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Status of the electronics systems of the MEG experiment

Status of the electronics systems of the MEG experiment. HV. 1:1. 1:1. Active Splitter. Active Splitter. 1:1. 1:1. Trigger. 216. 4:1. 4:1. Trigger. front. PMT. atten. Trigger. LXe. 630. lateral. PMT. 3 crates. HV. DRS. DRS. 1:1. Active Splitter. 60. 120. DRS. bars.

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Status of the electronics systems of the MEG experiment

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  1. Status of the electronics systems of the MEG experiment

  2. HV 1:1 1:1 Active Splitter Active Splitter 1:1 1:1 Trigger 216 4:1 4:1 Trigger front PMT atten Trigger LXe 630 lateral PMT 3 crates HV DRS DRS 1:1 Active Splitter 60 120 DRS bars PMT Ramp 1:1 DRS 4:1 TC DRS HV DRS 8:1 APD Pre-Amp fibers 512 5 crates HV Hit registers 32 Wires Pre-Amp 576 DC 1156 4 boards Strips Pre-Amp Aux. devices Electronic chain

  3. pE5 area ‘counting room’ Trigger Trigger Trigger Trigger clock start stop sync Front-End PCs Main DAQ PC PC (Linux) PC (Linux) PC (Linux) PC (Linux) Run start Run stop Trigger config PC (Linux) DRS PC (Linux) DRS Busy Error PC (Linux) DRS DRS PC (Linux) DRS PC (Linux) DRS 20 MHz clock PC (Linux) Hit registers Event builder PC (Linux) PC (Linux) Gigabit Ethernet Trigger signal Event number Trigger type PC (Linux) PC (Linux) On-line farm storage DAQ and control Ancillary system 3 crates 6 crates

  4. HV

  5. HV Active down regulation of an external HV supply PSI design • 10 chn per board • 180 chn per 3 HE crate • Back side connector • Total of 6 crates 4 different requirements: • Lxe: 1000V , 100 uA • TC bars: 2400V, 1 mA • TC curved: 500V, <1 uA • DC: 2400V, ~1 uA Commercial HV suppliesdelivered Mass productionin progress Installation inSeptember

  6. Splitters

  7. Splitter layout • ERNI high bandwidth output connector • crosstalk with ERNI connector plus 2m cable is ~ 0.6% Trigger or DRS Input DRS Trigger Power

  8. Backplane layout • Test circuit was implemented on backplane • Debug completed • PCB production in progress, mounting in house

  9. Crates • Mechanic parts and fans delivered • Power supplies delivered and tested Frontal panel Back panel Output (5V-36A)

  10. Cables Inputs • Single coaxial cable (RG178 – 9m long) bundled into a polyester braided sleeve • Negligible crosstalk between cables. DRS outputs • High bandwidth output (DRS) • high density twisted pairs cable (0.68 pitch) 2 m long with one flat zone in the middle (Amphenol SPECTRASTRIP 68p) Trigger outputs • Low density twisted pairs cable (1.27 pitch) 2 m long with 2 flat zone (3M 34p/10p)

  11. Splitter Summary Splitter • first prototype finished in may successfully • PCB production started the first of June • PCBproduction time one month • Component procurement in progress • Board mounting2 weeks end of July • Board test1 week • Boards ready by the beginning of September Backplane • Crates and power supplydelivered • backplane production in Lecce Cables • Trigger cables ready • LXe cables in production • DRS cables in production Installation • Foreseen between September 5 and 20

  12. TC

  13. PMT ramp generator B to Splitter Analog signals to DRS and trigger PMT B S TC Analog Sign. Monitor Passive Splitter RAMP GEN. D/D 6U Eurocards boards 8 boards to Splitters Signals to DRS Dual Threshold OR Constant Fraction OR Leading edge discriminator NIM Signal for any possible use

  14. Production PMT ramp generator • Design of the final boards in progress • Mass production September (?) • system delivery 8 boards October (?) APD pre amplifiers • First prototype with problems on IC and cross talk • Second prototype design and test completed • Mass production and test in progress • system delivery end of July APD hit registers • board design completed • Production and test in progress • system delivery (6 boards – 6U VME) end of July

  15. Trigger

  16. Type2 Front end Ancill Type1 TriggerBoards

  17. System test 4 Type1 2 Type2 2 Ancillary • Synchronous operation • No transmission errors

  18. Splitter-Type1 connection Alpha and cosmic muon events from the Pisa facility

  19. Number of boards: summary table

  20. Number of boards: status Done ! Done ! Boards Type2 • 10 funded • 5 needed • 10 delivered • 10 tested Boards Type1 • 48 funded • 36 needed • 40 delivered • 8 not completely mounted • 40 tested Front-End Boards • 800 funded • 576 needed • 800 delivered • 320 tested Boards Ancill • 8 funded • 4 needed • 4 delivered • 4 not completely mounted • 2 tested

