front-end electronics for strip detectors (an atlas perspective on slhc)
DESCRIPTION
Front-end Electronics for Strip Detectors (an ATLAS perspective on SLHC) 2 nd Trento Workshop on Advanced Silicon Radiation Detectors Trento, Italia 14-Feb-2006 A.A. Grillo SCIPP – UCSC. The ATLAS Strip Detector Readout. - PowerPoint PPT PresentationTRANSCRIPT
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Front-end Electronics for Strip Detectors2nd Trento Workshop on Advanced Si Rad Detectors
1A.A. GrilloSCIPP-UCSC
Front-end Electronics for Strip DetectorsFront-end Electronics for Strip Detectors(an ATLAS perspective on SLHC)(an ATLAS perspective on SLHC)
2nd Trento Workshop on Advanced Silicon Radiation Detectors
Trento, Italia
14-Feb-2006
A.A. GrilloSCIPP – UCSC
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Front-end Electronics for Strip Detectors2nd Trento Workshop on Advanced Si Rad Detectors
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The ATLAS Strip Detector ReadoutThe ATLAS Strip Detector Readout
The present ATLAS strip detector readout IC (named ABCD) is fabricated on the DMILL biCMOS technology.
• The front-end amplifier, shaper and discriminator in bipolar.
• The back-end pipeline, readout, command decoder, etc. in CMOS.
The DMILL technology is no longer available and it would likely not be sufficiently rad-hard for the higher SLHC luminosity, at least not at the same radii.
A new technology must be chosen.
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Deep Sub-micron CMOS a PossibilityDeep Sub-micron CMOS a Possibility
One obvious possibility is a complete IC in deep sub-micron CMOS.
• Radiation hardness of 0.25 m CMOS has been demonstrated at levels sufficient for strip use at SLHC
• Newer 0.13 m technologies are now being evaluated and are most likely at least as rad-hard if not more.
A demonstration front-end circuit was designed and fabricated in 0.25 m CMOS a few years ago and was shown to meet present ATLAS noise and timing requirements.
A proposal is now being discussed to build a CMOS replacement for the full ABCD chip to demonstrate feasibility and evaluate performance.
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J. Kaplon et al., 2004 IEEE Rome Oct 2004, use 0.25 m CMOS
Demonstration Front-end CMOS CircuitDemonstration Front-end CMOS Circuit
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Past ExperiencePast Experience
A biCMOS technology was ideal for the existing ATLAS readout IC because:
• We have shown for past experiments that the bipolar technology has advantages over CMOS in power and performance for front-end amplification when the capacitive loads are high and the shaping times short.
• ZEUS-LPS Tek-Z IC• SSC-SDC LBIC IC• ATLAS-SCT ABCD, CAFE-M, CAFE-P ICs
• CMOS is the preferred technology for memory and logic circuits of the back-end.
• BiCMOS technology afforded both of these optimizations in one IC.
Experience with commercial 0.25 m CMOS has shown the advantage of using a volume commercial rather than a niche technology.
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Technical IssuesTechnical Issues
The ATLAS-ID upgrade will put even greater constraints on power.
Can we meet power and shaping time requirements with deep sub-micron CMOS?
• Achieving sufficient transconductance of the front-end transistor typically requires large bias currents.
The timing of the SLHC is not yet fixed. If this dictates a faster
shaping time, the transconductance vs. power will become a bigger issue.
If past experience still applies, a bipolar front-end may be able to meet noise and timing requirements for less power than a CMOS solution.
Are there commercial biCMOS technologies that could meet all of our stringent requirements?
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biCMOS with Enhanced SiGebiCMOS with Enhanced SiGe
The market for wireless communication has now spawned many biCMOS technologies where the bipolar devices have been enhanced with a germanium doped base region (SiGe devices).
We have identified at least the following vendors:
• IBM (at least 3 generations available)
• STm
• IHP, (Frankfurt on Oder, Germany)
• Motorola
• JAZZ
Advanced versions include CMOS with feature sizes of 0.25 m to 0.13 m.
