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Status of SVT front-end electronics M. Citterio on behalf of INFN and University of Milan XVII SuperB Workshop and Kick Off Meeting: ETD3 Parallel Session.

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Presentation on theme: "Status of SVT front-end electronics M. Citterio on behalf of INFN and University of Milan XVII SuperB Workshop and Kick Off Meeting: ETD3 Parallel Session."— Presentation transcript:

1 Status of SVT front-end electronics M. Citterio on behalf of INFN and University of Milan XVII SuperB Workshop and Kick Off Meeting: ETD3 Parallel Session

2 Index La Biodola 2011Mauro Citterio 2 SVT: system status Parameter space Latest hit rates Readout chip for strips Buffers and Clusters Efficiencies vs rate and dead times DAQ reading chain for L0-L5 Conclusion

3 SVT Baseline for TDR - Striplets in Layer0 @ R~1.5 cm  Triggered FE chips - 5 layers of silicon strip modules  Triggered or data push FE chips (extended coverage w.r.t BaBar) Upgrade Layer0 to thin pixel for full luminosity run - more robust against background occupancy 40 cm 30 cm 20 cm Layer0 old beam pipe new beam pipe Several progress on the baseline design in the last few months:  Definition of the requirements for readout chips for striplets and strip:  Need to develop 2 new chips since existent chips do not match all the requirements : analog info, very high rates in inner Layers (0-3) & short shaping time, long shaping in Layers 4-5 to reduce noise for long modules.  Started to evaluate if readout architecture developed for pixel can be used for strips: no evident showstop up to now  First estimate of noise vs shaping time in each layer done: optimization still needed. SVT System (1 of 2) La Biodola 2011Mauro Citterio 3

4 La Biodola 2011Mauro Citterio  Detailed study of striplets performance in high background (occupancy >= 10%) just started with Fastsim.  Updated background simulation: Rates in strip layers 1-5 increased by a factor 3 after a bug was discovered, more checks ongoing. Layer0 was not affected.  Clearer definition of requirements for Layer0 pixels  Several options still open and under development  decision on technology in 2013  Hybrid pixels: more mature and rad hard but with higher material budget  CMOS MAPS: newer technology potentially very thin, readout speed and rad hardness challenging for application in Layer0. SVT System (2 of 2) Physics:  Resolution of 10-15 um in both coordinates  Total material budget <= 1% X0  Radius ~1.3-1.5 cm Background (x5 safety included)  Rate ~100-300 MHz/cm2 depends stronlgy on radius and sensor thickness  Timestamp of 1 us  5-10 Gbit/s per module  TID ~ 15Mrad/yr  Equivalent neutron fluence: 2.5 10 13 n/cm2/yr  Standard CMOS MAPS marginal 4

5 Parameter Space La Biodola 2011Mauro Citterio 5 Gangling/Occupancy/Simulations Several unknowns: exact background rate; hit multiplicities Trigger frequency: 150 kHz (1.5 S.F) jitter: 100 ns (the goal is to go down to 30 ns) latency: 10 us (1.7 SF; LVL1 design is 6 us) DAQ window: 100ns + 2 Time stamps or 300 ns Time stamping: 33 MHz (T(BCO)=30 ns) Chip readout clock: 66 MHz (T(RDclk)=15 ns) Mauro Villa

6 Hit rates from the last simulations La Biodola 2011Mauro Citterio 6 Assumptions: Strip dead time equal to 2.4 peaking time Strip rates as given by Riccardo Cenci (13/5/11): New Values(Old values) L0: 2060 kHz/strip L1: 687 kHz/strip(268 kHz/strip) L2: 422 kHz/strip(179 kHz/strip) L3: 325 kHz/strip(52.5 kHz/strip (?) ) L4: 47 kHz/strip(21.9 kHz/strip) L5: 28 kHz/strip(18.7 kHz/strip)

7 Efficiency vs peaking time La Biodola 2011Mauro Citterio 7 L0 L1 L2 L3 L4 L5 L0 L1 L2 L3 L4 L5 No safety factorSafety factor of 5 97.6% eff  Tp(L1)=74 ns97.6% eff  Tp(L1)=15 ns Mauro Villa

8 Readout chip for strips La Biodola 2011Mauro Citterio 8 FE Ctrl logic Buf #k... Buf #1 ADC Or ToT BUF #1 readout/slow control strip #127 strip #0 FE Ctrl logic Buf #k... Buf #1 ADC Or ToT Sparsifier ~hit_rate * trig_latency How many buffers? How many barrels? Triggered hits only Asynchronous logic assumed

9 9 L1 simulation: 687 kHz/strip Hit Efficiency till trigger Analog efficiency and limited buffer lenghts Buffer Size Single strip simulation Peaking time=50 ns  eff=92 % Peaking time=100 ns  eff=84% Mauro Villa

10 10 L4: 47 kHz/strip but longer deadtimes Hit Efficiency after trigger Buffer Size Tp=600 ns, eff=93.3% Tp=1000 ns, eff=89.2% Tp=800 ns, eff=91.3% For outer layers (smaller hit rate) the buffer size is not a problem: 5 buffers/strip are enough. The dominant parameter is the analog dead time. Mauro Villa

11 11 Efficiencies vs rate and dead times LayerC D [pF]t p [ns]ENC from R S [e rms] ENC [e rms] Hit rate/strip [kHz] MMC Efficiency 011.2252206802060(0.732) 126.7 506501190 687 0.917 100460930 0.841 231.2508301400422 0.948 345.85014802130325 0.960 452.6100034082047 0.893 567.51000500101028 0.934 Conditions: 20 buffers, 150 kHz trigger rate, 300 ns time window for all layers.

