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Stochastic Testing Method for Transistor-Level Uncertainty Quantification Based on Generalized Polynomial Chaos

Computational Engineering, Finance, and Science 2016-11-18 v1

Abstract

Uncertainties have become a major concern in integrated circuit design. In order to avoid the huge number of repeated simulations in conventional Monte Carlo flows, this paper presents an intrusive spectral simulator for statistical circuit analysis. Our simulator employs the recently developed generalized polynomial chaos expansion to perform uncertainty quantification of nonlinear transistor circuits with both Gaussian and non-Gaussian random parameters. We modify the nonintrusive stochastic collocation (SC) method and develop an intrusive variant called stochastic testing (ST) method to accelerate the numerical simulation. Compared with the stochastic Galerkin (SG) method, the resulting coupled deterministic equations from our proposed ST method can be solved in a decoupled manner at each time point. At the same time, ST uses fewer samples and allows more flexible time step size controls than directly using a nonintrusive SC solver. These two properties make ST more efficient than SG and than existing SC methods, and more suitable for time-domain circuit simulation. Simulation results of several digital, analog and RF circuits are reported. Since our algorithm is based on generic mathematical models, the proposed ST algorithm can be applied to many other engineering problems.

Keywords

Cite

@article{arxiv.1409.4831,
  title  = {Stochastic Testing Method for Transistor-Level Uncertainty Quantification Based on Generalized Polynomial Chaos},
  author = {Zheng Zhang and Tarek A. El-Moselhy and Ibrahim and M. Elfadel and Luca Daniel},
  journal= {arXiv preprint arXiv:1409.4831},
  year   = {2016}
}

Comments

published by IEEE Trans CAD in Oct 2013

R2 v1 2026-06-22T05:58:27.217Z