A Big-Data Approach to Handle Process Variations: Uncertainty Quantification by Tensor Recovery
Abstract
Stochastic spectral methods have become a popular technique to quantify the uncertainties of nano-scale devices and circuits. They are much more efficient than Monte Carlo for certain design cases with a small number of random parameters. However, their computational cost significantly increases as the number of random parameters increases. This paper presents a big-data approach to solve high-dimensional uncertainty quantification problems. Specifically, we simulate integrated circuits and MEMS at only a small number of quadrature samples, then, a huge number of (e.g., ) solution samples are estimated from the available small-size (e.g., ) solution samples via a low-rank and tensor-recovery method. Numerical results show that our algorithm can easily extend the applicability of tensor-product stochastic collocation to IC and MEMS problems with over 50 random parameters, whereas the traditional algorithm can only handle several random parameters.
Cite
@article{arxiv.1603.06119,
title = {A Big-Data Approach to Handle Process Variations: Uncertainty Quantification by Tensor Recovery},
author = {Zheng Zhang and Tsui-Wei Weng and Luca Daniel},
journal= {arXiv preprint arXiv:1603.06119},
year = {2016}
}
Comments
2016 IEEE 20th Workshop on Signal and Power Integrity (SPI), 8-11 May 2016, Turin, Italy