LECC 2006 Ewald Effinger AB-BI-BL The LHC beam loss monitoring system’s data acquisition card Ewald Effinger AB-BI-BL.

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Presentation transcript:

LECC 2006 Ewald Effinger AB-BI-BL The LHC beam loss monitoring system’s data acquisition card Ewald Effinger AB-BI-BL

LECC 2006 Ewald Effinger AB-BI-BL Outline Introduction: the BLM System Specification of the BLM DAC The data acquisition card FPGA functionality Tests during operation Measurement results Conclusion Acknowledgement

LECC 2006 Ewald Effinger AB-BI-BL Introduction: the BLM System 3680 Ionization chambers 290 Secondary emission monitors 650 BLM data acquisition cards The cards in the arc are installed underneath the magnets in a 19’’ create BLMs Q D 1 2 D

LECC 2006 Ewald Effinger AB-BI-BL Introduction: the BLM System Electronic cards are installed in the nearby side-tunnels, because of reduced radiation level Up to 6 x 19“ crates with 10 DACs are installed in the straight section Signal cable with length up to 600m 1 2

LECC 2006 Ewald Effinger AB-BI-BL Introduction: the BLM System Optical links are connected to 340 threshold comparators (TC) with an optical receiver card on the surface 25 VME creates are distributed around the LHC Each create includes a PowerPC (data logging), a Combiner card (connected to the beam interlock system), and two timing cards USB connected system for test and development Courtesy of C. Zamantzas

LECC 2006 Ewald Effinger AB-BI-BL Specification Radiation tolerant up to 500Gy (20 LHC lifetime) Reliability level SIL3 ( to failure/h) to protect the equipment of damage Current measuring range 2.5pA to 1mA Error +/-25% in the range from 1mA to 1nA Error +100%/-50% in the range from 1nA to 10pA Integration time window 40us

LECC 2006 Ewald Effinger AB-BI-BL Specification Input over-current protection: Input over-voltage protection: Redundant optical data transfer to surface Test features for system check Survey of the card voltage supplies Survey of detector high voltage supply

LECC 2006 Ewald Effinger AB-BI-BL The acquisitions card Essentials of the input circuit Current to frequency converter (CFC) Balanced charge integrator No charge loss (“no blind time”) Very large dynamic range Output frequency depends on input current Input CurrentOutput frequency 1mA5MHz 1uA5kHz 1nA5Hz 1pA5mHz

LECC 2006 Ewald Effinger AB-BI-BL The acquisitions card Measures to fulfill the specification Irradiation of single components (JFET, OP, Comparator, One shot, …) Insertion of fast protection diodes, high voltage capacitors, and leaded resistors on the input ADC added to decrease response time / increase dynamic range Automatic feedback loop with DAC to compensate leakage current due to integrated dose U nom. = 1500V Tested with pulse Tested with pulse 12 bit ADC AD bit DAC A5346 No change -30 to -80pA140pA No change At 500Gy Integrator ComparatorOne-shot

LECC 2006 Ewald Effinger AB-BI-BL The acquisitions card 8 current inputs (CFC) ADC AD41240 CERN ASIC LM4140 voltage reference FPGA for data combination Two redundant GOH from CMS (including CERN ASIC) Line driver CRT910 CERN ASIC DAC AD5346

LECC 2006 Ewald Effinger AB-BI-BL FPGA functional description Actel antifuse FPGA A54SX72A 4024 sequential cells 2012 combinational cells Total logic usage: 85% Pin usage: 100% 40 MHz clock

LECC 2006 Ewald Effinger AB-BI-BL Tests during operation Constant 10pA offset current - Check on channel availability - In case of exceeding limits, a beam dump can be generated Continuous status monitoring - Monitoring of voltage supplies and other status information - Should failure occur, a beam dump can be generated

LECC 2006 Ewald Effinger AB-BI-BL Tests during operation Continuous check during data transmission - Checked at each transmission * Card identity number check * Frame identity number check * Cycle redundancy check - Should failure occur, a beam dump can be generated

LECC 2006 Ewald Effinger AB-BI-BL Tests during operation High Voltage (HV) activation test - 100pA added, dynamic test - Degradation of electronic can be detected - In case limits are exceeded, no beam permission given - To be carried out before each beam fill HV modulation test - Capacitive current injection via chamber electrodes - Degradation of complete chain can be detected - In case limits are exceeded, no beam permission given -To be carried out before each beam fill

LECC 2006 Ewald Effinger AB-BI-BL Measurement results CFC input circuit Dynamic range over 8 decades from 1mA to 10pA Down to 1nA max error of 6.5% Down to 10pA max error of 96%

LECC 2006 Ewald Effinger AB-BI-BL Conclusion Error - +/-25% down to 1nA %/-50% down to 10pA - improvement possible with accurate calibration Radiation tolerance of 500Gy - 74HCT123 (one shot), malfunction at 300 to 350Gy components recovered when not irradiated - 54SX72A (FPGA), malfunction at 480 to 790Gy, no SEU detected up to 1x 10¹² p/cm² - All other components were working up to 1500Gy Input over current and voltage protection - completely fulfilled

LECC 2006 Ewald Effinger AB-BI-BL Conclusion Survey and test features - All features working correctly Optical link - Radiation tolerant design - Installed test system at HERA, no CRC error occurred for several months Extra system test - Temperature test: 0 – 70°C passed - Magnetic field test: 1000Gauss passed, performed for CMS

LECC 2006 Ewald Effinger AB-BI-BL Acknowledgment I would like to thank - K. Kloukinas, P. Moreira, A. Marchioro for providing help with the ASICs from PH/MIC -A. Singovski, F. Vasey, R.Rusack for providing help with GOH from CMS - The beam loss section Further information can be found: -The LHC Beam Loss Monitoring System’s Surface Building Installation (Poster/Paper LECC 2006 from C. Zamantzas) -Functional and linearity test system for the LHC beam loss data acquisition card (Poster/Paper LECC 2006 from J. Emery) -

LECC 2006 Ewald Effinger AB-BI-BL Appendix

LECC 2006 Ewald Effinger AB-BI-BL Appendix Magnet quench levels

LECC 2006 Ewald Effinger AB-BI-BL Appendix Ionization chamber

LECC 2006 Ewald Effinger AB-BI-BL FPGA functional description GOH 1 GOH 2 CFC Tripled Input pins Tripled redundant logic 2 x 2 out of 3 voter connected to two GOHs

LECC 2006 Ewald Effinger AB-BI-BL FPGA functional description 12 bit ADC AD41240 Double data rate bus 5 MHz clk

LECC 2006 Ewald Effinger AB-BI-BL FPGA functional description

LECC 2006 Ewald Effinger AB-BI-BL FPGA functional description

LECC 2006 Ewald Effinger AB-BI-BL Functional description of FPGA

LECC 2006 Ewald Effinger AB-BI-BL Functional description of FPGA

LECC 2006 Ewald Effinger AB-BI-BL FPGA functional description

LECC 2006 Ewald Effinger AB-BI-BL FPGA functional description CID (card identity number) STATUS 1 STATUS 2 (Level 1-8, CFC-ERR 1-8) Count 1ADC 1 Count 2ADC 2 Count 3 ADC 3Count 4 ADC 4 Count 5ADC 5 Count 6ADC 6 Count 7 ADC 7Count 8 ADC8 FID (frame identity number) DAC1DAC2 DAC3DAC4 DAC5DAC6 DAC7DAC8 CRC

LECC 2006 Ewald Effinger AB-BI-BL FPGA functional description