+ Running Micromegas in ATLAS: status update of DAQ integration and plans Marcin Byszewski On behalf of the MAMMA collaboration. 2/10/2012 RD51 Stony Brook.

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Presentation transcript:

+ Running Micromegas in ATLAS: status update of DAQ integration and plans Marcin Byszewski On behalf of the MAMMA collaboration. 2/10/2012 RD51 Stony Brook M. Byszewski (CERN) David Berge, Raffaele Giordano, George Glonti, George Iakovidis, Paolo Iengo, Vincenzo Izzo, Yousuke Kataoka, Kostas Kordas, Antonios Leisos, Stefanos Leontsinis, Sabrina Perrella, Givi Sekhniaidze, Ourania Sidiropoulou, Mimmo della Volpe, Andre Zibell, SRS development: Hans Muller, Sorin Martoiu, Alfonso Martinez (ALICE)

+ The Goal Compare data from the test chambers with ATLAS data (take these data with no impact on ATLAS data taking) 1. Stand-alone, random trigger (until September 2012) Convenient, Track matching not possible 2. Trigger from ATLAS, data separate (‘parasitic’) Offline synchronisation 3. Fully integrated with TDAQ in ATLAS partition Most of our event fragments empty A lot of discussions and support from CTP / TDAQ / run coordination / Sysadmins. Thank you. 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) 2

+ Micromegas test chambers Front of the LAr calorimeter cryo r ≈ 1 m z = 3.5 m One 9x4.5 cm 2 X-V (2 readout gas gaps) r = m Four 9x9 cm 2 chambers X, Y, XY, XUV Only three read out 1 FEC limit Power supply limits and SRU firmware MBTS, side ASmall Wheel, sec. 9, side A, CSC 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) EIL1 MDTs Installed Feb 2012, read out in stand-alone random trigger mode MBTS LAr Test chambers description and readout in stand alone mode see Joerg Wotschack’s presentation in Run Weekly 24/7/

MBT chambers (LAr ecal) 2/10/2012 RD51 Stony BrookJ. Wotschack (CERN) LAr Calor. MBT0_3 MBT0_4 MBTS MBT0 R ≈ 1 m 2 drift gaps of 4.5 mm each 2 x 190 x(phi)-strips (0.5 mm pitch) 2 x 66 v-strips (1.5 mm pitch) APV25 15 mm 150 mm 200 mm Drift electrode Active area 9.5 x 4.5 cm 2 Z ≈ 3.5 m 4

MMs on Small Wheel II 2/10/2012 RD51 Stony BrookJ. Wotschack (CERN) R16, chamber with 2D readout active area: 9 x 9 cm 2 R16 90 mm R13x R16xy R18y R19xuv CSC (large) Not yet read out Pitch (µm) R13–R R19x350 R19u,v100 5

+ Some typical events displays 2/10/2012 RD51 Stony BrookJ. Wotschack (CERN) L = 3.3 x cm -2 s -1 L = 3.3 x cm -2 s -1 x strip number Charge MBT0_3 MBT0_4 Charge Time (25 ns) Charge x strip number Uncorrelated hit (≈1/1000 triggers with activity) (≈each trigger with activity) 6

+ Rates / Occupancy / data size Rates: ≈20 kHz/cm L=10 33 cm -2 s -1 7 strips (16 time bins) 10kHz readout (100kHz * 0.1 due to slow readout) Up to 10MB/s by varying time window and data reduction mode (36GB/h) Total data: for 10 weeks, 5 days, 10h runs 17 TB of LV1 data Rate: 30 Hz/cm L = cm -2 s - 1 Majority (90%) of events with uncorrelated hits 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) MBT0SW 7

+ Current readout: ½ ROD SRS – based ROD: RD51’s SRS system APV25 chips (CMS Si tracker) (16+4) HDMI cables (10) SRS FEC (ADC, Ethernet) Data to a DAQ PC in USA15 mmDAQ / RECOmm 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) APV25 FEC (ADC/Eth ernet) FEC (ADC/Eth ernet) Switch (Cu  Optical) Switch (Cu  Optical) DAQ PC USA 15 UX 15 HDMI Ethernet fibre Slow control + Data Cu 8

+ SRS – based Readout Front end electronics: APV25 chips (CMS tracker, no other choice) HDMI cables (LV, data) ROD in UX15: SRS FEC – digitization, peak finding, zero suppression DTC link to SRU SRU – EB, TTC, LV1, DCS, SLINK USA15 CSC TTC, DATA, DTC fibres Run Control Application (on RC PC) ROS DCS(ACR Muon Desk, CSC infrastructure) 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) APV25 ROS USA 15 UX 15 SLINK SRU FEC (ADC/Eth ernet) FEC (ADC/Eth ernet) RC PC Local Switch (Cu  Optical) Switch (Cu  Optical) Ctrl TTC CSC ROD 9

+ Configuration Not in ATLAS partition There is no way of getting LV2/EF information to our ROS (event selection) MM partition fully described in TDAQ OKS database Reading out 10% of LV1 triggers (slow APV data transfer) Pre-selection on SRU possible Send only events with APV data Possibly select on FEC event size Store all read out data Switch to SW-only readout We could switch back to TDAQ-compliance mode, if we want into fully integrated mode and serve all LV1 if in ATLAS partition 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) APV25 FEC (ADC/Eth ernet) FEC (ADC/Eth ernet) ROD (1) SRU FEC (ADC/Eth ernet) FEC (ADC/Eth ernet) ROS 10

