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Published byTobias Terry Modified over 9 years ago
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1 DAQ Update MEG Review Meeting, Feb. 17 th 2010
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2 DAQ Status DAQ modifications Replace DRS2 by DRS4 boards Added synchronization signal between boards Added slow control equipment into DAQ allowing remote control Overview of DAQ performance Average total trigger rate 6.4 Hz ~5 minutes runs with 2000 events Inter-run time: 6.8 s Event size: 9 MB (raw) 2.6 MB (zero suppressed) Data rate 16.6 MB/s, 1.4 TB/day Offline compression ÷ 2 38 TB taken in ~54 days DAQ issues during routine running Lost sync signal: twice a day run restart (10 s) Run startup problem: every few hours retry start (4 s)
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3 Offline Cluster 64 CPUs 150 TB disk DAQ scheme TRG1TRG2TRG3TRG9DRS4DRS5DRS6DRS7DRS8 trigger & sync & trigger type & event # LSB busy internal trigger & busy SYSTEM01SYSTEM02SYSTEM03SYSTEM04SYSTEM05SYSTEM06SYSTEM07SYSTEM08SYSTEM09 Event Builder SYSTEM Logger Archiver
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4 Examples of remote control
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5 “Ghost pulse” problem R “Ghost pulse” 2% @ 2 GHz “Ghost pulse” 2% @ 2 GHz After sampling a pulse, some residual charge remains in the capacitors on the next turn and can mimic wrong pulses Solution: Clear before write write clear Fixed in DRS4 chip
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6 Problems with DRS2 Ghost pulse effect (previous slide) Clock crosstalk (1-2 mV) Temperature dependence offset and gain Complicated calibration DAQ rate was limited by front-end computer software calibration Offset shift of last 64 bins Offset shift with readout frequency Redesign of DRS chip and replacement of complete DAQ electronics
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7 New DRS4 Mezzanine Board clock chip 4 x DRS4 chips (was 2 x DRS2)
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8 On-chip PLL PLL Reference Clock V speed Internal PLL On-chip PLL locks sampling speed to external clock f clk = f samp / 2048 On-chip PLL locks sampling speed to external clock f clk = f samp / 2048
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9 Old vs. New Synchronization DRS2 signal clock trigger DRS4 signal Channel 0 Inverter Chain Channel 1 Channel 2 Channel 3 Channel 4 Channel 5 Channel 6 Channel 7 Channel 8 PLL Skipping Channel 8 during readout reduces dead time by 11%
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10 Global Synchronization master quartz fan out VME Board DRS chips Clock divider and jitter cleaner (LMK03000) 20 MHz 0.78 MHz
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11 Synchronization of clock chips 1.2 GHz 0.78 MHz Chip 1 0.78 MHz Chip 2 n * 0.83 ns SYNC & 20 MHz SYNC has to arrive on all board within 50 ns trigger bus 20 MHz MEG clock has to arrive on all boards within 0.83 ns SYNC has to arrive on all board within 50 ns trigger bus 20 MHz MEG clock has to arrive on all boards within 0.83 ns 20 MHz 50 ns
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12 Problems with synchronization Synchronization pulse has to arrive within 50 ns on all boards optimize trigger bus cabling Clock divider chips need several configuration cycles Re-timing with global clock required firmware modification due to bug in original version syncing did not work initially Time frame changed (global clock edge vs. bin #0 time) modification in analysis and calibration database Due to these problems, the deployment of the DRS4 boards were not as smooth as anticipated
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13 Timing Limitations Requirements: « 100 ps Current timing resolutions measured with split signal: 15 ps (same chip) 30 ps (different chips same mezzanine board) 130 ps (different VME boards) Worse than for DRS2 chips ( Ryu’s talk) Inter-board timing limits our experiment Immediate changes “Bypass wire” Keep DRS3 for timing counters Possible causes Global Clock Jitter Jitter inside DRS4 boards Jitter added by active splitter ~10 MHz 1 mV noise on top of signal clock fan-out PMT splitter trigger + = threshold
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14 Clock Distribution LMK 03000 < 20 ps period < 20 ps period (was 120 ps with old resistor) LMK 03000 < 32 ps relative mezzanine added “bypass wire” to sample original clock jitter of on-board clock distribution eliminated
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15 Aperture Jitter inside DRS chip 3.2 GHz 1.6 GHz slope Intrinsic DRS aperture jitter 1/f sampling if power supply (U) is constant Intrinsic DRS aperture jitter 1/f sampling if power supply (U) is constant
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16 Plan to improve timing Increase sampling speed 1.6 GSPS 3.2 GSPS only firmware modification required goal: end of March Disentangle different contributions to timing Re-measure global clock jitter between crates Measure split pulse jitter before/after active splitter Investigate noise situation in area (XEC timing improved in ’09, e + - timing decreased, TC uses same electronics (DRS3) noise in TC signals ???) Optimize DRS4 timing calibration algorithm can also be applied to old data Lab tests showed ~10 ps accuracy with sampling technique (DRS4 [PSI], SAM [Saclay], BLAB [U.Hawaii]) Goal: Electronics should not limit capabilities of experiment
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17 Daisy-chaining of channels Channel 0 – 1024 cells Channel 1 – 1024 cells Channel 2 – 1024 cells Channel 3 – 1024 cells Channel 4 – 1024 cells Channel 5 – 1024 cells Channel 6 – 1024 cells Channel 7 – 1024 cells Domino Wave Generation DRS4 can be partitioned in 4x2048 cells Running with 2048 cell channels allow sampling speed of 1.6 GHz * 2 = 3.2 GHz with current trigger latency internal timing accuracy should improve ~2x Deal with increased data rate by on-board averaging DRS4 can be partitioned in 4x2048 cells Running with 2048 cell channels allow sampling speed of 1.6 GHz * 2 = 3.2 GHz with current trigger latency internal timing accuracy should improve ~2x Deal with increased data rate by on-board averaging 1.6 3.2 averaging
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18 Reduce dead time Use various binning regions in waveforms Double-buffering in front-end electronics Use multi-threading in run start/stop sequencing (6.8 s inter-run gap 3-4 s = 1% dead time improvement) VME Transfer Further plans Rebinning 2:1, 4:1, … Chip readout 0.5 ms VME Transfer 25 ms Chip readout VME Transfer now reduced data size multi-event buffers Chip readout ready for next event
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19 2 nd Level Trigger Drift Chamber wires are connected to trigger, but too slow to be included in trigger decision (400 ns) Would be possible with 2 nd level trigger scheme Only firmware modifications (spare bits on trigger bus) If trigger rate ÷2, dead time would be ~÷2 1 st LT 400 ns25 ms event stop DRS chips 2 nd LT 1 us Chip readout VME Transfer trigger DRS boards restart DRS chips
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