red label STOPPED is displayed Finally if the ACU recognizes the activation of a limit switch the orange colored label LIMIT is displayed in this field Target name The name of the satellite the antenna is pointing to Click to the name to get a dialog page where you can change the name The name is stored together with a satellite s pointing at the target memory page If you change the target pointing values the target name is set to unknown by the ACU Hence you first sh
68. l wire as well WARNINGS e The outside of the equipment may be cleaned using a lightly dampened cloth Do not use any cleaning liquids containing alcohol methylated spirit or ammonia etc Follow standard Electrostatic Discharge ESD procedures when handling the Unit Apply the appropriate voltage according to the attached schematic In case of switching off all the circuit breakers is still voltage available at the mains terminals Only use shielded cable to connect the AZ and EL Motor The other components in the cabinet might be jammed through the harmonic waves the frequency inverters inject into the motor wires e Use only double shielded twisted pair cables e g CAT7 Ethernet cable to connect the resolvers to the sat nms ACU e Only ACU ODU If the Unit is equipped with an optional air ventilation avoid direct contact with jets of water normal rain is no problem C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 6 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 3 The sat nms ACU ODU DC The sat nms ACU ODU is a full featured antenna positioner and as an option antenna tracking system The electronics of the sat nms ACU ODU is build into an outdoor cabinet The protection class of the cabinet is IP66 if no optional air ventilation is installed So it is no problem to install it outside without any additional roof The unit consists from the components listed in the following table All of the
69. lligent network switches Hence the typical sequence of tasks when putting an sat nms ACU outdoor module into operation is as follows Read the chapter Safety Instructions Set the ACU s IP address Mechanically mount the ACU Connect the ACU to the antenna position encoders limit switches and motor drivers Finally connect the UPS power supply and the Ethernet network 5 Start up the system and set the parameters as described below AUNE 4 3 1 Setting the IP Address Before you can operate the sat nms ACU ODU you need to set the ACU s IP address There is a special configuration program on the documentation CD shipping with the ACU for this purpose We recommend to configure the ACU s TCP IP settings before you install the sat nms ACU RMU at it s final place To configure the ACU the following equipment is required e The sat nms ACU ODU itself e 230V AC power at UPS mains terminals e A Computer running a Microsoft Windows operating system equipped with CD ROM drive and Ethernet network card e ACAT5 crossover network cable or an Ethernet hub and standard network cables to connect the ACU and the computer e The CD ROM shipping with the sat nms ACU Setting the ACU s IP parameters now is easily done within a few minutes 1 First install a network cable between the ACU and your computer If you have a crossover cable available this is very easy simply put the cable into the network connectors of computer and A
70. llite and click to submit 6 The ACU calculates and sets the calibration offsets to a value so that the actual pointing is displayed as the angle you entered For the azimuth axis there is another offset which also is taken into account the Antenna course This value is provided for mobile applications where a compass reading has to be included into the azimuth value Calibration Normally the ACU assumes that the full range of a position sensor corresponds 360 If you scale are using a multiturn position sensor or if the position sensor is mounted to the shaft of a C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 30 64 SatService Gesellschaft fiir Kommunikationssysteme mbH gear rather than to the antenna axis directly the position sensor reading must be scaled The displayed angle is computed as follows displayed value raw reading pre scale offs scale pos scale offs Mathematically a scale value of 1 0 disables the scaling Beside this the ACU also accepts the special value O to disable scaling at all If you set 1 0 the ACU performs the scaling with this factor With the value 0 the scaling is skipped completely including the conversion of the reading to floating point This ensures that the full accuracy is retained in cases where no scaling is necessary Sense With this parameter you easily can reverse the sense of a position sensor The sense should invert be as follows e Azimu
71. ly point the antenna to that position where the signal is the strongest The sat nms ACU uses an optimized variant of this method which lets the tracking find the best pointing peak with a minimum amount of depointing Within one step track cycle on one axis the ACU does several very small steps Using the position and beacon level values of all steps in the cycle the ACU calculates the peak position by aligning the approximated antenna pattern to the measured points C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 51 64 SatService Gesellschaft fiir Kommunikationssysteme mbH pairs of position beacon level values recorded during the step track cycle the peak position p sy evaluated by a least squares calculation antenna pattern approximated by a parabola This method minimizes the impact of noise and measurement errors to the evaluated peak position The benefit is that the size of depointing steps can be reduced to a very small value A tracking cycle consists of 2 4 tests steps With each step the antenna is moved a certain angle increment the beacon level is measured before and after the movement The angle increment is an adjustable value expressed as a percentage of the antenna s 3dB beamwidth A typical value is 15 of the half beamwidth START Do one step in direction A WORSE Do another step in direction A WORSE DONE Do a last step in direction A DONE
