Towards a CBM-XYTER Readout Chain

1. Towards a CBM-XYTER Readout Chain Walter F.J. Müller, GSI, Darmstadt 11th CBM Collaboration Meeting26 February 2008

2. CBM-XYTER Data • A CBM-XYTER hit can be represented in 6 bytes (48 bit) • The 'hit message' might look like (here 42 bits) • message type (1 bit) • chip id (~ 8 bit) • channel id (7 bit) • status flags (~4 bit) • time stamp (~14 bits) • amplitude (~8 bits) • On a serial link we have some overheads • Framing, FEC, ect: ~75% efficiency • 8bit/10bit coding • 'on-the-wire' we need about 80 bit to encode a hit 2.5 Gbps ↔ 31.25 MHz hit rate 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI

3. Some Values • Use hit densities form CBM Technical Status Report2006 Update, Section 13.1 "Hit densities and Rates" • Detector edge hit/cm2 part/cm2 TIDSTS @ 30cm inner 10 7.5·1014 20 Mrad outer 0.25 1.8·1013 0.5 MradSTS @ 1m inner 1 7.5·1013 2 Mrad outer 0.03 2.3·1012 60 kradTRD @ 4m inner 0.04 3.0·1012 80 krad outer 0.002 1.5·1011 4 kradTOF @ 10m inner 0.01 7.5·1011 20 krad outer 0.0006 5.0·1010 1.2 krad • STS @ 30 cm is now 1st plane in 'all strips' configuration(the hit rate for STS@30 cm is scaled from the STS3 @ 20 cm plot of the CBM TSR) • Hit rates in 1st MUCH plane are similar to STS plane @ 1m 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI

4. STS Data Rates – Rough Estimate • With 60 μm pitch: 128 channel ↔ 0.768 cm • The hottest place: • 10 hit(cent)/cm2↔ 2.5 hit(mbias)/cm2↔ 25·106 hit/(s·cm2) • A 2cm sensor ↔ 1.5 cm2 ↔ 37.5 MHz hit rate/chip • Note: background and cluster size not included here • A typical data link to DAQ: • Assume 2.5 Gbps link speed from here on • Number of data links needed: • A single CBM-XYTER can fill a 2.5 Gbps link • most of the CBM-XYTER see less hits • in most cases 2, 4, or 8 CBM-XYTER's can be aggregated to fill a 2.5 Gbps link 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI

5. STS Data Rates – MC Results • Radek made a detailed study. The current 8 station STS with a total of • ~1.2 Mchannels, • 9296 CBM-XYTER chips • 586 modules (with mostly 2 * 8 chips) • Note: • cluster size not yet included ( 1 strip hit per particle)(ALICE SSD has an average cluster size of ~1.4) • effects due to non-perpendicular incidence also still ignored • Following tables under the caveats listed above 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI

6. STS Data Rates – Au+Au @ 25AGeV • Chip count only for one of the two sides of the modules • Properties of stations quite similar (module size tracks quite well the inverse hit density  hit/chip roughly equal) Hit rate per chip 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI

7. STS Data Rates – Aggregation • 75% of the chips have < 4 MHz • It is prudent to aggregate the data of several chips onto one data link before it is send of the module • Only 2.5% of chips have a hit rate of 16-32 MHz • 842 of 1172 of the module sides (71%) have a sum hit rate of <32 MHz, can thus be aggregated on a 2.5 Gbps link • in 188 module side two groups of 8 chips can be aggregated on a link Hit rate per module 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI

8. STS Data Rates – # of Data Links • 75% of the chips have < 4 MHz • It is prudent to aggregate the data of several chips onto one data link before it is send of the module Hit rate per module • Total hit rate: 32.6 GHz • Net data rate: ~200 GByte/s • Number links: 1850 • Per station end (top/bot) we have about 120 data links - Aggregation may be cleverer, links a little faster- Cluster size will be >1 and increase data volume About 2000 'fast' links seems a reasonable estimate 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI

9. CBM-XYTER@STS Readout • In many cases information of all 8 chips can be aggregated to fill one 2.5 Gbps link • Some schemes: • embedded (aggregation integrated in CBM-XYTER) • with communication controller (aggregation on separate chip) 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI

10. GBT: The CERN proposal for SLHC • The GBT project at CERN addresses these issues • targeted for SLHC • radhard design • communication-controller handling • clock distribution • trigger distribution • slow control traffic • data readout traffic • exactly what we talk about since years • In the following a few slides from Paulo Moreira's presentation on the TWEPP-07 workshop. 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI

11. The GBT, a Proposed Architecture for Multi-Gb/s Data Transmission in High Energy Physics P. MoreiraCERN – Geneva, Switzerland Topic Workshop on Electronics for Particle PhysicsSeptember 3 - 7, 2007, Prague, Czech Republic http://indico.cern.ch/contributionDisplay.py?contribId=71&sessionId=16&confId=11994