12 12 DAQ reading chain for L0-L5 High rad area 15Mrad/year Off detector low rad area ROM Optical Link 2.5 Gbit/s Counting room Std electronics FEB HDI +Transition card+FEB+ROM DAQ chain independent on the chosen FE options Optical 1 Gbit/s ~100 cm LV1 HDI and transition card design is ongoing Data Encoder IC.... Specs are under discussion Rad-hard serializer to be finalized  looking into a low power/low speed version Copper tail: lenght vs data transfer are under study FEB + ROM as before fibers

13 Low Speed / Low Power Serializer La Biodola 2011Mauro Citterio LOCs1 (mW)low power design CML Driver 9650% PLL17380% Others18730% The block schematic of the SMU LOC1 shows that the typical power of the chip (~ 500 mW at 5 Gbps) has a substantial contribution coming from the PLL circuit. A “Tunable” Serializer (data rate from 2.5 to 5 Gbps) can be obtained by changing the PLL. The goal is to reduce the power to ~ 250 mW at 2. 5 Gbps Simulation results indicate that (courtesy of SMU) : The final design/prototyping phase of this Low Speed /Low Power IC did not start, yet. SMU has received expression of interest by other experiment for such a development SMU is looking into opening a collaboration on such IC (technology is 0.25 um Silicon on Sapphire)

14 Data/Clock and Control Cables (1 of 2) La Biodola 2011Mauro Citterio 14 Kapton tail is probably not a solution for SuperB - data speed is much higher than before - differential/coaxial lines are not usually designed in flat circuits Some small and flexible cables have been selected and tests are on-going Some preliminary results are shown - the reference lenght has been chosen ~ 1m (not to push on driving capability of devices) - the test has been performed using - Xilinx FPGA + Rocket IO as a reference - Xilinx FPGA + LOC1 serializer as a comparison

15 Data/Clock and Control Cables (2 of 2) La Biodola 2011Mauro Citterio 15 Signal: 30 AWG, Solid Copper Clad Aluminum Differential Impedance ~ 100 Ohms +/- 5% Capacitance: 16 pF / ft Propagation Delay: < 2 ns/ft The preliminary measurements show that LOC1 can drive such a cable without substantial degradation even without pre/post emphasis Eye diagram BER probability density function

16 SuperB-FEB Board schematics DAQ link 2.5 Gbit/s L1/Spare DAQ link 4x1 Gbit/s FE links Small FPGA Memory Large FPGA Gb ethernet VME FPGA Or uCPU VME? FCTS interface ECS interface FCTS, ECS protocols to be decided experiment-wide Large FPGA for data shipping and monitoring VME FPGA or uCPU might be included in the large FPGA.

17 Optical link mezzanine card for EDRO Developed as a part of ATLAS/FTK project 4 optical links at 1 Gbit/s; FPGA Xilinx, 40/100 MHz clk (programmable) PCB realized; now mounting components on first prototype Usable as link test mezzanine in SuperB (fall 2011)

18 Data Chain …. locations La Biodola 2011Mauro Citterio 18 HDILocated near the detector Transition cardsLocated approximately ~ 1 m from the HDI in a “not too hostile” environment.  We will try to maximize such a distance  Receivers and electrical to optical transition will be located on this card. It is an advantage to go further away form the detector. DAQLocated after the so called "radiation wall“.... For L1-L5 layers are needed ~ 120 optical links, equivalent to ~ 20 boards (each board will have up to 12 optical links) L0 layer..... Still to be addressed

19 19 Conclusions First core of a Mini Monte Carlo for the Strip readout chip is available, containing Hit and trigger generation Analog inefficiency, buffers and barrels Several improvements can be foreseen: input hit multiplicities and correlations, etc Good indications that for L1 the pixel readout architecture can be reused fruifully Two parameters were found to be (very) critical: T(BCO) vs T(RD) Analog dead time Analysis on other layers foreseen Mauro Villa Data chain is progressing by defining all the elements of the chain....

20 La Biodola 2011Mauro Citterio

21 21 Strip chip: how many barrels ? 32 strips/barrel 4 barrels/chip 128 strips/barrel 1 barrel/chip Hit Efficiency after trigger Buffer Size Peaking time=50 ns One or few barrels seem enough! T(BCO)>2T(RD) Mandatory! when T(BCO)=T(RD) Efficiencies at zero 150 kHz trig rate 300 ns DAQ time window Mauro Villa

22 22 Number of buffers required for L0 striplets/L1 strip (preliminary) Assume L0 @ 225 MHz/cm2, L1@5 MHz/cm2 L0 = 2 MHz/strip, L1=270 KHz/strip F. Morsani/G. Rizzo Just calculations; Mini-MC simulation needed

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