72. mbH www satnms com ACU ODU DC UM 1411 Page 48 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 8 Theory of Operation This section gives some background information about how the ACU works Chapter 8 1 Angle Measurement describes how the ACU measures the antenna pointing and how it calculates the angles displayed at the user interface Chapter 8 2 Pointing Motor Control describes the way the ACU performs the antenna pointing and how it controls the motors Chapter 8 3 Steptrack describes the step track method used by sat nms ACUs providing this function Chapter 8 4 Adaptive Tracking describes the adaptive orbit prediction tracking method used by sat nms ACUs providing this function Chapter 8 5 Program Tracking describes the program file tracking capability built into the sat nms ACU 8 1 Angle Measurement The sat nms ACU provides exchangeable interfaces for several types of position sensors Position sensor interfaces may be selected individually for each axis This gives a maximum of flexibility for application where the sat nms ACU replaces an existing antenna controller Position sensor types Actually there are three types of position sensor interfaces available for the ACU The interfaces principally are field replaceable however changing interface boards inside the ACU should be done by skilled personnel only ESD protection must be followed when handling the ACU boards The ACU is capable to interface to th
73. means The file format is described in chapter 8 5 2 File Format 2 Set the tracking interval parameter to a value significantly below the intervals between the position entries in the file Setting it to 60 seconds will work with most applications 3 Switch the tracking mode to PROGRAM The antenna will move as defined in the program txt file The ACU polls the file every tracking interval seconds and moves the antenna if it finds a table entry which is time stamped within the next tracking interval Be aware that the clock in the ACU must be set precisely to make the feature work as expected 8 5 2 File Format The program txt file is a plain text file containing a three or four column table Empty lines are ignored comments starting with a as well The numbers in the table are parsed as floating point numbers which only may consist of decimal digits one decimal point ans an optional leading if negative The columns must be separated by an arbitrary number of space or tabulator characters They have the following meanings 1 time stamp The time stamp must be a Julian date with the time of day coded as a fraction of a day Example The Julian date for the common base of most computer clocks 1970 01 01 00 00 00 is 2440587 5 2 azimuth The azimuth angle in degrees angle C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 61 64 SatService Gesellschaft fiir Kommunikati
74. motor lock that was set by pushing the STOP button REDRAW Back to start screen POL Turns the polarisation counterclockwise CCW STEP Selects the step size small steps x keypress x is the value that was set on the setup SIZE screen large steps 10 x keypress continuous mode the antenna moves as long until the button is pushed or a limit switch or limit value is reached POL Turns the polarisation clockwise CW Moves the antenna up EL Moves the antenna to the left AZ HALT Stops the antenna movement only in continuous mode gt Moves the antenna to the right AZ Moves the antenna down EL C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 35 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 6 Frontpanel operation The sat nms ACU ODM and ACU ODU do not provide frontpanel operation For these units we provide an optional handheld for local controlling and monitoring without a laptop Please refer to chapter 5 7 Handheld Terminal for more informations C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 36 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 7 Remote Control The sat nms ACU may be controlled remotely by a monitoring and control application either through the TCP IP interface or through a serial RS232 interface RS232 not yet implemented in ACU19 and ACU RMU Both communi
75. n RX C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 40 64 SatService Gesellschaft fiir Kommunikationssysteme mbH voltage scale bcty SATNMS VOLTAGE Beacon RX type blev r o HHH dBm Beacon level Beacon level ripple 999 00 100 00 Level threshold 00 FF 90 000 90 000 Software capabilities 1 Antenna declination 0 99 0 0 100 0 Delete target AZ Antenna diameter 0 0 100 0 EL Antenna diameter EL antenna beamwidth 360 000 360 000 EL Amplitude Calibration offset Calculate offset from El value see below 0 000 2 000 NORMAL INVERTED EL model coefficients EL Pointing hysteresis 0 000 90 000 character string emin 0 000 90 000 emmx SMALL MEDIUM LARGE C 2014 SatService GmbH WWw satnms com ACU ODU DC UM 1411 Page 41 64 SatService Gesellschaft fiir Kommunikationssysteme mbH DUAL START DIR START NONE 0 000 90 000 00000000 FFFFFFFF 0 000000 100000 000000 SSI 13B SSI 13G SSI 17B SSI 17G SSI 18B SSI 18G SSI 19B SSI 19G SSI 20B SSI 20G SSI 24B SSI 24G RESOLVER VOLTAGE NONE Maximum model type EL Motor driver type EL Pointing EL raw pointing EL Calibration scale EL Position sensor type EL Low speed threshold 0 000 90 000 0
76. na gets moved to the smoothed position rather than to the recently evaluated peak position The usage of the smoothing function is recommended when tracking satellites where the antenna pointing oscillates less than 25 of the antenna s 3dB beamwidth For tracking inclined orbit satellites the usage of smoothing may be problematic as such satellites may require an significant position oscillation at 12 hours cycle time sin 2wt The smoothing function uses a simple sinusoidal model which does not provide this double frequency component Hence applying the smoothing function for such a satellite with more than 3 hours smoothing time may average the antenna movement path too much 8 3 4 Steptrack Parameters The behavior of the satellite step track is adjustable with a couple of parameters This permits to tune the step track performance for special preconditions arising from the antenna and also the satellite The first parameters listed below are setup parameters they are set once for an ACU installation to adapt the ACU to the antenna and the beacon receiver AZ Antenna diameter The diameter values are used by the ACU software to evaluate the antenna s EL Antenna diameter beamwidth There are separate values for both axes to handle offset antennas as well Beacon RX type With this parameter you specify which type of beacon receiver For a sat nms LBRX beacon receiver set it to SATNMS and set the receiver s IP address accordingly To
