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Overview of TPC Front-end electronics I.Konorov Outline:  TPC prototype development  Readout scheme of the final TPC detector and further developments.

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Presentation on theme: "Overview of TPC Front-end electronics I.Konorov Outline:  TPC prototype development  Readout scheme of the final TPC detector and further developments."— Presentation transcript:

1 Overview of TPC Front-end electronics I.Konorov Outline:  TPC prototype development  Readout scheme of the final TPC detector and further developments  Conclusions

2 April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

3 Signal detection and Time/Amplitude measurements April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov Threshold RO architecture: Signal sampling –Amplitude : Maximum –Time extraction Amplitude Ratio Digital CFD PreAmpShaperAnalog Sampling MUX 1 76 75

4 TPC prototype April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov Geometry : 10.5 cm inner diameter 30 cm outer diameter 73 cm drift distance ReadOut : 10756 channels 511 samples More than 5 10^6 space points

5 AFTER ASIC 90 ns peaking time Analogue Sampling(SCA),10-20MHz 511 Samples/Channel No Zero Suppression 72(64) channels/chip Very slow sequential readout –1-2 ms/event 600 eˉ ENC with detector Objectives: TPC characterization Optimization feature extraction algorithms FOPI real data taking April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov PreAmpShaperAnalog Sampling MUX 1 76 75

6 Readout chain April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov 42 AFTER FE cards 11 ADC 2 HGESiCA PCI card in PC (event building)

7 April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

8 April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

9 RO status Complete detector equipped with RO electronics Noise performance is about 600e- Stable data taking during last test beam @FOPI 300-400 Hz trigger rate(2.5 ms dead time) Maximum 2.5% occupancy (0.5 MB/ev) Everything is ready for FOPI run in June April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

10 Problems with commissioning large detector Power distributions Grounding Optical links Temperature Sensors Revision of detector design at early stage to be foreseen April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

11 Towards final PANDA TPC detector April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

12 GEM TPC requirements About 80K channels with hexagonal pads of 5.8 mm² 500-700 eˉ ENC 4 ns signal time resolution to determine Z coordinate 8 bit amplitude resolution for dE/dX measurements Continuous readout 200 kHz hit rate/pad @2 10  April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

13 Design challenges Low noise in mixed Analog/Digital environment Signal processing – feature extraction High data rate Relatively High channel density Cooling April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

14 Considered ASICs for final TPC 1.XYTER – CBM –CSA => Discriminator TDC => Peak Sensitive ADC 2.S-ALTRO – ILC – CSA=> Sampling ADC => Zero suppression 3.PCA16 + Transient Recorder – PANDA –CSA=> Analogue Sampling => Zero Suppression 4.SPADIC – CBM TRD –CSA=> Sampling ADC => Zero suppression April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

15 Transient Recorder ASIC Status First prototype to be submitted in Spring 4 channels No zero suppression Goal of prototype Testing SCA(Switched Capacitor Array) performance April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

16 SPADIC: Self triggered Pulse Amplification and Digitization asIC April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

17 SPADIC ASIC Status of Latest Prototype (SPADIC v0.3) ● 8 complete channels (plus 18 test channels) ● Positive input charges, about 0..40fC input range ● 2nd order shaping, 90 ns shaping time ● Noise: 800e @ 30 pF capacitive input load ● ADC with 7.5 Bit effective (INL) @ 25 Msamples/s ● Power per Channel/ADC: 3.8/4.5 mW ● Size: 1.5 x 3.2 mm2 Status of Latest Setup ● 8 complete setups have been available @ CERN Testbeam Nov. 2010 ● New PCB with low noise layout and reduced ground loops has just been designed and is now being fabricated ● Ongoing software development (config. + monitoring tools) First full-blown SPADIC (v1.0) ● Design phase has just been started ● Planned Submission: summer/fall 2011 ● First measurement results end of 2011 at the earliest April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

18 ASICs summary table April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov XYTERS-ALTROPCA16+TRSPADIC # channels12816/6432 ENC(eˉ)?500@5pF 800@30pF Peaking Time(ns) 20, 14030-100 90 Sampling-20 MHz20-100 MHz25 MHz Power24 mW/ch16 mW/ch~10 mW/ch~12 mW/ch Availability20112011/?20142012 Power Cons. 80 kCh. 1.9 kW1.2 kW0.8 kW1.0 kW

19 Next steps Development of FE prototype using PCA16 and commercial ADC or ALTRO chip 100 PCA16 chips purchased – 1600 channels Commercial ADC 40mW/ch @20 MHz, ALTRO Digital logic in FPGA Goal: –Study system integration Powering scheme Noise optimization of mixed Analog/Digital system –Develop Cooling system concept –Solid number for material budget –Detector test with fully functional prototype April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

20 Data rate and data processing 320 FE cards, 80 GB/s Zero suppression 10 Data Concentrators, 50 GB/s Feature extraction TPC SuperBurst Building Network 25 GB/s Clustering Full Suberburst Building Network 200 GB/s Compute Nodes Further data reduction April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov Data Structure Data organized in Super Bursts of 500 μs Last 50 us of data copied to next block to resolve boundary effects SODA Front End Cards Data Concentrator Building Network Compute Node SODA

21 Readout chain and responsibilities Detector group responsibility DAQ group responsibility April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov SODA Front End Cards Data Concentrator Building Network Compute Node SODA

22 TPC Data concentrator April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov Features: uTCA/AMC card Lattice FPGA ECP3 4(2) GB DDRAM Configurations: 2x7x1 Concentrator 8x8 Switch

23 ATC module April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov 32 x 32 switch, 10 GB/s bandwidth

24 Conclusions GEM TPC readout concept, based on AFTER ASIC provided and allow to do full TPC characterization Few ASIC chips being developed and some of them will be available for final detector Developing next FE prototype with data driven readout based on PCA16+Commercial ADC is planned Data concentrator board being developed April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

25 BACKUP SLIDES April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov

26 SUPER ALTRO CERN’s ASIC for ILC TPC –12 bits –20 MSPS –16/64 channels/chip –Expected power consumption 16mW/channel @20MHz –16 channel version was submitted, very limited number of chips –64 channel version no plans yet 16/64 channels/chip, CMOS 0.130 µm April 28-29 2011 Grünberg

27 Transient Recorder April 28-29 2011 Grünberg PANDA FEE-DAQ workshop Igor Konorov 180 nm 32 channels/chip 4.5x4.5 mm²

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