Quadratic Statistical MAX Approximation for Parametric Yield Estimation of Analog/RF Integrated Circuits

Quadratic Statistical MAX Approximation for Parametric Yield Estimation of Analog/RF Integrated Circuits

In this paper, we propose an efficient numerical algorithm for estimating the parametric yield of analog/RF circuits, considering large-scale process variations. Unlike many traditional approaches that assume normal performance distributions, the proposed approach is particularly developed to handle...

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Bibliographic Details
Published in:IEEE transactions on computer-aided design of integrated circuits and systems Vol. 27; no. 5; pp. 831 - 843
Main Authors: Xin Li, Yaping Zhan, Pileggi, L.T.
Format: Journal Article
Language:English
Published: IEEE 01-05-2008
Subjects:
Analog/RF circuits
Approximation algorithms
Circuits
Distributed computing
Large-scale systems
MAX operator
Monte Carlo methods
parametric yield
Probability distribution
Radio frequency
Runtime
Taylor series
Yield estimation
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Summary:In this paper, we propose an efficient numerical algorithm for estimating the parametric yield of analog/RF circuits, considering large-scale process variations. Unlike many traditional approaches that assume normal performance distributions, the proposed approach is particularly developed to handle multiple correlated nonnormal performance distributions, thereby providing better accuracy than the traditional techniques. Starting from a set of quadratic performance models, the proposed parametric yield estimation conceptually maps multiple correlated performance constraints to a single auxiliary constraint by using a MAX operator. As such, the parametric yield is uniquely determined by the probability distribution of the auxiliary constraint and, therefore, can easily be computed. In addition, two novel numerical algorithms are derived from moment matching and statistical Taylor expansion, respectively, to facilitate efficient quadratic statistical MAX approximation. We prove that these two algorithms are mathematically equivalent if the performance distributions are normal. Our numerical examples demonstrate that the proposed algorithm provides an error reduction of 6.5 times compared to a normal-distribution-based method while achieving a runtime speedup of 10-20 times over the Monte Carlo analysis with 10 3 samples.
ISSN:0278-0070
1937-4151
DOI:10.1109/TCAD.2008.917582