77. nes the size of every depointing step the ACU makes in order to find out where the optimal antenna pointing is Setting too high values will cause significant signal degradations during the step track cycle because the antenna moves a too large amount away from the satellite Setting the value too small will let the beacon level jitter mask the level differences caused by the test steps the antenna will not track the satellite properly The step size is specified as a percentage of the antenna s half 3dB beamwidth The ACU calculates the beamwidth from the antenna diameter and the beacon frequency Expressing the step size in this relative way keeps the value in the same range regardless of the type of antenna The recommended value for this parameter is 15 20 You may want to start with 20 and try to reduce down to 15 if the signal degradation during tracking becomes too high The tracking step size is a common parameter for both axes If both axes behave differently you can tweak the antenna diameter settings in the setup Specifying a larger diameter makes the ACU using a smaller step size for this axis If the tracking step seems to be completely out of range you should check if the beacon frequency is set properly The frequency must be the true receive frequency at the antenna entered in MHz not an L band frequency or other IF Tracking mode The tracking mode parameter switches the steptrack on or off With the operation modes ST
78. nna to the calculated position To make this function work satisfactory it is necessary to have the geodetic location of the antenna entered at the Setup page with a sufficient accuracy The first target location labeled adaptive tracking memory is reserved for special purposes If you store to this target location this saves the tracking parameters and the tracking memory as well When this memory location is recalled later on the parameters and the memory contents are restored This may be useful to track another satellite for a couple of hours and then to return to the first satellite If the tracking memory has been saved before the antenna has been moved to the second satellite it may be restored after the C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 23 64 SatService Gesellschaft fiir Kommunikationssysteme mbH antenna returned to the old position You should not use the first target location for general purposes in order to keep it available for the short time storage described above Targets Page Example Target Go Save Delete 0 ADAPTIVE TRACKING MEMORY El 1 19 2 E 1G 11698_8 166 029 34 152 9 131 gt P 2 8 E AB2 11703982 202 275 32 979 12 300 P 3 Intelsat 901 18 214 430 29 924 30 152 2 19 8 E AB2 Tracking 202 266 32 960 25 000 gt E P Numeric orbit position gt 5 4 Tracking Parameters sat nms ACUs with the tracking function installed give acc
79. om ACU ODU DC UM 1411 Page 54 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 8 3 2 ACU And Beacon Receiver explains how to find the best settings for this The parameters in the table below are to be set individually for each satellite They are set at the Tracking page and stored with each target memory Beacon RX frequency This parameter is only of interest if a third party beacon receiver is used The beacon frequency you must enter the frequency received by the antenna MHz not the IF frequency seen by the receiver is used by the ACU to calculate the antenna s beamwidth and an approximated beam pattern With the sat nms LBRX beacon receiver the ACU automatically reads the frequency from the receiver Tracking cycle time The cycle time specifies how often the ACU shall perform a step track cycle The value is to be entered in seconds In fact the parameter does not specify a cycle time but the sleep time between two tracking cycles This means the true cycle time is the time the ACU needs to perform one step track cycle plus the time entered here 300 seconds 5 minutes is a good starting value for this parameter Inclined orbit satellites probably will require a shorter cycle time very stable satellites can be perfectly tracked with one step track cycle every 15 minutes 900 seconds Tracking step size The tracking step size is a very important parameter for the performance of the tracking It defi
80. onssysteme mbH 3 elevation The elevation angle in degrees angle 4 polarization The polarization angle in degrees This column is optional no polarization pointing is angle commanded if this column is missing Memory space is very limited in the ACU ODM The file size is limited to 64 Kbytes being equivalent to about 12 days of AZ EL data in 10 minutes intervals 8 6 Faults and Tracking There are different faults which could occur during operation Please also refer to chapter Operation Below is a collection of all this faults There are the following cases for a fault of one axis TIMEOUT and FAULT are releasable during a tracking cycle A STOPPED fault have to be released with the RESET button Jump Values of angle encoder 5 in azimuth and elevation or 10 in polarisation STOPPED Antenna moves 5sec into the wrong position STOPPED Motor timeout occur because of no antenna movement within the entered time TIMEOUT Motor fault input triggered for example from frequency converter FAULT There are the following cases for a STOPPED fault of all axes together which have to be released with the RESET button e Trigger emergency stop input e Click the STOP button on the web interface All faults are released by clicking the RESET button on the web interface or by sending the remote command mrst 0 The RESET button activates the MOTOR RESET outputs of all three axes for a quarter second and delete the
