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Preshower Front-End Boards News LHCb group / LPC Clermont News TRIG-PGA Bit Flip Behaviour

Preshower Front-End Boards News LHCb group / LPC Clermont News TRIG-PGA Bit Flip Behaviour Bit Flip Simulations Conclusion. 1. PS FEB Validation : Data Path. 2 First Final Prototypes FE Boards received from Hitachi Fully Tested @ LPC Test Bench = FUNCTIONNAL

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Preshower Front-End Boards News LHCb group / LPC Clermont News TRIG-PGA Bit Flip Behaviour

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  1. Preshower Front-End Boards News • LHCb group / LPC Clermont • News • TRIG-PGA Bit Flip Behaviour • Bit Flip Simulations • Conclusion

  2. 1. PS FEB Validation : Data Path • 2 First Final Prototypes FE Boards received from Hitachi • Fully Tested @ LPC Test Bench = FUNCTIONNAL • Production tests processes ready • FEPGAs • data processing path • offsets • Analogic and the DAQ parts by analogic injection with AWG and DAQ through the SEQPGA • Power-up failure SEQ ?, ‘random’ Problematic with multiple Boards Stable Offsets over 55 h ‘sine’ injection with AWG

  3. 1. PS FEB Validation : Trigger Path • Functioning of the delay chips & Synchronisation • ~OK, ongoing studies • Connectivity on the trigger path: OK • FEPGA-TRIGPGA • inputs/outputs with memory boards • Trigger algorithm: OK see also Combined Tests in Building 156 Manufacturer JTAG Tests for Production • Basic tests on wires between PGAs, spot soldering defects • Improved JTAG tests including most of the board I/Os with dedicated back-plane • data conversion, access to individual bits @ 40 MHz, TTL levels • internal buses, pga pins + links drivers and connectors • Limitation : no JTAG access to analogue parts and ADCs

  4. 1. TRIG-PGA ISSUE An issue was spotted with the APA450 TRIG-PGA Some input patterns lead to erroneous output This failure can be correlated to inputs Bit Flip Rate ( BFR ) Failure diagnostic : output values missing, then repeated TRIG-PGA enters a ‘Blocked’ status We are in touch with ACTEL France No obvious problem from PGA code, implantation Internal to APA450, Noise handling issues suggested ? • Meanwhile … • … TRIG behaviour extensivelly studied @ LPC, Clermont Test Bench …

  5. 2. Bit Flip Generation Monte-Carlo strategy to study BFR impact 8 words of 8 bits Mask n/8 2 Internal BCID counters [0; 255 ] Average BFR = 2 % Table 1: Bit usage for the TRIG bit flip tests. In the last raw are also indicated the fraction of the total 188 bits varied during the tests. (*) The BCID counters of ECAL bits have a particular status. BFR = flips / 188 40 s LHCb @ 40 MHz = 2 days of injection Table 2: Bit Flip Rate generation strategies. For the RAMs setup all data, except BCIDs were taken randomly at each cycle. In MB runs in order to finely investigate the problematic area of high BFR we used a combination of some bits being fully flipped while others were alternated with random patterns.

  6. 2. TRIG-PGA Failure Distribution Failure occurs on average when cumulating some amount of Bit Flip Board P#8-01 Board P#8-02 • Statistical spread: • Fluctuations in the BFR over time due to BCIDs, pattern randomization protocol • Inherent. Even for same inputs few % spread Figure 1: TRIG PGA failure in the RAM configuration for a mean BFR of ~47 %. The figure shows the distribution of cumulated flips in PS and SPD bits before failure occurs. The open circles stand for board P#8-01 and the plain dots for board P#8-02. Error bars are statistical.

  7. 2. TRIG-PGA Failure as BFR • There is a threshold BFR, fr,0, below which no failure occurs. • Failure is not driven by a dynamical process. • Below the threshold, the TRIG-PGA can re-generate. fr,0 Relax BFR = 5 % Additional cycles before failure Relax BFR = 16 % Relax Blocked Postponed failure sequency

  8. 2. TRIG-PGA Failure as T, Clock f Failure depends on Temperature, Clock frequency No failure @ -55 ºC No failure below 25 MHz Figure 4: TRIG PGA failure in the MB configuration for various temperatures and operating clock frequencies. On the left is shown the failure cycle number for different temperatures. The usual conditions encountered in the lab were of 30 ºC. The right figure shows the failure cycle number for various operating frequencies. The nominal frequency is 40 MHz. Below 25 MHz no failure occurs up to a maximal 39 % BFR.

  9. 2. TRIG-PGA Recovery • Once blocked the TRIG-PGA can recover if BFR below threshold • Full recovery is long … ~ 103 cycles ‘Exhausted’ plateau Full recovery 1st load 2nd load Relax Blocked Blocked Recovery Sequency Recovery litle depends on load and relax BFR values ( except threshold )  Suggests time driven mechanism

  10. 2. TRIG-PGA Failure Cost Model • Failure cycle follows a simple ‘Cost’ model as BFR • Assume cost is stationnary Cost modeled from data Cross-check model Fully random BFR in perfect agreement with data ~ 20 % bias when BFR varies in time ; BOOT ? Cost / cycle ( % ) Blocked Cross-check sequency

  11. 3. TRIG-PGA Bit Flip Expected in LHCb • Bit Flip simulated from DC 06 minimum bias pp events • (103 events / cell) • Set SPD threshold to 0.3 MIP = very low L = 5·1032 cm-2·s-1 • Select the 2 ‘hottest’ boards • (close beam line) BCID Counters Average BFR well below failure Threshold But … Distribution extends well above ( ~ 3 % above ) Threshold Table 3: Mean Bit Flip Rate for cells ( 82, 91 ) at a luminosity of 5·1032cm-2·s-1.The fractions at which the various bits contribute to the BFR are also indicated. Figure 9: Bit Flip Rate distribution for pp events at a luminosity of 5·1032cm-2·s-1and for the two ‘hottest’ cells ( 82, 91 ) of the PS/SPD system. The SPD threshold was set as low as 0.3 MIP.

  12. 3. TRIG-PGA Failure Probability @ LHCb • MiniBias pattern injection looped @ 40 MHz over 1 day : No TRIG-PGA failure • But always same pattern … 40 s LHC = 2 days tests Cost Below 10 % Estimate failure from simulation / Cost model 116 min @ 40 MHz simulated in Lyon batch farm 1st : Bunchs of 65 k cycles  No faillure predicted 2nd : Extrapolate to 1 yr LHCb ‘non-stop’ Failure expected @ cost ~ 80 % SHOULD NOT HAPPEN in standard conditions Figure 10: Cost probabilities and TRIG-PGA failure as simulated. The left figure shows the maximal cost distribution within 65 k events runs. The right figure is the failure probability within 1 year of LHC operation and assuming various cost thresholds.

  13. 4. CONCLUSION THE PS FEB ARE WORKING PROPERLY fits our needs PS FEB BOARDS EXTENSIVELY TESTED @ LPC & ongoing in Building 156 • Power-up issues @ SEQ ? • TRIG-PGA ‘pathologic behaviour’ • No problem expected in standard LHCb conditions • Actel France @ LPC Monday, December 4th  Production Should Follow

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