mistral christine hu-guo on behalf of the iphc (strasbourg) picsel team outline mistral (inner...

Mistral

Christine Hu-Guo on behalf of the IPHC (Strasbourg) PICSEL team

Outline MISTRAL (inner layers)

Circuit proposal Work plan

Sensor variant for larger radii

IPHC [email protected] 227/6/2011 ALICE ITS WG3 meeting

MISTRAL-in (Inner layers) Running conditions:

30-35 °C, 2 MRad, 2x10^13 Neq/cm² Proposal: active area: ~10 x 30 mm²

Double Sided Readout (DSR) Power consumption: ~1200 mW/sensor

~400 (~250) mW/cm²

Single Sided Readout (SSR) Power consumption: ~600 mW/sensor

~200 (~160) mW/cm²

1 common digital development for both versions, only doubled for DSR

Pixel size Rφ,zReadout time

~20x20 µm² ~3.5-4 µm ~40-50 µs

~20x40 µm² ~5-6 µm ~20-25 µs


~20x40 µm² ~5-6 µm ~40-50 µs

Pixel Array

~ 10

Unit: mm

~ 30

Digital Part: Controller + SUZE + Memory

Pixel Array

~ 10

~ 30



MISTRAL-in (e.g. Single-Sided Readout SSR)

~1 c

m

~1 cm

Discriminators

512x256

SUZEMUX

Memory 1 Memory 2Serial read out

Discriminators

512x256

SUZEMUX

Memory 1 Memory 2

Discriminators

512x256

SUZEMUX

Memory 1 Memory 2

Proposal for a modulo design: Overcome design complexity (frequency, readout time, layout) over 3 cm long sensor

Reuse the basic block for other applications Easy for prototype evaluation, the basic block should incorporate all pads needed for

tests

Independent blocks


SUZE-02 Based on MIMOSA26 and ULTIMATE design principle

Occupancy 5.2 x10^5 hits/cm²/s (Costanza, 20 June 2011) Parallel search in 8 banks (64 columns/bank)

No. of states per bank Combine the outputs of the 8 banks

No. of states per raw Safety factor x 4

Safety factor x 5

Sensor type Pixel (µm²)

RO* (µs)

Hits/ frame

Noisy pixels

No. of states / bank (probability)*

No. of states / row(probability)*

Memory sizex 2 *

DSR 512x512 20x20 51.2 56x2 13x2 3 (0.016%) 6 (0.017%) ~5.8 Kbits x 2

DSR 512x256 20x40 25.6 28x2 7x2 3 (0.017%) 6 (0.019%) ~2.9 Kbits x 2

SSR 512x256 20x40 51.2 112 13 3 (0.09%) 7 (0.07%) ~ 11.2 Kbits

*Readout time 200 ns/row (based on 0.35 µm process, perhaps shorter in 0.18 µm)*Fraction of noisy pixels 10^(-4)*Overflows per bank & per raw < 0.1%*Calculation for worst case, 2 memories in pipeline mode, 16 bits / word

Sensor type Pixel (µm²)

RO* (µs)

Hits/ frame

Noisy pixels

No. of states / bank (probability)*

No. of states / row(probability)*

Memory size* x 2

DSR 512x512 20x20 51.2 70x2 13x2 3 (0.027%) 6 (0.044%) ~7.2 Kbits x 2

DSR 512x256 20x40 25.6 35x2 7x2 3 (0.03%) 6 (0.049%) ~3.6 Kbits x 2

SSR 512x256 20x40 51.2 140 13 4 (0.009%) 8 (0.045%) ~ 13.9 Kbits IRFU - IPHC [email protected] 2012-17/03/2009 TIPP

State: Column address of the 1st pixel+ 2 bits code

Row M-1

Row M+1

Row M

HIT

.….…

1 0

1 0

0

10

0

1 0

1 1

1

1

1

1

State Binary code

00011011

statestatestate

……

.…

Column address of the 1st pixel

2 bits binary code

Assume each hit activates 3 contiguous rowsState: Up to 4 contiguous pixels with output above threshold