The bipolar devices have DC current gains () of several 100 and fTs up to 200s of GHz. This implies very small geometries that could afford higher current densities and more rad-hardness.
Growing number of fab facilities
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Technical QuestionsTechnical Questions
The changes that make SiGe Bipolar technology operate at 100s of GHz for the wireless industry coincide with the features that enhance performance for our application.
• Small feature size increases radiation tolerance.
• Extremely small base resistance (of order 10-100 ) affords low noise designs at very low bias currents.
Can these features help save power?
Will the SiGe technologies meet rad-hard requirements?
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Radiation vs. Radius in Upgraded TrackerRadiation vs. Radius in Upgraded Tracker
The usefulness of a SiGe bipolar front-end circuit will depend upon its radiation hardness for the various regions (i.e. radii) where silicon strip detectors might be used.
1
10
100
0 20 40 60 80 100
Fluence for 2,500 fb -1
Radius [cm]
InnerPixel
Mid-RadiusShort Strips
Outer-Radius “SCT”
Flu
ence
[10
14 n
eq/c
m2 ]
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Tracker Regions Amenable for SiGeTracker Regions Amenable for SiGe
For the inner tracker layers, pixel detectors will be needed, and their small capacitances allow the use of deep sub-micron CMOS as an efficient readout technology.
Starting at a radius of about 20 cm, at fluence levels of 1015 n/cm2, short strips can be used, with a detector length of about 3 cm and capacitances on the order of 5 pF. At a radius of about 60 cm, the expected fluence is a few times 1014 n/cm2, and longer strips of about 10 cm and capacitance of 15 pF can be used.
It is in these two outer regions with sensors with larger capacitive loads where bipolar SiGe might be used in the front-end readout ASICs with welcome power savings while still maintaining fast shaping times.
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Biasing the Analogue CircuitBiasing the Analogue Circuit
The analog section of a readout IC for silicon strips typically has a special front transistor, selected to minimize noise (often requiring a larger current than the other transistors), and a large number of additional transistors used in the shaping sections and for signal-level discrimination.
The current for the front transistor is selected in order to achieve the desired transconductance (minimize noise). For the other bipolar devices, bias levels for the other transistors are determined to achieve the necessary rad-hardness, matching and shaping times.
Depending upon the performance (especially radiation hardness) of the bipolar process, power savings could be realized in both the front transistor and in the other parts of the analogue circuit.
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Evaluation of SiGe Radiation HardnessEvaluation of SiGe Radiation Hardness
The Team
D.E. Dorfan, A. A. Grillo, A. Jones, G.F. Martinez-McKinney, M. Mendoza, P. Mekhedjian, J. Metcalfe, H. F.-W. Sadrozinski,
G. Saffier-Ewing, A. Seiden, E. N. Spencer, M. WilderSCIPP-UCSC
Collaborators: A. Sutton, J.D. Cressler, A.P. Gnana PrakashGeorgia Tech, Atlanta, GA 30332-0250, USA
F. Campabadal, S. Díez, C. Fleta, M. Lozano, G. Pellegrini, J. M. Rafí, M. Ullán
CNM (CSIC), Barcelona
S. Rescia et al.BNL
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First SiGe High-rate Radiation Testing First SiGe High-rate Radiation Testing
Radiation testing has been performed on some SiGe devices by our Georgia Tech collaborators up to a fluence of 1x1014 p/cm2 and they have demonstrated acceptable performance. (See for example: http://isde.vanderbilt.edu/Content/muri/2005MURI/Cressler_MURI.ppt)
In order to extend this data to higher fluences, we obtained some arrays of test structures from our collaborator at Georgia Tech. These were from a -enhanced 5HP (called 5AM) process from IBM. (i.e. the was ~250 rather than ~100.)