+ Run Modes Physics ATLAS LV1, 10% Data to SLink-ROS-RC PC-HDD Offline synchronisation of LV1 Throttled data transfer to storage (Castor) All APV / SW-only runs Calibration Off-run Internal / CSC triggers On FEC measurement of ZS pedestals RC PC storage of pedestals (read from FEC) APV calibration (rare) Internal triggers ZS in bypass mode SRU in bypass mode to Ethernet port Display / Verify raw APV frames 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) FEC SRU RO S RC Local ETH ATL CTRL net Castor EOS CSC TTC Slow control SLINK ctrl Eth Throttled 11

+ Run Modes Physics ATLAS LV1, 10% Data to SLink-ROS-RC PC-HDD Offline synchronisation of LV1 Throttled data transfer to storage (Castor) All APV / SW-only runs Calibration Off-run Internal / CSC triggers On FEC measurement of ZS pedestals RC PC storage of pedestals (read from FEC) APV calibration (rare) Internal triggers ZS in bypass mode SRU in bypass mode to Ethernet port Display / Verify raw APV frames 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) FEC SRU RO S RC Local ETH ATL CTRL net ATL CTRL net Castor EOS Castor EOS CSC TTC CSC TTC Slow control SLINK ctrl Eth Throttled 12

+ Run Modes Physics ATLAS LV1, 10% Data to SLink-ROS-RC PC-HDD Offline synchronisation of LV1 Throttled data transfer to storage (Castor) All APV / SW-only runs Calibration Off-run Internal / CSC triggers On FEC measurement of ZS pedestals RC PC storage of pedestals (read from FEC) APV calibration (rare runs) Internal triggers FEC ZS in bypass mode (RAW data of one APV) SRU in bypass mode (to Ethernet port) Display / Verify raw APV frames 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) FEC SRU RO S RC Local ETH ATL CTRL net ATL CTRL net Castor EOS Castor EOS CSC TTC CSC TTC Slow control SLINK ctrl Eth Throttled 13

+ Offline synchronisation Before data analysis Save all RAW events ATLAS synchronisation at our convenience Max of 16TB of data (SW+MBTS) for 10 weeks of 10h ATLAS runs daily (SW+ MBT0) We will get that space Throttled speed of output to storage will limit data taking Dedicated SW-only runs This data will by compared to ATLAS data 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) RC ATL CTRL net ATL CTRL net Castor EOS Castor EOS Throttled 14

+ Current status ATLAS compliant ROD based on SRS But run in a different mode Readout synchronised with ATLAS triggers There is no way of getting LV2/EF information from TDAQ 1 FEC (MBT0 + SW chambers) Power supply To be switched to SW only RC-PC with storage space is being prepared Time to debug 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) 15

+ Next steps: to data analysis Run planning to be made (9 weeks) MBT0/SW runs dedicated SW runs (re-cabling 4 th chamber) DAQ commissioning Verify APV settings (raw data) Verify FEC ZS pedestals Stability (not to disturb the Muon shifter’s sleep) Write data decoder (ATLAS -> ROOT for EventBrowser) Data preparation / Offline Synchronisation Select based on Timestamp + LV1ID (ATLAS and MM) Select events with CSC tracks ATHENA jobs mmDAQ root files feed to RECOmm Data analysis (Write Manual / Documentation) 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) 16

+ Next steps: to data analysis Run planning to be made (9 weeks) MBT0/SW runs dedicated SW runs (re-cabling 4 th chamber) DAQ commissioning Verify APV settings (raw data) Verify FEC ZS pedestals Stability (not to disturb the Muon shifter’s sleep) Write data decoder (ATLAS -> ROOT for EventBrowser) Data preparation / Offline Synchronisation Select based on Timestamp + LV1ID (ATLAS and MM) Select events with CSC tracks ATHENA jobs mmDAQ root files feed to RECOmm Data analysis (Write Manual / Documentation) 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) 17 Thank you

+ Backup slides 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) 18

Micromegas principle  Parallel-plate chamber Conversion & drift region (typically a few mm) with moderate electric field of 100–1000 V/cm Amplification in a narrow (128 µm) gap with high electrical field (40–50 kV/cm)  With drift velocities of 5 cm/µs (or 20 ns/mm) electrons need 100 ns drift time to reach the mesh (for a 5 mm gap)  By measuring the arrival time of the signals a MM functions like a TPC => Track vectors for inclined tracks 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) 128 µm 5 mm 19

+ SRU Virtex 6, TTCrx chip, 4 SFP ports 40 DTC links EB, and TTC LVL1 Accept treatment Process first, buffer others TTC SRU uses onboard TTCrx chip to receive BC clock, L1A, ECR, BCR and trigger type Connect to CSC TTC partition with unique TTC address Additional user-programmable offset value for BCID S-LINK HOLA emulator on Virtex 6 board 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) 20

+ Configuration (1): TDAQ 1) Fully integrated solution required much more work (MM and TDAQ) without clear advantage for data analysis. 2) Parasitic mode LVL1A from CSC TTC crate Sub-detector ID : RPC 0x65 (side A), data channel 0xFF (non- existent, ignored by decoder) Separate MM partition for ROS local storage Offline synchronization with ATLAS data 3) Parasitic with RCD in ATLAS partition Send UDP packages to our ROD (e.g., to set RunNumber) (Always returns with success) 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) ROS RC PC Local ATL RC 21

+ 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) 22

+ 2/10/2012 RD51 Stony BrookM. Byszewski (CERN) 23