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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 - PowerPoint PPT Presentation
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ALPIDE status and future plans
CERN, INFN, NIKHEF, CCNU (China) and YONSEI (Korea)
LOGO
Specifications & motivation
2
Lowering integration time would significantly reduce background Lowering power would significantly reduce material budget
UPPER LIMIT lower much better !
• Nr of bits to code a hit : 35• Fake hit : 10-5 /event
Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014
Status 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
3Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014
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
Explorer
4
PU
LSE
D R
OW
S
Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014
Explorer-1 (April 2013) vs Explorer-0 (July 2012)
5
• 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
Efficiency & fake hit rate (Explorer-0)
6
High efficiency at low fake hit rates
Reverse substrate bias gives extra margin
Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014
Efficiency & fake hit rate (Explorer-1)
7
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
pALPIDE pixel circuit diagram
8Thanushan Kugathasan - WP3, ITS-MFT mini-week, 10 March 2014
Memory cell, hit enabled during the strobe window.
Priority encoder – Reset decoder: only zero-suppressed data are transferred to the periphery.
Low Power Analog Front End (< 40 nW/pixel) based on a single stage amplifier/current comparator.
Pixel State Register
Priority encoder
state
resetSTROBE
set
Front-end output pulse
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)
pALPIDE first results
9
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
Analog output of one pixel under 55FeNoise
Threshold
Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014
pALPIDEfs Low Power Front-End
10Thanushan Kugathasan - WP3, ITS-MFT mini-week, 10 March 2014
VRESET
PWELL
IBIASsource
curfeed
VCASP
AVDD
AVSS
VCASN
ITHR IDB
M0b
D1
M1
M2
M3
Cc
M4
M5
IRESET
pix_in
pix_out
PIX_OUT_B
VPULSECinj
160 aFVAUX
D0
Diode ResetPMOS Reset
AVSS
M0a
Fixes for two issues: Input PMOS transistor outside collection electrode (also for pAlpide1) Replace for some sectors resetting diode with PMOS transistorCost: additional capacitance, will have to evaluate impact Implement capacitor with PMOS instead of NMOS Also for faster clipping PMOS instead of NMOS clipping transistorStill exploring other alternatives in pAlpides: avoid/minimize the penalty of additional capacitance, further reduce shaping time
pALPIDEfs reset scheme
Thanushan Kugathasan - WP3, ITS-MFT mini-week, 10 March 2014 11
Sector Columns nwell diameter spacing pwell
opening Reset
1 0 to 255 2 µm 1 µm 4 µm PMOS
2 256 to 511 2 µm 2 µm 6 µm PMOS
3 512 to 767 2 µm 2 µm 6 µm Diode
4 768 to 1023
2 µm 4 µm 10 µm PMOS
PMOS reset Diode reset
Collection electrode example
Pulsing capacitor:160 aF
Input routing line
Input PMOS
pwell opening = nwell diameter + 2 . spacing
Please note that in pALPIDE_fs the nwell is octagonal and the p+ ring is squared
PADs over matrix: pixel routing 4 metals only 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
13
8 x 28 µm = 224 µm
Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014
Readout and I/O pads
Investigator
17Thanushan Kugathasan - WP3, ITS-MFT mini-week, 10 March 2014
• 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)
5.0 mm x 5.8 mm
Present engineering run: expected April 9th
18
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
Conclusions 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
19Walter Snoeys - WP3, ITS-MFT mini-week, 10 March 2014