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ALPIDE status and future plans CERN, INFN, NIKHEF, CCNU (China) and YONSEI (Korea)

ALPIDE status and future plans CERN, INFN, NIKHEF, CCNU (China) and YONSEI (Korea) . Specifications & motivation. UPPER LIMIT lower much better !. Nr of bits to code a hit : 35 Fake hit : 10 -5 / event. Lowering integration time would significantly reduce background

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ALPIDE status and future plans CERN, INFN, NIKHEF, CCNU (China) and YONSEI (Korea)

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  1. ALPIDE status and future plansCERN, INFN, NIKHEF, CCNU (China) and YONSEI (Korea)

  2. Specifications & motivation UPPER LIMIT lower much better ! • Nr of bits to code a hit : 35 • Fake hit : 10-5/event • Lowering integration time would significantly reduce background • Lowering power would significantly reduce material budget Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014

  3. Status Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014 • Low power : • Front-end (20.5nA/pixel), shaping(a few μs) determines integration time • Data driven readout (see Cesar’s presentation) • Two early submissions + Two engineering runs shared with the other groups. Present engineering run delayed to April 9th. • Several chips: • Explorer : sequential analog readout for pixel sensor optimization • Investigator : parallel fast (~10ns rise time) analog readout for pixel sensor optimization • pAlpide : small scale (512x64 array of 22x22 micron pixels) prototypes to optimize circuit • pAlpide_fs: full scale prototype (1024x512 of 28x28 micron pixels) prototype for system studies

  4. Explorer • Analog readout for pixel characterization • Readout time decoupled from integration time • Possibility to reverse bias the substrate • Sequential readout with correlated double sampling • Contains two 1.8x1.8mm2 matrices of 20x20 and 30x30 micron pixels with different geometries PULSED ROWS Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014

  5. Explorer-1 (April 2013) vs Explorer-0 (July 2012) • Comparison of 55Fe cluster signal for Explorer-0 and Explorer-1 • Explorer-1 shows ~ 2x signal increase, and similar noise level • Confirms correction on input capacitance, circuit contribution reduced from ~4.6 fF to ~2 fF Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014

  6. Efficiency & fake hit rate (Explorer-0) • High efficiency at low fake hit rates • Reverse substrate bias gives extra margin Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014

  7. Efficiency & fake hit rate (Explorer-1) Explorer-1 results after tests with electrons at DESY, averaged on all diode geometries • after irradiation drop of 10 - 20% in CCE, recovered with back bias • better performance of larger diodes with larger spacing to electronics • wider distance  wider depletion volume  lower input capacitance • better performance of 20 x 20 µm2 at low back bias voltage • detection efficiency above 99% up to 10σ cut, also after irradiation Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014

  8. pALPIDE pixel circuit diagram Low Power Analog Front End (< 40 nW/pixel) based on a single stage amplifier/current comparator. Priority encoder – Reset decoder: only zero-suppressed data are transferred to the periphery. Memory cell, hit enabled during the strobe window. Front-end output pulse set state STROBE Pixel State Register Priority encoder reset • Circuit capacitance is even smaller than on explorer 1. • First prototype pAlpide-0 works, but two issues: • Source to nwell diode of transistor inside collection electrode competes with resetting diode, “fixed” with light (> 10fA/pixel !!) • Amplifier/comparator stops working for reverse substrate biases > 2 V, due to loss of inversion in NMOS capacitor => could not operate at minimum sensor capacitance • Note: doubling the Pixel State Register significantly reduces dead time (cfr Adam’s simulations) ThanushanKugathasan - WP3, ITS-MFT mini-week, 10 March 2014

  9. pALPIDE first results Threshold Noise Analog output of one pixel under 55Fe • Minimum detectable charge <130 e- • At nominal bias (20.5 nA/pixel) and threshold setting: • Threshold spread 17 e- • Noise ~ 7 e- • 99.6% efficiency in beam test Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014

  10. pALPIDEfs Low Power Front-End • Fixes for two issues: • Input PMOS transistor outside collection electrode (also for pAlpide1) • Replace for some sectors resetting diode with PMOS transistor • Cost: additional capacitance, will have to evaluate impact • Implement capacitor with PMOS instead of NMOS • Also for faster clipping PMOS instead of NMOS clipping transistor • Still exploring other alternatives in pAlpides: avoid/minimize the penalty of additional capacitance, further reduce shaping time ThanushanKugathasan - WP3, ITS-MFT mini-week, 10 March 2014

  11. pALPIDEfs reset scheme PMOS reset Diode reset Collection electrode example Please note that in pALPIDE_fs the nwell is octagonal and the p+ ring is squared pwell opening = nwell diameter + 2 . spacing Pulsing capacitor: 160 aF Input routing line Input PMOS ThanushanKugathasan - WP3, ITS-MFT mini-week, 10 March 2014

  12. pALPIDE_fs: 30x15.3mm 1024x512 pixels Pads over the matrix 15.3 mm 30 mm gianluca.aglieri.rinella@cern.ch

  13. PADs over matrix: pixel routing 4 metals only 8 x 28 µm = 224 µm Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014 • Region of 8x8 pixels allocated for pad over matrix • Provide by-pass for row select and power routing • First results on explorer with metal pads over the matrix promising • Large design effort

  14. Periphery Matrix DACs Readout I/O pads gianluca.aglieri.rinella@cern.ch

  15. Pixels and Priority Encoders Analog Routing Priority Encoder gianluca.aglieri.rinella@cern.ch

  16. Readout and I/O pads gianluca.aglieri.rinella@cern.ch

  17. Investigator 5.0 mm x 5.8 mm • 135 mini-matrices • Each mini-matrix has 8x8 pixels. • 64 analog outputs to read all the pixels in a mini-matrix. • Different pixel designs: • Pixel width: from 20 x 20 um2 up to 50 x 50 um2 • Input transistor inside/outside collection n-well • Continuous diode reset and active PMOS switch reset • Deep-p-well (minimum and maximum) Thanushan Kugathasan - WP3, ITS-MFT mini-week, 10 March 2014

  18. Present engineering run: expected April 9th • CERN/INFN/WUHAN/YONSEI • pALPIDE_fs • pALPIDE (3) • EXPLORER (3) • INVESTIGATOR • TEST STRUCTURES • RAL • CHERWELL3 • 2 OTHER TEST CHIPS • IPHC • 2 AROM • 1 OTHER CHIP Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014

  19. Conclusions Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014 • Low power front-end (20.5nA/pixel) with data-driven readout, integration time of a few μs determined by shaping time of the front end • Analog: 20mW/4.5cm2, digital not optimized (100mW+200mW)/4.5cm2 for total chip, serializer to be added • This year one more submission for a further iteration before final decision • Full scale chip : Currently defining features, including interface (see Gianluca’s presentation) • Several additional building blocks (also on separate test chips): • Bandgap reference & temperature sensor (Nikhef) • Biasing DAC (Yonsei &CERN, already done for first pALPIDE_fs) • Monitoring ADC (INFN, Yonsei, CERN) • Serializer (with PLL) & LVDS driver (INFN) (see Gianni’s presentation) • pAlpide(s) : further front-end optimization (reduce C and shaping time) • Investigator & Explorer : further sensor optimization if needed • Front-end & sensor: Benefit of low C clearly established, still measuring different structures and starting materials, issues with front end have forced us to take a penalty for pALPIDE_fs, still exploring further improvements also for reduced shaping time • For further details on digital part, see Cesar’s and Alberto’s presentations

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