The parts were tested at UCSC and with the help of RD50 collaborators (Michael Moll & Maurice Glaser) they were irradiated in Fall 2004 at the CERN PS and then re-tested at UCSC.
For expediency, all terminals were grounded during the irradiation This gives slightly amplified rad effects compared to normal biasing.
Annealing was performed after initial post-rad testing.
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Irradiated SamplesIrradiated Samples
Pre-rad
1.15 x 10144.15 x 1013 3.50 x 1014
1.34 x 10153.58 x 1015
1.05 x 1016
ATLAS Upgrade
Outer Radius
Mid RadiusInner Radius
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Radiation Damage MechanismRadiation Damage Mechanism
10-14
10-12
10-10
10-8
10-6
10-4
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
Forward Gummel Plot for 0.5 mm x 2.5 mm:
IC, IB vs. VB pre-rad and after 1*10 15 p/cm2 + anneal
IC (pre-rad)IB (pre-rad)IC (1e15, anneal)IB (1e15, anneal)
VB [V]
Ionization Damage (in the spacer oxide layers)• The charged nature of the particle creates oxide trapped charges and
interface states in the emitter-base spacer increasing the base current.
Displacement Damage (in the oxide and bulk)• The incident mass of the particle knocks out atoms in the lattice
structure shortening hole lifetime, which is inversely proportional to the base current.
Radiation damage increases base current causing the gain of the device to degrade.
Gain=Ic/Ib (collector current/base current)
I c , I
b [A
]
Forward Gummel Plot for 0.5x2.5 m2
Ic,Ib vs. Vbe Pre-rad and After 1x1015 p/cm2 & Anneal Steps
Vbe [V]
Base current increases after
irradiation
Collector current remains the same
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Annealing EffectsAnnealing Effects
0.1
1
10
100
1000
10-10 10-9 10-8 10-7 10-6 10-5 10-4 10-3
Annealing of 0.5 um x 2.5 um: Current Gain beta vs. Ic
pre-rad and after 1*1015 p/cm2 and anneal steps
pre-rad1e15, no anneal1e15, 5 days RT1e15, +6 days RT+1 day 60deg C1e15, +1 day 100deg C1e15, +6 days 100deg C
IC [A]
We studied the effects of annealing. The performance improves appreciably. In the case above, the gain is now over 50 at 10A entering into the region where an efficient chip design may be implemented with this technology. The annealing effects are expected to be sensitive to the biasing conditions. We plan to study this in the future.
Cur
rent
Gai
n,
Ic [A]
Annealing of 0.5x2.5 m2: Current Gain, , vs. Ic
Pre-rad and After 1x1015 p/cm2 & Anneal Steps
Before Irradiation
After IrradiationAfter Irradiation & Full Annealing
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Initial ResultsInitial Results
0.1
1
10
100
1000
10-10
10-9
10-8
10-7
10-6
10-5
10-4
10-3
Current Gain beta vs. Ic for 0.5 um x 10um pre-rad and for all Fluences including full annealing
Pre-rad3e131e143e141e153e151e16
IC [A]
After irradiation, the gain decreases as the fluence level increases. Performance is still very good at a fluence level of 1x1015 p/cm2. A typical Ic for transistor operation might be around 10 A where a of around 50 is required for a chip design. At 3x1015, operation is still acceptable for certain applications.