SUZE-02

Accounting for the effect of long term irradiation (Noise , Signal ): 6 states per bank 12 states (or more, up to 16? 4-bit encoding) per group of 512 columns Memory: 16-bit/word not yet optimised

Silicon surface & data flow

Output bit rate for whole, 3 cm long, sensor : ~ 800 Mbits/s (safety factor = 5, SSR, memory: 16-bit/word)

In case of fake rate ~10^(-3), foresee ~1Gbit/s In case of single output (SSR), a digital modulation seems mandatory

Within 1 clock cycle, more than 1 bit can be sent

Status of a raw

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

Bit (0-3) Bit (0-7)

No. of states address of the raw F unused

Status of a state

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

Bit (0-2) Bit (0-7)

No. hit pixels address of the column unused


Work Plan: MISTRAL-in (1) RAMSES (INMAPS 0.18 µm) tested in April/May 2011 at IPHC

ENC~20-50 e-, wide noise dispersion, Contact with designer, investigation on going

MIMOSA30 (0.35 µm) design on going, submission: Sept. 2011 Evaluate elongated pixel (16x64 µm²) and readout from both sides

MIMOSA32 1st prototype in Tower CIS 0.18 µm technology Motivation for CIS 0.18 µm:

Small technology feature allows: Radiation tolerance , Read-out speed , Power consumption , Si surface (periphery)

6 metal levels may suppress dead zone (steering logic control part) Optimised sensing systems available and tunable enhanced SNR High-resistivity epitaxy (1 - 5 kΩ · cm) enhanced SNR … Deep P well PMOS transistors permitted (radiation tolerance detection efficiency?)

Improve pixel performance, integration of intelligence within pixel


Work Plan: MISTRAL-in (2)

MIMOSA32 submission: end of Oct. 2011: Chip dimension: ~3x8 mm² Technology exploration & evaluation Sensing device optimisation Pixel optimisation: in pixel amplifier (PMOS?)

Basic pixel size: 20x20 µm², but also 20x40 and 20x80 µm² Develop building blocks: amplifier, column-level discriminators, LVDS, … Evaluate digital circuit w.r.t. latch up!

STAR collaboration • SUZE, Mimosa22 and Phase-1 are more susceptible to latch up than Mimostar2.

• SUZE is more susceptible to latch up by a factor of ~5.


Work Plan: MISTRAL-in (3) MIMOSA22THR (3 circuits?): submission June 2012

Estimated total chip dimensions ~80 mm² Integration of pixel array + discriminators

Both have been tested in Mimosa32 Test the most critical sub-circuits SEU tolerance design for critical parts

Decision: after irradiation test, make a choice 1. Pixel 20x20 vs 20x40 µm² 2. DSR vs SSR

SUZE-02: submission June 2012 ? Evaluate: latch-up tolerance, memory design (IP? who?)

FSBB(~ 1.3 cm²): submission Q2/2013 Proposal: basic modulo block

MISTRAL (e.g. SSR ~4 cm²): submission Q2/2014 Synchronisation of three blocks Clock distribution Serial transmission (should be studied before)

DiscriminatorsRed: (4 signals) PWR_ON, Slct_Row, Slct_Grp, Clp

Green: Column line of pixels output

Discriminators

512x256

SUZEMUX

Memory 1 Memory 2

Discriminators

512x256

SUZEMUX

Memory 1 Memory 2

Discriminators

512x256

SUZEMUX

Memory 1 Memory 2Serial read out

Discriminators

128x128

A trial to suppress dead zoneIt may be done with 6 ML

128x526

FSBB: Full Size Building Block


Sensor variant for larger radii

Pixel Array

~ 20

~ 30


Running conditions: 30-35 °C, less than 50 kRad (estimated), less than 5x10^11 Neq/cm² (estimated)

Active area: ~20 x 30 mm², readout: SSR Pixel width ~ 20 µm may be an extension of MISTRAL-in

Discriminators ending each column Not adapted to dE/dx measurement Power consumption: ~600 mW/sensor, ~200 (~160) mW/cm²

May benefit from the digital development of MISTRAL

Pixel width ~ 40 µm n (?) -bit ADC ending each column dE/dx measurement Power consumption: ~500 (?) mW/sensor

