Modelling circuit performance variations due to statistical variability: Monte Carlo static timing analysis
Modelling circuit performance variations due to statistical variability: Monte Carlo static timing analysis
The scaling of MOSFETs has improved performance and lowered the cost per function of CMOS integrated circuits and systems over the last 40 years, but devices are subject to increasing amounts of statistical variability within the deca-nano domain. The causes of these statistical variations and their effects on device performance have been extensively studied, but there have been few systematic studies of their impact on circuit performance. This paper describes a method for modelling the impact of random intra-die statistical variations on digital circuit timing and power consumption. The method allows the variation modelled by large-scale statistical transistor simulations to be propagated up the design flow to the circuit level, by making use of commercial STA and standard cell characterisation tools. The method provides circuit designers with the information required to analyse power, performance and yield trade-offs when fabricating a design, while removing the large levels of pessimism generated by traditional Corner Based Analysis.
CMOS integrated circuits, MOSFET, Monte Carlo static timing analysis, circuit performance variations, corner based analysis, deca-nano domain, digital circuit timing, large-scale statistical transistor simulations, power consumption, random intra-die statistical variations, standard cell characterisation tools, statistical variability, Monte Carlo methods
1 -4
Merrett, M.
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Asenov, P.
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Wang, Yangang
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Zwolinski, M.
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Reid, D.
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Millar, C.
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Roy, S.
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Liu, Zhenyu
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Furber, S.
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Asenov, A.
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March 2011
Merrett, M.
5054c490-7dad-45ba-a937-88a80c11abcf
Asenov, P.
ba255b6b-7ed6-4e3e-8fbd-d242cd286cee
Wang, Yangang
84511804-36d1-44c7-90d4-a18201735a08
Zwolinski, M.
adfcb8e7-877f-4bd7-9b55-7553b6cb3ea0
Reid, D.
aa2ccf48-cc50-4bc9-acc8-a2a01c7ee9d1
Millar, C.
47515479-0dbf-42c6-9095-198e4d3cd3c3
Roy, S.
ac99cb46-0b15-486d-bd52-8a0523d7dc39
Liu, Zhenyu
a56b5a64-abab-4bc9-be95-6b031159680e
Furber, S.
138aa65c-75e3-4c42-bd9c-2d17d9b61ded
Asenov, A.
0c4a44b6-b45c-445c-841c-7294dfd67205
Merrett, M., Asenov, P., Wang, Yangang, Zwolinski, M., Reid, D., Millar, C., Roy, S., Liu, Zhenyu, Furber, S. and Asenov, A.
(2011)
Modelling circuit performance variations due to statistical variability: Monte Carlo static timing analysis.
Design, Automation Test in Europe Conference Exhibition (DATE), 2011.
.
Record type:
Conference or Workshop Item
(Poster)
Abstract
The scaling of MOSFETs has improved performance and lowered the cost per function of CMOS integrated circuits and systems over the last 40 years, but devices are subject to increasing amounts of statistical variability within the deca-nano domain. The causes of these statistical variations and their effects on device performance have been extensively studied, but there have been few systematic studies of their impact on circuit performance. This paper describes a method for modelling the impact of random intra-die statistical variations on digital circuit timing and power consumption. The method allows the variation modelled by large-scale statistical transistor simulations to be propagated up the design flow to the circuit level, by making use of commercial STA and standard cell characterisation tools. The method provides circuit designers with the information required to analyse power, performance and yield trade-offs when fabricating a design, while removing the large levels of pessimism generated by traditional Corner Based Analysis.
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More information
Published date: March 2011
Venue - Dates:
Design, Automation Test in Europe Conference Exhibition (DATE), 2011, 2011-03-01
Keywords:
CMOS integrated circuits, MOSFET, Monte Carlo static timing analysis, circuit performance variations, corner based analysis, deca-nano domain, digital circuit timing, large-scale statistical transistor simulations, power consumption, random intra-die statistical variations, standard cell characterisation tools, statistical variability, Monte Carlo methods
Organisations:
EEE
Identifiers
Local EPrints ID: 272390
URI: http://eprints.soton.ac.uk/id/eprint/272390
PURE UUID: 8c090653-faa3-460a-a9f1-44be0c1e0f77
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Date deposited: 01 Jun 2011 13:19
Last modified: 10 Jan 2022 02:33
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Contributors
Author:
M. Merrett
Author:
P. Asenov
Author:
Yangang Wang
Author:
M. Zwolinski
Author:
D. Reid
Author:
C. Millar
Author:
S. Roy
Author:
Zhenyu Liu
Author:
S. Furber
Author:
A. Asenov
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