Cur
rent
Gai
n,
Current Gain, , vs. Ic for 0.5x10 m2
Pre-rad and for All Fluences Including Full Annealing
Ic [A]
Before Irradiation
Highest Fluence
Lowest Fluence
Cur
rent
Gai
n,
Increasing Fluence
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Universality of ResultsUniversality of Results
0.0001
0.001
0.01
0.1
1013 1014 1015 1016
Delta(1/beta) post-rad+anneal to pre-rad @ Jc = 10 uA
0.5 um x 1 um0.5 um x 2.5 um0.5 um x 10 um0.5 um x 20 um4 um x 5um
Proton Fluence F [p/cm2]
0
0.2
0.4
0.6
0.8
1
1013 1014 1015 1016
Ratio of Current Gain beta post-rad+anneal to pre-rad @ Jc = 10 uA
0.5 um x 1 um0.5 um x 2.5 um0.5 um x 10 um0.5 um x 20 um4 um x 5um
Proton Fluence F [p/cm2]Proton Fluence [p/cm2]
1/(
fina
l) -
1/
( ini
tial
)
(1/)
Post-rad & Anneal to Pre-rad @ Jc=10A
Proton Fluence [p/cm2]
Ratio of Current Gain, Post-rad & Anneal to Pre-rad @ Jc=10 A
Rat
io
(fin
a l)/ (
init
ial)
Universal behavior independent of transistor geometry when compared at the same current density Jc. For a given current density (1/b) scales linearly with the log of the fluence. This precise relation allows the gain after irradiation to be predicted for other SiGe HBTs. Note there is little dependence on the initial gain value.
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Feasibility for ATLAS ID UpgradeFeasibility for ATLAS ID UpgradeQualifications for a good transistor:
A gain of 50 is a good figure of merit for a transistor to use in a front-end circuit design.
Low currents translate into increased power savings.
At 3.5x1014 in the outer region (60 cm), where long (10 cm) silicon strip detectors with capacitances around 15pF will be used, the collector current Ic is low enough for substantial power savings over CMOS!
At 1.34x1015 closer to the mid radius (20 cm), where short (3 cm) silicon strip detectors with capacitance around 5pF will be used, the collector current Ic is still good for a front transistor, which requires a larger current while minimizing noise. We expect better results from 3rd generation IBM SiGe HBTs.
Fluence: 3.50E14 p/cm2 (2.17x1014 neq/cm2)=50
Transistor Size m2 cirrad Ic anneal
0.5x1 2.E-060.5x2.5 4.E-06 5.E-080.5x10 3.E-05 8.E-070.5x20 5.E-05 2.E-064x5 9.E-06 5.E-07
Fluence: 1.34E15 p/cm2 (8.32x1014 neq/cm2)=50
Transistor Size m2 cirrad Ic anneal
0.5x1 3.E-05 1.E-070.5x2.5 7.E-05 4.E-060.5x10 4.E-04 9.E-060.5x20 6.E-054x5 1.E-04 1.E-05
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IHP - Another SiGe Vendor IHP - Another SiGe Vendor
CNM has obtained a first set of test structures from IHP and is proceeding with that evaluation.
• 2 Test chip wafer pieces with ~20 chips
• 2 Technologies:
SGC25C (bipolar module equivalent to SG25H1)
SG25H3 (Alternative technology)
• Edge effects:
Test chips came from edge of wafer
Will be solved in future samples
Irradiations with gammas to 10 Mrad and 50 Mrad have been performed. Neutrons and protons to be done.
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Preliminary Results for IHP from CNMPreliminary Results for IHP from CNM
IHP SGC25C SiGe technology• Bipolar transistors equivalent to SG25H1 technology (fT = 200 GHz)• No Annealing !
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Second IHP TechnologySecond IHP Technology
IHP SG25H3 SiGe technology• fT = 120 GHz, Higher breakdown voltages• Annealing after 50 Mrads: 48 hours, very good recovery• Very low gains before irradiation (edge wafer transistors)
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Continuing Studies of IBM TechnologiesContinuing Studies of IBM Technologies
Neutron irradiation is in progress at Ljubljana. Gammas will be done at BNL next month with protons to follow this spring.
We are continuing the studies of three IBM technologies (5HP, 7HP and 8HP) using neutrons, gammas and protons.
8HP comes with0.13 m CMOS
5AM & 5HP comes with 0.25 m & 0.50 mm CMOS
5AM & 5HP comes with 0.25 m & 0.50 mm CMOS
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IHP has the SG25H1 200 GHz SiGe process available on Europractice. is ~200. In parallel with radiation testing by Barcelona, UCSC is developing an eight channel amplifier/comparator with similar specifications to the present ABCD.
