1. Huazhong Normal University (CCNU) Dong Wang

2.  Introduction to the Scalable Readout System  MRPC Readout Specification  Application of the SRS to CMB-MRPC  Summary

3. Scalable Readout System from: https://espace.cern.ch/rd51-wg5/default.aspx ---Introduction to the Scalable Readout System

4.  Links instead of buses: more reliable, longer distance, more bandwidth  Scalable: small system= few links 1SRU, large system= N links  Merge 3 streams :single DTC link (Data, Trigger, Control )copper or fiber  Chip frontend exchangeable: keep the common readout system  Cheap & standard: frontend card chassis (Eurocard format), cables(CAT6 cable), fibers(850 nm MM fiber), network(10 Gigabit Ethernet)  DAQ system: robust, user-friendly and supported: Alice / DATE  Radiation protected on FEC and SRU FPGA chips from: https://espace.cern.ch/rd51-wg5/default.aspx ---Introduction to the Scalable Readout System

5. from: https://espace.cern.ch/rd51-wg5/default.aspx ---Introduction to the Scalable Readout System

6.  Overall time resolution σT = 80 ps.  Occupancy < 5 % for Au-Au central collisions at E=25 GeV/A.  Space resolution ≤ 5 mm x 5 mm.  Efficiency > 95 %.  Pile-up < 5%.  Rate capability > 20 kHz/cm2.  Multi-hit capability (low cross-talk).  Compact and low consuming electronics (~65.000 electronic channels). The TOF wall of the CBM experiment at FAIR 15-03-2007 D. Gonzalez-Diaz (GSI-Darmstadt) ---MRPC Readout Specification

7.  One SRU can handle 2304 channels 1 SRU = 36 FEE = 36*8 TDC = 36 * 8*8 channel = 2304 channel  ~65000 CBM/TOF channels = ~30 SRU needed  One SRU-DROC link can support 6Gb/s data rate maximum  One FEC-SRU link can support 200Mb/s data rate via cat6 connection ---MRPC Readout Specification

8. from: https://espace.cern.ch/rd51-wg5/default.aspx Architecture of the readout Chain

9. VIRTEX5 LXT 32 x RJ45... 128 x SN65LVDS100 DCS mezzanine 54 LVTTL bus signals ( 32 data 16 addr. 3 cntr. 1 Rst ) 8 TTC signals (4 Broadcast, 2 strobes, 2x clock ) 5 other (2 x ADC, 1 ext. Inp, 2 RxTx ) 128 x differential LVDS (256 I/O) Con13 CON14 TTCr x 67 I/O signals 4 I/O signals NIM input 2x LVDS coax 4x bidir 4 diff LVDS ( 8 I/O) 88E 1111 RJ4 5M 4 x SN65LVDS100 70 pin connectors70 pin connector RJ4 5 DCS ethernet cable Ethernet-DCS Gigabit Ethernet Optical SFP 1000 BASE- T ( 1 GB copper) 10 GBASE-S (10 GB* optical) 32 x Serial quad LVDS links (CAT6) RJ4 5 40 MHz 25 MHz ICS844021 I-01 35 I/O signals 125 MHz 2 Rocket I/O clock s TPS74401 MIC29301 +1V +3.3V +2.5V - 5V +3.3V, +4.2V, -12V LDO area Power XCF32P- VOG48 FLASH JTAG Molex 87831-1420 Clock outputs AD7417 T+V monitoring LT1175... TTC fiber (LHC) PHYSICAL 9 ---Application of the SRS to CMB-MRPC from: https://espace.cern.ch/rd51-wg5/default.aspx

10.  First version of SRU board layout finalized.  First success with porting of DATE software to Gigabit Ethernet. ---Application of the SRS to CMB-MRPC from: https://espace.cern.ch/rd51-wg5/default.aspx

12. ---Application of the SRS to CMB-MRPC

13. A cards : custom chip adapter, ADC’s etc B cards: options, Extensions (LEDs, HV bias etc.) C-cards: larger, more complex extensions A, B card: ~100x89 mm 2 C-card: ~ 128x233 mm 2 C-cards A,B-cards Note: A,B and C cards can be mixed in single Eurocrate ---Application of the SRS to CMB-MRPC

14. A-card 4 HPTDC chips FEC card To be defined: Connectors on A card to FEA Power for FEA card might also use larger C-card ---Application of the SRS to CMB-MRPC The analog electronic Part can be designed based on GSI/CBM group collaborate, ALICE/TOF NINO/HPTDC tecnology, or collaborate with other groups.

15.  CCNU is RD51 member  Adapter card design and firmware of FEC will be designed by CCNU  FEC card and DATE Readout will supported by RD51  Connectivity to FEA to be studied  Existing ALICE readout system: DATE being ported to GBE  First version of SRU has finished design at CERN  Upgrade version of SRU is under development at CCNU