ECAL Off-detector Upgrade at SLHC

1. ECAL Off-detector Upgrade at SLHC J. Varela LIP, Lisbon CMS SLHC Calorimeter Trigger Upgrade, U. Wisconsin,Thursday 29 November 2007

2. Motivations • SLHC high luminosity implies a huge number of p-p collisions (up to 400) • Higher ECAL occupancy results in increased ECAL data volume and data readout bandwidth • Integration of ECAL TPGs in new trigger system is required • Improved integration of ECAL trigger and readout paths should be attempted

3. ECAL occupancy • p-p minimum bias collisions at sqrt(s)=14 TeV: • ~ 5 0 per rapidity unit • <PT> ~500 MeV • SLHC • up to 400 p-p collisions per crossing • crossing rate 20 MHz • Per Trigger Tower (. ~0.1 x 0.1), per crossing : • ~ 12  ( rate in ECAL ~2.4 MHz/cm2) • <PT> ~3 GeV • No empty ECAL towers!

4. Trigger rates L1 e/ trigger: QCD background rates At LHC low luminosity (L=1033cm-2s-1) ~ 1 p-p collision per crossing At SLHC (L=1035cm-2s-1), assuming prob/collision x 400  (cuts are probably less efficient)

5. Electron & photon measurement • Moliere radius ~ crystal size ~ 100% of shower energy is contained in 3x3 crystal window (when no electron radiation or photon conversion) • Average pile-up energy in 3x3 window: ~2 0  <ET> ~ 1 GeV ;  (ET) ~ <ET> ~ 1 GeV • For non-converted photons of ET=50 GeV:  (pile-up) ~ 2%  (ECAL) < 1% • Energy resolution is dominated by pile-up. • Preshower could allow to identify individual pile-up photons • Is the tracker material at SLHC an issue?

6. ECAL data volume • At LHC: • Total event size per DCC (FED): 40 kBytes • After data reduction in DCC: 2 kBytes •  average output bandwidth ~ 200 MB/s, for L1A=100 kHz • Data filtering: • Selective readout + zero suppression • SR: read trigger tower with ET>2-3 GeV + 8 surrounding towers (225 crystals) • At SLHC: • Increase the SR thresholds at the expense of physics or • Increase the data bandwidth • We assume full event readout and L1A max=100 kHz •  bandwidth 4 GBytes/s / DCC

7. L1A Xtal Data TRIGGER D C C C C S T C C … … OFF-DETECTOR ECAL Off-detector electronics ON-DETECTOR Timing, Control & L1A Trigger primitives VME Controller DAQ

8. ECAL Data Concentrator Card VME SRP Link Spy Mem Deserializers/ Input Handler Evt Builder S-Link64 Optical Receivers Merger TCC Channels QPLL/Ref Clk Fanout ECAL Backplane Stiffness bars 40 cm 72 Input Optical Links @ 1 Gbit/s Data collection and merging Data suppression by a factor ~ 20

9. Synchronization Link Board (SLB) Trigger Concentrator Card (TCC68) ECAL TCC & SLBs • 72 Input Optical Links • @ 1 Gbit/s • Trigger Primitives • Links to RCT: • 4x 1.2 Gbits/s per SLB • 9 SLBs

10. Upgrade directions • Re-design DCC  higher data rate : 40 Gbit/s or 8 x 5 Gbits/s output links to DAQ • Re-design TCC  better integration with trigger system (see Jose’s talk) • DCC and TCC: same board, different firmware • Further integration? • Constraints: • Keep FE electronics and link granularity • FE trigger & data use the same physical link Tx: GOL+ NGK VCSEL • Rx: 12 ch NGK receiver (obsolete) • Possibilities: re-built GOH with new radhard optical link and new Rx • or use present Tx with replacement for NGK Rx

11. ECAL Trigger/Readout Board • Input links: • Trigger barrel (per SM): 68 • Trigger endcap (per 20o sector): 88 max • Data barrel (per SM): 68 • Data endcap (per 80o sector): 72 max •  use 8 x 12 ch Rx = 96 input links (detector trunk cable capacity) • Output links: • Data: requires 8 links 5 Gbit/s • Trigger: requires 9 links 5 Gbit/s •  use 12 x 5 Gbit/s output links • Processing: FPGAs

12. Conclusions • ECAL Frontend processing (TPGs and readout) is adequate for SLHC • Upgrade of FE links could be considered (new GOH mezzanine) • Common ECAL Trigger/Readout board (barrel and endcap) seems possible • Around 120 boards would be needed (presently ~160 boards) • Each board communicates with DAQ and Trigger via 12 “CMS standard” 5 Gbit/s links