81. ot fit to describe the satellite s motion If this value causes false alarms too often you may want to raise the threshold to 50 Setting it to 0 switches the threshold monitoring completely off 8 5 Program Tracking Program tracking is a tracking method which lets the antenna follow a path which usually has been calculated by an extern software This software produces a list of time stamp antenna pointing records The list is copied to the ACU and the ACU is switched to PROGRAM track mode The ACU now moves the antenna following the path described in the file This way of tracking has a couple of advantages e There is no beacon receiver needed e Even very low elevation satellites may be tracked e Also objects which are not in a geostationary orbit may be tracked for a couple of hours provided that the object of interest does not move to fast The main disadvantage of program tracking is that prediction calculations for stationary satellites always are only valid for a couple of days then a new file must be calculated and loaded to the ACU 8 5 1 Practical Usage To use the program tracking facility of the ACU follow the step by step instructions below 1 Create a program txt file with the antenna pointings you want to track SatService GmbH offers a PC Software for this purpose which calculates the antenna pointing from commonly used ephemeris data sets for geostationary satellites You also may create the file by your own
82. ould adjust the antenna pointing then enter the satellite s name sat nms ACUs with the tracking option installed display the actual tracking mode state in this field ACUs without tracking show OFF all the time In STEP and ADAPTIVE tracking modes this field shows what the tracking actually is doing and some information about the tracking data in memory fill tells how many hours of step track data for calculating a model the ACU actually has in memory This data may be used in ADAPTIVE mode to predict the satellite movement in case of a beacon failure The smoothing which may be applied to the step track also relies on this data age means the age of the most recent successful tracking step In other words this describes how many hours ago the beacon was lost in case of a beacon failure Beacon This field shows the beacon level as read from the beacon receiver Depending on the level source defined at the Setup page this either is the beacon level reported by a sat nms LBRX beacon receiver via TCP IP of the level derived from the ACU s analog input Temperature The actual temperature inside the ACU enclosure This value is for information only C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 21 64 SatService Gesellschaft fiir Kommunikationssysteme mbH ACU Faults If there are any faults with the ACU they are displayed in this field If there is more than one fault at a time the AC
83. outdoor unit is able to act as a standalone antenna control and tracking system without an indoor unit required e The ACU provides an Ethernet interface using the TCP IP and HTTP Internet protocols It can be controlled using any PC providing an Ethernet interface and a web browser like the Microsoft Internet Explorer The ACU runs a web server which acts as a user interface to the antenna controller e The ACU is prepared to read the receive level of a sat nms beacon receiver through the TCP IP interface e The flexible interface design of the ACU enables it to control most types of motor driving antennas for geostationary satellites Supported motor controllers are configurable in the field e Power relays This simple solution is suitable for antennas using 2 speed AC motors e Frequency inverters Speed and acceleration ramps are programmed into the inverter module with this solution e Servo controllers Used for DC motors at small antennas Supported position sensors are separate hardware interface modules for each axis e Resolver Interface The resolver interface module contains a resolver to digital chip which does the decoding of the resolver sin cos signals e SSI Interface SSI is a high speed serial interface used by modern digital position encoders e DC Voltage Interface The third position encoder interface module contains an A D converter which is suited to measure the DC voltages produced by simple inductive angle encode
84. protocol The ACU also packs its reply in a protocol C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 38 64 SatService Gesellschaft fiir Kommunikationssysteme mbH frame as described above Incomplete frames checksum errors or address mismatches let the ACU ignore the message The time between the characters of a message must be less than 5 seconds or the ACU will treat the message as incomplete If the ACU is set to the device address NONE it uses a simple line protocol instead of the framed protocol described above Messages sent to the ACU have to be terminated with a carriage return character ASCII 13 the ACU terminates replies with a CR LF pair ASCII 13 10 There is no echo for characters entered hence this protocol easily may be used for computer based remote control This setting is also used for allowing communication to an optional frontpanel display and keyboard if implemented If TERM is selected the serial interface is used to allow communication between the ACU and a sat nms Handheld This function is not available at ACU RMU and ACU19 Version 7 4 Parameter list The table below shows the complete list of M amp C parameters the ACU knows in alphabetical order For each parameter the valid range and a short description is given description AZ antenna 3dB beamwidth Antenna abs altitude AZ Amplitude 360 000 360 000 AZ Calibration offset Calculate offset from Az val