The x4 minimum transistor has base resistance of 51 m x 3.36 m. 0.25 m CMOS is also included. Extensive use is made of the 2.0 k/ square unsilicided polysilicon resistor structure, since this is expected to be radiation resistant.
The purpose of this FE design is to estimate the low current bias performance of SiGe, and to see whether it can produce significant power savings. The target voltage bias level is 2 V.
IHP Design to Estimate Power of IHP Design to Estimate Power of Upgrade FrontendUpgrade Frontend
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IHP provides a Cadence Kit, with support for both Diva and Allegro.
The bipolar devices are complete as provided, no editing allowed, with some hidden layers to protect IHP intellectual property.
Radiation hard annular NMOS transistor drawing is well supported. This is done by allowing 135 degree bends of Poly lines on Active in the DRC. There are included Virtuoso utilities that are needed for successful DRC.
Cadence Spectre does not DC converge well. Mentor has Eldo utility “Artist Link” that enables Eldo to run with Cadence schematic Composer. Eldo converges vigorously. Overall, the Cadence Kit is complete enough, and with the help of Eldo, is a good toolset.
Design Procedure DetailsDesign Procedure Details
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Frontend Simulation ResultsFrontend Simulation Results
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J. Kaplon et al., 2004 IEEE Rome Oct 2004, use 0.25 m CMOS
For CMOS: Input transistor: 300 A, other transistors 330 A (each 20 – 90 A)
Power for the CMOS Front-EndPower for the CMOS Front-End
Can SiGe beatthese numbers?
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First Guess at Potential Power SavingsFirst Guess at Potential Power Savings
CHIP TECHNOLOGY FEATURE
0.25 m CMOS ABCDS/FE
J. Kaplon et al.,(IEEE Rome Oct 2004)
IHP SG25H1 SCT-FE Preliminary design
Power: Bias for all but front transistor
330 A 0.8 mW= 30 A(conservative)
.06 mW
Power: Front bias for 25 pF load 300 A 0.75 mW
150 A 0.30 mW
Power: Front bias for 7 pF load 120 A 0.3 mW A 0.10 mW
Total Power (7 pF) 2x1015
0.36 mWTotal Power (25 pF) 3x1014
1.1 mW
1.5 mW
0.16mW
Using similar estimates of bias settings and transistor counts, an estimate for power can be obtained.
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Conclusions on SiGe Evaluation So FarConclusions on SiGe Evaluation So Far
First tests of one SiGe biCMOS process indicate that the bipolar devices may be sufficiently rad-hard for the upgraded ATLAS tracker, certainly in the outer-radius region and even perhaps in the mid-radius region.
A simulation estimate of power consumption for such a SiGe front-end circuit indicates that significant power savings might be achieved.
More work is needed to both confirm the radiation hardness and arrive at more accurate estimates of power savings.
In particular, with so many potential commercial vendors available, it is important to understand if the post-radiation performance is generic to the SiGe technology or if it is specific to some versions.
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Work AheadWork Ahead
Along with our collaborators, we plan two parallel paths of work.
We will complete the irradiation studies of several SiGe processes. In particular, we plan to test at least the IBM 5HP, IBM 7HP, IBM 8HP, IHP SGC25C (eq. to SG25H1), IHP SG25H3 and IHP SGB25VD.
• CNM will focus on the IHP technologies.
• UCSC on IBM.
To obtain a better handle on the true power savings, we will submit an IHP 8 channel amplifier/comparator in spring 2006. This work is in parallel with IHP radiation characterization.
The BNL LAr group is also interested in SiGe and has joined the team to complete the evaluation.
Once the SiGe evaluation is complete, a choice can be made between SiGe bipolar or CMOS for the front-end to be married with the CMOS backend.