  21. Firmware V1.0 Present Status Type1 : VIRTEX II- PRO (XC2VP20-7-FF1152) • Type1-0 LXe front face • Type1-1 LXe lateral faces  • Type1-2 LXe top,bottom and back face  • Type1-3 TC bars  • Type1-4 TC fibers  • Type1-5 DC  • Type1-6 Auxiliary devices  • Type1-7 LXe back face x Type2 : VIRTEX II- PRO (XC2VP40-7-FF1152) • Type2-0 Final Level completed   • Type2-1 LXe front+up/down faces  • Type2-2 LXe lateral faces  • Type2-3 TC

  22. Board Type3

  23. Board Type3 Modified Type1 boards to produce an auxiliary digitization of the LXe signals • Type3 board 32 channels • Number of boards for the LXe lateral sides(612 chn): 20 • Boards design : ~ready • PCB prototype : end of July • Component delivery:(12 weeks)~ beginning of September • Test: September • Production: October • Installation: end of October

  24. Comments on trigger Installation • Ready: any time from beginning of Jul. to end of Aug. • Should follow the NaI moving system • Should precede the electronic integration Sep. • DAQ computers Configuration • Baseline version V1.0 written • Needs tuning, at least 1 month during purification • Needs analysis tools, under development Documentation • Hardware register list available • Almost available for Type1 • In progress for Type2

  25. DRS

  26. DRS • DRS2 available for all channels • New PMC card finished • Reduced noise 1.2 mV → 0.5 mV RMS • Self-calibration on card • Mass production started • cards expected in August • PSI GPVME boards in production • Delivery end of August

  27. DRS2 issues All issues could be resolved as planned

  28. DRS3 • DRS3 design finished • Prototypes expected in August • Tests foreseen at the end of the year

  29. DRS3 layout • Smaller “standard cells” • Totally > 600,000 transistors • Smaller package (QFP64) • 12 channels/chip • ROI readout and parallel readout to reduced dead time:230 ms → 50 ms → 5 ms

  30. DRS and Trigger Crates 20 cm Issue: “Splitter” rack cannot be accessed easily from back side! Power distribution box

  31. DAQ cluster

  32. DAQ Cluster Layout /home/meg |-- root <- ROOTSYS |-- midas <- MIDASSYS |-- mxml |-- rome <- ROMESYS `-- meg <- MEGSYS |-- meganalyzer |-- megbartender |-- megmc `-- online |-- drivers |-- eventbuilder |-- frontend |-- slowcontrol | |-- bts | |-- calorimeter | `-- scfe |-- trigger `-- VPC 80 GB System Disk RAID 1 (Mirror) VME-Interface Front-End #1 80 GB System Disk RAID 1 (Mirror) VME-Interface Front-End #2 . . . NFS 80 GB System Disk RAID 1 (Mirror) SC-FE 1.2 TG Data Disk RAID 5 /home/meg Data rate 100 MB/s Back-End

  33. Front-end computers • Two DAQ computer installed with DAQ software • Remaining computers delivered • Installation end of July GBit Switch Front-end #1 Back-end1.2 TB disk

  34. Offline Cluster 15 x 500 GB SATA Sun Fire x4100 quad core 4 GB Sun Fire x4100 quad core 4 GB Fiber Channel Switch Sun Fire x4100 quad core 4 GB GBit Ethernet Sun Fire x4100 quad core 4 GB Sun Fire x4100 quad core 4 GB • Ordered on June 14th: 20 cores + 30 TB disk • Easily extensible • Redundancy through GFS/GPFS file systems • GBit link to online cluster requested

  35. Slow control

  36. SCS-2000 • Replaces SCS-1001 unit • 64 I/O lines (analog, digital, opto-coupler, PT100, etc.) • Outputs stable during CPU firmware upgrade (→ BTS control) • “Soft” fuse • LED pulser (40 lines, computer controllable)

  37. BTS slowcontrol • Slowcontrol back-end to MSCB slow control units • Integrated in MIDAS history system • Monitoring and control though MIDAS web pages • More pages added as SC equipment gets operational

  38. MIDAS history

  39. Conclusions • All the key elements of the electronic system are available for integration in September • Some parts will arrive with ~1 month delay

  40. Rack space

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