85. resh once a second The refresh rate may be adjusted on the setup page from software version 2 1 007 or higher The navigation bar at the left contains a couple buttons which build the ACU s main menu Pointing Pointing This button switches back to the main page you already see when you connect Tact to the ACU This page displays the actual antenna pointing together with some status A information You also use this page to move the antenna to a certain pointing given as Edna azimuth elevation values Q Test FP Seir Target By clicking to this button you switch to the Target page where you can store Setup Em and recall the antenna pointing for up to eight satellites Info Help Tracking sat nms ACUs with the tracking option installed offer the tracking mode and ar tracking fine tune parameters on this page step Move 4 oS Test By clicking to this button you switch to the Test page The Test page shows the low level I O signals of the ACU It helps you to install the ACU or to identify a nooo a ry y r malfunction of peripheral components Sl Setup This button switches to the Setup page which lets you inspect or change less STOP RESET common parameters which usually are set only once to adapt the ACU to it s working environment Info After a mouse click to this button the ACU outdoor module shows a table with information like the serial number of the device or the revision ID and compilation date
86. rs This application is for small antennas especially in the SNG business The paragraphs below give a short overview to the contents of the documentation A subset of this documentation is stored on the device itself the complete documentation is available on the sat nms documentation CD and at www satnms com e Safety Instructions This chapter gives an overview about the safety precautions that have to be C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 4 64 SatService Gesellschaft fiir Kommunikationssysteme mbH observed during installation operation and maintenance e Unit Overview The installation chapter gives informations about the different modules that are integrated in the ACU not ACU ODM and ACU19 e Installation Start up The installation chapter guides through the installation and setup of the ACU outdoor module It describes the mechanical concept of the ACU and the assignment of the ACU s connectors It gives you informations about the starting up procedure Finally you learn in this chapter how to set the ACU s IP address which is a essential precondition to operate the ACU by means of a web browser e Operation The sat nms ACU is operated using a standard web browser like the Internet Explorer on MS Windows based computers The user interface design is straight forward and clearly structured Operating the ACU is mostly self explanatory Nevertheless the Operation chapter outlines the map
87. s the ACU resets the models of both axes Adaptive tracking will be possible not until 6 hours after this happens During adaptive tracking the ACU evaluates for each axis a figure called jitter The jitter value describes standard deviation of the measured peak positions with respect to the positions calculated from the currently selected model The figure is also expressed as a percentage of the antenna s beamwidth low values indicate that the model ideally describes the antenna s path High values indicate that s something wrong The step track results may be to noisy at low amplitudes or the model does not fit at all This may be the case if a satellite gets repositioned in the orbit A typical threshold value is 20 this will detect very early that a model does not fit to describe the satellite s motion If this value causes false alarms too often you may want to raise the threshold to 50 Setting it to 0 switches the threshold monitoring completely off AZ Maximum model type These settings let you limit the adaptive model to a simpler one the ACU EL Maximum model type would choose by itself The maximum model type can be set individually for each axis Normally you will set both axes to LARGE which leaves the C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 26 64 SatService Gesellschaft fiir Kommunikationssysteme mbH model selection fully to the ACU s internal selection algorithms In cas
88. sat nms ACU ODU DC Antenna Control Outdoor Unit DC User Manual Version 4 3 2012 11 08 Copyright SatService Gesellschaft f r Kommunikatiosnsysteme mbH Hardstrasse 9 D 78256 Steisslingen satnms support satservicegmbh de www satnms com www satservciegmbh de Tel 49 7738 97003 Fax 49 7738 97005 SatService Gesellschaft fiir Kommunikationssysteme mbH Table Of Contents Table Of Conte ici ee a ARE ELLE a 1 LICEO UCLM enn e A A Wet A ee even 4 Z Safety Instr ctions 2 24 oren a a e a arean a a A AEE E TE OTE KO EES 6 3 The sat nms ACU OQDU DG ua 6 3 1 sat nms ACU ODM reee een a it enaa p a A ae 8 3 2 Power supplies for sat nms ACU ODM ooooococnnnnnnononnnonononononononononononononnnnnnnnnnnnnnnnnnnonnnonononnnonenenenenes 8 3 3 Power supply for motor drivers ooooococcnonononononononononononononononononononononononononononononononononononeneneninenenos 8 3 4 MOtor DAVE A AS A AA 8 3 5 Circuit breakers una A A AA land dete A A ata dez wera tend doti 10 3 6 COMA areas ee aaa rn ea Run eiees Ave ey 10 3T pera S A 10 SiO Cater E E En E A A E E T 10 3 9 Optional arr Ventilation ita a ei A De Bee 10 4 Installation 2 2 AA A ei Aia 10 4 1 Mechanical installation iavecens fobvvens ioe esis iodueeagieaueess 6bvevasieuueeds iadedeagsteeseaaies 11 4 2 Interfaces to the Antenna Pin descriptions 00ooooooooooonononononono nono nonononononono nono nono nono nono non nn nn nn 11 4 2 1 Angle Encoder Connection cdta droi
89. se components are described in the next chapters As the unit is available in different versions optional LNA power supply with or without Polarisation drive ect the following picture shows one standard cabinet The look and the arrangement of the units may vary depending on your demand LRG Racy ir IB a Es y Y y No component No component EN sat nms ACU ODM 5 Circuit breakers 2 Power supplies for sat nms ACU ODM 6 Contactor 5 Power supply for motor drivers 7 Terminals 3a Capacitor for motor driver power supply 8 Thermostat for heater www satnms com ACU ODU DC UM 1411 Page 7 64 C 2014 SatService GmbH SatService Gesellschaft fiir Kommunikationssysteme mbH Motor drivers n a Optional air ventilation 3 1 sat nms ACU ODM The sat nms ACU ODM is the core module of the sat nms ACU ODU For the detailed operation of the antenna controller please refer to chapter 5 Operation Another interesting chapter is belonging the ACU ODM is 4 3 Startup here you find also the description how to change the IP address of the unit in order to integrate the antenna controller in your sub net A short version of the documentation could also be found on the internal website of the sat nms ACU ODU Just enter the IP address of the unit standard IP is 192 168 2 69 into the Web browser of a connected computer and press the HELP button on the left side 3 2 Pow