Need new SUZE development & for n>4, need ADC development FTE

Modulo design proposal should still be valid for both designs


~20x80 µm² ~6-7 µm ~ 50 µs


~40x80 µm² ~4 µm ~ 50 µs


Existing Prototype: MIMOSA22AHR (1) MIMOSA22AHR (0.35 µm) submitted & tested in 2010

EPI: ~400 Ω.cm, thickness: 10, 15, 20 µm (Standard EPI: ~10 Ω.cm, thickness: 14 µm) 16 different sub matrices connected to discriminators

128 columns: binary output + 8 columns: analogue output 2 sub-arrays (2/16) featuring elongated pixels

18.4x36.8 µm² (S15) & 18.4x73.6 µm² (S16)

Low diode density CCE Irradiation Leakage current Noise Globally: enhanced vulnerability to radiation

128 x 32

128 x 16

Discriminators

S15 S16S11


Existing Prototype: MIMOSA22AHR (2)

Lab test @20 & 35°C, @3x10^12 Neq/cm², @150 kRad

Preliminary beam test results at SPS (T ~20°C, before irradiation): Analogue readout: region limited statistics limited

S/N (seed) ~ 30 Digital output: overall satisfying performances

No significant loss in detection efficiency: eff >~ 99.8% for a 10-5 fake rate No inefficient region observed (but statistics small) Spatial resolution satisfactory

S15 ~ 4.7 m ; S16 ~ 6 m (binary charge encoding)

S11: 18.4 x 18.4 µm² S15: 18.4 x 36.8 (µm²) S16: 18.4 x 73.6 (µm²)

35 °C 3x1012 Neq/cm² 150 kRad 3x1012 Neq/cm² 150 kRad 3x1012 Neq/cm² 150 kRad

CCE (seed) 31.4 % 31.7 % 31.5 % 29.9 % 29.1 % 29.7 % 24.7 % 19.2 % 24.6 %

Total Noise 12.2 e- 17.9 e- 15.1 e- 11.3 e- 20.1 e- 13.8 e- 11.6 e- 22.9 e- 14.2 e-

S/N (~MIP) 32 24 28 32 20 27 26 13 22

A. DOROKHOV


Other sensors (0.35 µm process) planned for submission

MIMOSA29: test structure for large pixels to be submitted in June 2011 64x16 µm², 64x32 µm², 64x64 µm²

1, 2 or 4 diodes in a pixel 80x16 µm², 80x48 µm², 80x80 µm²

1, 2 or 4 diodes in a pixel

MIMOSA31 design on going, submission: Sept. 2011 1st sensor incorporating pixel array with ADC ending each column

Pixel: 35x35 µm² ADC: "4" bit (4-3-2 bit)

ADC is based on a successive approximation Architecture requires 4 cycles to complete one conversion

These sensors act as forerunners for possible R&D of sensors adapted to large radii

Translate design from 0.35 to 0.18 µm? dE/dx measurement may require a dedicated ADC development

SUZE development


Summary

A baseline CMOS pixel sensor adapted to the specifications of L0 + ... is likely to be achievable by 2014

It is based on the ULTIMATE (MIMOSA28) chip realised for the STAR-PXL 0.18 μm CMOS technology expected to comply with radiation tolerance specifications DSR or SSR 40-50 or 20-25 μs readout time (NI rad. tolerance vs pitch) Room temperature operation (air flow)

Work plan (MISTRAL-in): 4 submissions Oct. 2011 MIMOSA32: technology exploration, pixel optimisation, building

blocks, latch-up evaluation for digital part June 2012 MIMOSA22THR: integration of pixel array + discriminators, test of

most critical sub-circuits, SEU tolerance design for critical parts

SUZE-02: latch-up tolerance evaluation, memory design Q2/2013 FSBB: development of the basic modulo block Q2/2014 MISTRAL: final sensor

MISTRAL-out: 2 possibilities: Extension of MISTRAL-in: pixel 20x80 µm², discriminators ending each column Alternative (R&D needed): pixel 40x80 µm², n(?)-bit ADC ending each column new

SUZE


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