12. Outline • Motivation • The proposed link architecture • Link topology • GBT chipset • Link bandwidth • GBT to Front-end link topology • TTC • Slow control • Development and testing • Error correction and line coding • Summary Disclaimer: “This project is still in its specification phase, detailed features are likely to change prior to the final silicon fabrication…” The objective of this presentation is to communicate the current ideas to stimulate discussion and to obtain feedback from the potential users! 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI Slide from: TWEPP-07 presentation of Paulo Moreira (see this link)

13. GBT link architecture Versatile optical link project GBT project GBT project • Bidirectional point-to-point optical fiber links • The heart of the link is the GigaBit Transceiver (GBT13) • Each link carries simultaneously: DAQ, TTC and SC data • Embedded transceiver: the GBT Chipset • Counting room transceivers: FPGA and COTS optoelectronics components 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI Slide from: TWEPP-07 presentation of Paulo Moreira (see this link)

14. The GBT chipset • GigaBit Transimpedance Amplifier (GBTIA) • GigaBit Laser Driver (GBLD) • GigaBit Transceiver (GBT13) • SERDES • Communications controller • TTC receiver • GBT – Slow Control ASIC 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI Slide from: TWEPP-07 presentation of Paulo Moreira (see this link)

15. GBT to front-end link topology • GBT to Front-end links: • 32 (+1) bi-directional serial links (e-links) • E-link bandwidth is 80 Mb/s • Several e-links can be grouped together to serve a single front-end device achieving bandwidths that are multiples of 80 Mb/s • 16-bits for TTC • 8 phase adjustable clocks • An E-Link Port Adaptor (EPA) “macro” will be available for integration in the front-end ASICs 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI Slide from: TWEPP-07 presentation of Paulo Moreira (see this link)

16. SC – Two chips solution 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI Slide from: TWEPP-07 presentation of Paulo Moreira (see this link)

17. Link bandwidth • GBT: 120-bits transmitted during a single bunch crossing interval  4.8 Gb/s. • 4 header bits • 32 forward error correction bits • User field of 84 bits  3.36 Gb/s: • SC: 4-bits  160 Mb/s • TTC: 16-bits  640 Mb/s • DAQ: 64-bits  2.56 Gb/s • Bandwidth is fixed per frame but can be shared by the front-end devices 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI Slide from: TWEPP-07 presentation of Paulo Moreira (see this link)

18. Forward error correction (FEC) • Objectives: • Correct burst errors: • Generated on the PIN-diode • Generated by particles hitting the transceiver • Generated in the fast SERDES circuits (which cannot be triplicate) • Done with minimal latency • Done with good efficiency • Merge with line-coding • Proposed code: • Compatible with FPGAs capabilities • Interleaved Reed-Solomon double error correction • 4-bit symbols (RS(15,11)) • Interleaving: 2 • Error correction capability: • 2 Interleaving × 2 RS = 4 symbols  16-bits • Code efficiency: 88/120 = 73% • Line speed: 4.80 Gb/s • Coding/decoding latency: one 25 ns cycle 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI Slide from: TWEPP-07 presentation of Paulo Moreira (see this link)

19. Summary • We propose a “Single” Link solution for: • Timing Trigger Links • Data Acquisition Links • Experiment Slow Control Links • The link is based on: • The GBT chip set in the detectors: • GBT13, GBTIA, GBLB & GBT-SCA • Optoelectronics from the Versatile Link Project • An FPGA in the counting room • Both ends implement a error robust transmission protocol over an optical fibre • The GBT13 communicates with the front-end electronics with up 32(+1) e-links • Two or more e-links can be grouped to match the front-end bandwidth • We propose that the e-links communicate using the Ethernet protocol • An E-link Port Adaptor “macro” will be provided by the GBT team for integration in the front-end ASICS • Slow control is implemented by a dedicated channel • One e-link • Slow control is managed by the GBT-SCA 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI Slide from: TWEPP-07 presentation of Paulo Moreira (see this link)

20. Today's Summary • GBT seems to be a very interesting architecture • Some aspects are quite SLHC specific (the 80 Mhz world) • Some parameters might not be well adapted to our needs • why is the E-link bandwidth only 80 Mbit/sec ? • all the TTC specifics • Goal is to start a discussion on the CBM-XYTER readout architecture • many CBM-XYTERS will sit in places with a TID > 1 Mrad • the path to the first place with TID < 1 krad, where COTS components can be placed (e.g. FPGA), is at least 5 m. • Is Cu+LVDS still feasible, given total needed bandwidth ? • Or is it better to go locally (that means radhard) to optical ? 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI

21. The End Thanks for your attention 11th CBM Collaboration Meeting -- Walter F.J. Müller, GSI