90. sion 4 3 2012 11 08 C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 5 64 SatService Gesellschaft fiir Kommunikationssysteme mbH 2 Safety Instructions Safety The mains shall only be connected provided with a protective earth wire Any interruption of the protective wire inside or outside the sat nms ACU is likely to make the unit dangerous Intentional interruption is prohibited The unit described in this manual is designed to be used by properly trained personnel only Adjustment maintenance and repair of the exposed equipment shall be carried out only by qualified personnel who are aware of hazards involved Refer servicing to qualified personnel To prevent electrical shock do not remove covers For the correct and safe use of the instrument it is essential that both operating and servicing personnel follow generally accepted safety procedures in addition to the safety precautions specified in this manual Whenever it is likely that safety protection is impaired the unit must be made in operative and secured against unintended operation The appropriate servicing authority must be informed For example safety is likely to be impaired if the unit fails to perform the intended measurements or shows visible damage Ensure that the cabinet is proper connected to the protective earth conductor The circuit breaker that fuses the mains for the sat nms ACU has to switch off all phases AND the neutra
91. specified with an arbitrary precision however the device will reply only a fixed number of places The ACU recognizes a decimal point numbers must not contain any commas e There must not be any whitespace in front or after the in a message e If the command query is not of the form name value or name the ACU replies the message SYNTAX e If the message syntax is OK but contains an unknown parameter name is used the reply is UNKNOWN e Numeric parameters are cut to the limits defined for this particular parameter e Misspelled choice values cause the ACU to set the first value of the choice list e Assigning a value to a read only parameter will cause no fault however the ACU will overwrite this parameter immediately or some seconds later with the actual value 7 2 The TCP IP remote control interface C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 37 64 SatService Gesellschaft fiir Kommunikationssysteme mbH Controlling the ACU through the network is done by means of HTTP GET requests Setting parameter values or querying readings or settings all is done by requesting HTTP documents from the ACU The message to the ACU thereby is coded into the URL as a CGI form parameter The ACU replies a one line document of the MIME type text plain The document name for remote control is rmt hence assuming the ACU is listening to the IP address 10 0 0 1 requesting a document with the URL http 10 0
92. t step If the delay is too long the impact of fluctuation to the measures level grows and may cover the small level difference caused by the test step With the sat nms LBRX beacon receiver best results are achieved if the receiver is set to 0 5 Hz post detector filter bandwidth and a measurement delay of 1500 msec Smoothing interval This parameter controls the smoothing function Setting it to zero disables smoothing A detailed description of this function you find at chapter 8 3 3 Smoothing 8 4 Adaptive Tracking Adaptive tracking is an extension to the standard step track method The ACU records the tracked positions over several days It computes a mathematical model from the recorded data which is used to predict the antenna position in case of a beacon receive failure The following paragraphs describe how the sat nms adaptive tracking algorithm works 8 4 1 The sat nms Adaptive Tracking Algorithm The motion of a geostationary satellite at the sky mainly is caused by an inclination of the satellite s orbit with respect to the earth s equatorial plane sometimes also by the fact that satellites decelerate in orbit The motion seen from the antenna s point of view can be described as the sum of harmonic oscillations with the frequency being multiples of the reciprocal of an sidereal day The mathematical models used by the sat nms adaptive tracking algorithm to predict the satellite s motion are finite sets of harmonic el
93. t petanca ive 11 4 2 2 Limit switch and emergency switch connection oocccnnnnnnnnnnnnnnnnnnnnnnnnnnnonononnnnnnnnnnnnnnnnnnninininos 13 4 2 3 MOtors conecto ii ee eee a 14 4 2 4 Mains MECA nn une di 14 4 2 5 Ethernet connection AA AAA 14 4 SiSLATEUP ros eraino i liar ahatenes ea stiegen Pe E a a e T tiena Pibe ENES aS 14 4 3 1 Setting the TP Address 2 50 258 Aa 15 4 3 2 Limit Switches ar a nen ii un EE S E Eoee EEE dead 16 4 33 Angle detectors A 0 en E RAEE E E E AARE 17 4 3 A Mot S cti A AA A A AAA AA A AS 17 a AAA nine eee ie 17 4 3 6 Backup of ACU settings iii nn ah Sn E a oe 17 DS OPSratlon tesy Blaues itavdedsadarvasdeladteescsdetosd ctawtedaceanwdudebaleguscodutead hantalssspnsuslehittusscchntenditintefensnfl 20 5 1 The Web based User Interface ooococcnonononononononononononononononononononononononononononononononononononenenenenenos 20 5 2 Ant nn PON A ea agile dian aa ie eae 21 3 3 Target Memory na nee nash cuedanetetes sncuchausecncet vagn ceed aacaeees weghcoadda cases sengncacdegencaedtags 23 5 4 Tracking P rameters 8 4 282 B 8 2 82 ideen il 24 I Lest RO NR 27 OOPS AN A A AS AAA de a a 28 3 7 Handheld Terminal r 2 2 2 nto veve a ae ee aa eben La 34 6 Frontpanel oper tiol 4 22 30 OO 36 7 Remote Control reine aed a Anke nk a i nee a 36 7 1 General command Syntax eee eeeeeeeeeceeeeeceeececeeeeeeeceeeeeeeceeeceeeeeceeeceeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeee es 37 7
