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GOSSIPO-3: Measurements on the Prototype of a Read- Out Pixel Chip for Micro- Pattern Gas Detectors André Kruth 1, Christoph Brezina 1, Sinan Celik 2, Vladimir Gromov 2, Ruud Kluit 2, Francesco Zappon 2, Klaus Desch 1, Harry van der Graaf 2 1 Physics Department, University of Bonn, Nussallee 12, 53115 Bonn, Germany 2 National Institute for Subatomic Physics (Nikhef), Science Park 105, 1098 XG Amsterdam, The Netherlands TWEPP, Aachen September 20 th -24 th 2010
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 2/21 Outline Read-Out of Micro-Pattern Gas Detectors GOSSIPO-3: Features & Architecture Measurement Results and Discussion –Front-End –LDO –TDC Summary & Outlook
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 3/21 Read-Out of Micro-Pattern Gas Detectors - Particle track image (projection) - 3D track reconstruction - No sensor leakage current compensation - Low parasitic capacitance (less than 10fF) - Micro-discharges in avalanche gap Cluster3 Cathode (Drift) Plane Gas Amplification Structure Cluster2 Cluster1 Read-Out Chip 1mm …1m → Drift Gap 400V 50 m Avalanche Gap Gas-avalanche detector combining a gas layer as signal generator with a CMOS readout pixel array Front-End Circuit C PAR
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 4/21 GOSSIPO-3 Features Prototype for a read-out chip in TPCs IBM 130nm CMOS (8 metal layers) 60 m x 60 m pixels (high granularity) Time Measurement mode and Hit Counting mode Local TDC in every pixel Design Goals: –3 W per channel –Arrival time measurement up to 102 s –Arrival time accuracy 1.56ns (one fast VCO bin) –ToT accuracy 200e - accuracy (27ns)
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 5/21 Pixel Electronics Layout of the pixel LFSR = Counters (data taking) or LFSR = Shift registers (data read-out) Control signals - Clock - TRIGGER (common stop) - TOKEN - RESET Preamp Discr. control Local fast oscillator (640MHz) Local fast oscillator (640MHz) 4 bit Fast counter 8 bit ToT counter 12 bit Slow counter 6 bit Pixel configuration Memory Threshold DAC pad -Threshold - Mask Time / Counting HIT Block diagram of the pixel oscillator Logic: counters & control Preamp & comparator DAC
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 6/21 GOSSIPO-3 Architecture 2 LDOs (generate controllable Power Supply Voltage for Ring Oscillators) Pixel (pre-amplifier, comp, Threshold DAC, high resolution TDC, counters & control logic) 3 Front-Ends ( preamp, comp) Ingrid preampBias generating circuit
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 7/21 Demonstrator Test Set-Up G3 Test Board (dedicated PCB) S3 Multi IO Board (general purpose test board designed by Bonn group) USB Port FPGA External Bias Overwrite -=G3=- Demonstrator Power Regulators CC SRAM
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 8/21 Front-End Performance Pre-Amplifier with MOS feedback parasitic capacitance C FB about 1fF – high gain Low parasitic input capacitance
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 9/21 Measurement (averaged) V=64mV Measurement V PK-PK <20mV Front-End Performance Excellent pre-amplifier noise performance –Charge injection through test pad –Measurement includes output pad driver –ENC ca. 25e - – NOISE ca. 4mV Simulation Q IN =375e -
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 10/21 Front-End Performance Pre-amplifer measurement for different channels Metal-Metal Injection Capacitance C TEST Stable high gain Varying time constant of feedback discharge Channel#1 Channel#2 Channel#3 U IN ●C TEST1 /C FB1 U IN ●C TEST2 /C FB2 C TEST and C FB are good reproducible U IN ●C TEST3 /C FB3
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 11/21 Front-End Performance ToT measurement for different channels Q IN =375e - ToT channel to channel mismatch up to 50% Jitter on TOT rising edge caused by noise on pre- amplifier signal falling edge Cross-talk between channels observed when pad driver switches Channel#1 Channel#2 Channel#3 ToT1 ToT2 ToT3
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 12/21 Analysis of time variation of the discharge Process variation of small feedback MOS responsible for variation of feedback current Small feedback MOS needed for high gain Front-End Performance Replace picture simulations slope ~ 0.2ns/e - measuremen t
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 13/21 Front-End Performance Internal delay 9ns assumptotical delay for a charge >6000e - (injection to comperator) Stabilisation needed Replace picture
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 14/21 LDO controls supply voltage of fast TDC ring- oscillator (arrival time measurement) Oscillation frequency of f=640MHz in all process corners –Time bin size T=1.56ns –Maximum run time 25ns (16 bins) –V OUT_LDO =0.61V (fast)..1.10V (slow) –Occupancy expectation gives avg. I OUT_LDO =24mA peak I OUT_LDO =44mA –VCO control characteristic allows for V LDO_OUT =31mV for 25ns LDO Performance
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 15/21 LDO Performance Step response to typical load step 20mA –additional external load –inductance of package and bond wires limit response time
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 16/21 LDO Performance Settling time to nominal V OUT value for different (external) load steps
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 17/21 TDC Performance Counting steps of TDC (input signal directly at digital logic) Replace picture?
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 18/21 Pixel Performance What do we have here?
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 19/21 Summary Front-End: –Rise time / internal delay needs to be stabilized –Source of pixel to pixel TOT mismatch identified –High gain / low noise LDOs: –Step response time critical for TDC performance –Close match between simulation and measurement TDC: –???
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 20/21 Outlook Larger pixel array needed for InGrid test The Gossipo-3 design team joins Timepix II design efforts
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 21/21 Thanks for your attention!
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 22/21 Backup Slides
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 23/21 Pre-Amplifier Schematic
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 24/21 Pre-Amplifier Schematic
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 25/21 LDO Performance Static R OUT measurement
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 26/21 LDO Performance Linearity measurement
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A. Kruth, GOSSIPO-3, TWEPP, Aachen, Sept. 20 th -24 th 2010 27/21 LDO Performance Step response to maximum load step 40mA –additional external load –inductance of package and bond wires limit response time
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