94. tage of the full 3dB beamwidth B beamwidth The 3dB beamwidth as calculated by the ACU from the antenna diameter in this axis and the beacon receive frequency This is the full beamwidth the angle between both 3dB points in the antenna pattern S step size The absolute step size used by the step track in this axis Time The actual time of the ACU s internal clock GPS State The actual state of an external GPS receiver connected to the ACU if applicable Antenna Pointing Page Example C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 22 64 SatService Gesellschaft fiir Kommunikationssysteme mbH Azimuth Elevation Polarization 219 089 27 471 70 049 Target value 219 080 Target value 27 461 Target value 70 082 Target name SES4 22 W RX 11451M003 Tracking mode ADAPTIVE SLEEPING sleep 317s fill 111 1h age 0 0h Beacon level 82 54 dBm var 0 00 dB Temperature 36 8 C ACU Faults Tracking Faults AZ Tracking State M SMALL A 11 J 1 B 0 496 S 0 056 EL Tracking State M SMALL A 15 J 2 B 0 496 S 0 050 Time 2012 11 27 12 42 37 GPS State DISABLED 5 3 Target Memory The page Targets gives access to the ACU s target memory The ACU is capable to remember the pointing and tracking parameters if the ACU has the tracking module installed of up to 99 satellites Managing these memories is done with the Targets page The page displays a table with all pointings ac
95. ted Between three trimmers are located where the maximum current high and low speed could be adjusted When using a 24VDC power supply the adjustable range is trimmer range Current Adj 0 5A 15A Low Speed 6 5VRMS 11 7VRMS High Speed 10 5VRMS 22 4VRMS All interfaces are realized with altogether 4 Phoenix combicon connectors type MSTBT 2 5 3 ST By this an easy replacement of the unit is possible Use 24VDC as control signal ATTENTION As a PWM puls width modulation is used to realize the speed control it is b absolutely necessary to use shielded cables for connecting the motors in order to prevent disturbance due to harmonic waves Take care that the shielding of the cable is connected only on one side of the cable either on driver or on motor side This is to prevent ground loops We recommend to connect the shield to PE Pin of the DC driver and isolate shield on motor side The following table shows the pin description of the motor drivers pin signal description type speed selection connect 24VDC for low speed OV or floating selects high IN speed GND for control voltage IN in OK condition this pin is connected to COM by an optocoupler In case OUT of fault state is high Z R right apply 24VDC here to drive motor right IN C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 9 64 SatService Gesellschaft fiir Kommunikationssysteme mbH COM C
96. th The antenna looks more to the west for larger values e Elevation Larger values mean higher elevation e Polarization The feed turns clockwise when looking through the antenna to the satellite for increasing values When operated on the southern hemisphere the polarization sense must be set the other way round Motor The ACU knows two different configuration modes to control a motor driver They are driver type called DIR START and DUAL START In DIR START mode the FWD signal switches the motor on off the REV signal controls the motor direction This is the configuration many frequency inverters use In DUAL START mode the FWD signal switches the motor on in forward direction REV activates the motor in reverse direction This configuration mode is convenient to control a motor with relays Beside the modes DIR START and DUAL START you may set the motor driver type to NONE which prevents the ACU from controlling the motor at all Low The ACU controls a motor at two speeds If the actual position is far away from the target speed value the ACU commands the motor to use the fast speed Once the antenna comes close to threshold the target value the ACU slows down the motor The low speed threshold sets the angle deviation which lets the ACU use the fast motor speed Pointing The ACU performs the motor control as a closed loop if the angle reading and the target hysteresis value differ the motor is switched on to compensate the
97. tion Connect the ethernet cable for remote controlling directly to the sat nms ACU ODM the core module of the cabinet Use a standard network cable with RJ45 connectors to connect the sat nms ACU ODU to an ethernet hub If you want to connect your computer and the ACU directly without using a hub you need a crossover cable for this with swapped RX TX lines Please refer to chapter 5 Operation and to chapter 7 Remote Control for detailed informations about remote controlling 4 3 Start up This chapter describes how to install and set up the sat nms ACU ODU It is a step by step description without detailed description If you need more detailed description for e g some parameter settings please refer to chapter 5 Operation all of the parameters are described here Before you start please first read the Safety Instructions chapter It contains some important recommendations to prevent damage from the ACU Then we strongly recommend to do a first setup of the ACU on a lab desk before installing it at it s final location This is mainly for the following reason To setup the ACU s IP parameters the PC used for configuring and the ACU must either be connected to C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 14 64 SatService Gesellschaft fiir Kommunikationssysteme mbH the same Ethernet hub or must be connected directly with a crossover cable The initialization program does not work through routers or inte
98. ton For special applications however it might be helpful to set the step delta to a much greater value C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 29 64 SatService Gesellschaft fiir Kommunikationssysteme mbH Position With this parameter you set the type of position sensor the ACU shall read for this axis sensor Principally the ACU is capable to read SSI RESOLVER and ANALOG type position type sensors The selected sensor type must match the type of interface board installed in your ACU It is not possible to switch from SSI to RESOLVER or vice versa without changing the interface module When selecting a SSI type position encoder also the number of bits and the encoding scheme must be selected For the position sensor type parameter these values are combined to one name E g SSI 13G means 13 bit Graycode SSI sensor SSI 24B means 24 bit binary encoded SSI sensor Beside the SSI xxX RESOLVER and ANALOG selections this parameter offers the choice NONE which tells the ACU not to read a position encoder at all With this selection you can tell the ACU if the polarization is not to be controlled by the ACU If you are using multiturn SSI encoders you will have to scale the reading See Calibration scale below Pre scale The pre scale calibration offset is added to the raw position encoder reading before scaling is offset applied The pre scale offset is defined as an 8 digit he
99. tually stored By clicking the icons in the table settings may be stored recalled or deleted If a memory location has stored a pointing the table shows a blue arrow in the Go column of the table Clicking to this arrow recalls the settings stored for that target and moves the antenna to the stored pointing The ACU displays a confirmation dialog before it actually recalls the target memory Only if you click to Submit in this dialog the antenna moves to the stored location Save For each memory location the table shows a floppy disk icon in the Save column Clicking to this icon saves the actual pointing and tracking parameters if applicable to the selected memory location Again there is a confirmation dialog page before the data actually is saved Delete Analogous to the Save icon the table shows an eraser icon in the Delete column The icons only are shown for the memory locations which are in use Clicking to the eraser icon clears the selected memory location after a confirmation inquiry Numeric orbit position The table contains an additional row at the bottom labeled Numeric orbit position Clicking to the blue arrow icon in this row opens a dialog where you are requested to enter the orbit position of a satellite you want the antenna to point to After you pressed Submit in this dialog the ACU computes the antenna pointing for the orbit position you entered and immediately moves the ante
100. ue see below AZ model coefficients 180 000 180 000 Antenna course ABCDEFG NONE RS485 address 0 000 2 000 AZ Pointing hysteresis NORMAL INVERTED AZ Sense invert AZ Peaking jitter 0 000 90 000 Antenna latitude alon 180 000 180 000 E Antenna C 2014 SatService GmbH www satnms com ACU ODU DC UM 1411 Page 39 64 SatService Gesellschaft fiir Kommunikationssysteme mbH amax 180 000 360 000 character string 0 000 180 000 SMALL MEDIUM LARGE AZ OVER EL POLAR DUAL START DIR START NONE Antenna mount type AZ Motor driver type 180 000 180 000 00000000 FFFFFFFF AZ Pointing AZ raw pointing 0 000000 100000 000000 AZ Calibration scale SSI 13B SSI 13G SSI 17B SSI 17G SSI 18B SSI 18G SSI 19B SSI 19G SSI 20B SSI 20G SSI 24B SSI 24G RESOLVER VOLTAGE NONE 0 000 90 000 AZ Position sensor type AZ Low speed threshold AZ Step delta 180 000 180 000 Az target value 0 32000 PARALLEL SEQUENTIAL AZ Motor timeout AZ tracking step size Axes control mode 25 samples Level averaging 1000 000 40000 000 MHz bcip aaa bbb ccc ddd bcof 200 00 0 00 dBm Beacon RX frequency Beacon RX IP address Beacon RX OV level besc 5 0000 5 0000 V dB Beaco
101. umber 31 the most significant bit in this number description OUT AZ FWD C 2014 SatService GmbH WWWw satnms com ACU ODU DC UM 1411 Page 46 64 OUT_AZ_REV azimuth motor reverse SatService Gesellschaft fiir Kommunikationssysteme mbH OUT_AZ_SPD1 OUT_AZ_SPD2 azimuth motor low speed azimuth motor hi speed OUT_AZ_RESET OUT_AZ_RESERVE azimuth motor driver reset reserved for extended motor control OUT_AUX1 not used OUT_AUX2 not used OUT_EL_FWD elevation motor forward OUT_EL_REV elevation motor reverse OUT_EL_SPD1 elevation motor low speed 11 OUT_EL_SPD2 elevation motor hi speed 12 OUT_EL_RESET elevation motor driver reset 13 OUT_EL_RESERVE reserved for extended motor control 14 OUT_AUX3 not used 15 OUT_AUX4 not used 16 OUT_POL_FWD polarization motor forward 17 OUT_POL_REV polarization motor reverse 18 OUT_POL_SPD1 polarization motor low speed 19 OUT_POL_SPD2 polarization motor hi speed 20 OUT_POL_RESET polarization motor driver reset 21 OUT_POL_RESERVE reserved for extended motor control 22 OUT_AUX5 not used 23 OUT_AUX6 not used 24 OUT_SUMMARY summary fault relay 1 OK 25 OUT_TRACKING tracking fault relay 1 OK 26 OUT_BCPR1 27 OUT_BCPR2 reserved for beacon receiver frequency select reserved for beacon receiver frequency select 28 OUT_BCPR3 29 OUT_BCPR4A reserved for beacon receiver frequency select
102. xadecimal value in normalized position encoder ticks 00000000 FFFFFFFF equivalent to the full range of the encoder 0 360 with single turn encoders The pre scale offset must be adjusted to avoid any 7FFFFFF to 8000000 overflow within the used range of the encoder The value is added to the encoder reading neglecting an overfly eventually occurring Thus the offset implements a 360 turnaround automatically The pre scale offset may be computed and set manually or by assistance of the ACU s automatic calibration function as described below Post scale The post scale calibration offset is added to the position value before the angle value is offset displayed but after the scaling is applied The post scale offset is defined in degrees of AZ EL POL The ACU provides a function to calculate and set both the pre scale and the post scale offset from a known pointing 1 Set the calibration scale gear ratio for the axis this calibration parameter is described with the next paragraph 2 Set the soft limits of the axis to preliminary values In most cases this needs not to be very accurate the ACU needs this information to calculate the pre scale offset to shift the encoder overflow outside the used range 3 Optimize the satellite pointing for the reception from a satellite for which the azimuth and elevation values are known 4 Click to the calc label beside the calibration offset 5 Enter the known pointing angle for the sate
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