Beyond the Yield Barrier: Variational Importance Sampling Yield Analysis
Abstract
Optimal mean shift vector (OMSV)-based importance sampling methods have long been prevalent in yield estimation and optimization as an industry standard. However, most OMSV-based methods are designed heuristically without a rigorous understanding of their limitations. To this end, we propose VIS, the first variational analysis framework for yield problems, enabling a systematic refinement for OMSV. For instance, VIS reveals that the classic OMSV is suboptimal, and the optimal/true OMSV should always stay beyond the failure boundary, which enables a free improvement for all OMSV-based methods immediately. Using VIS, we show a progressive refinement for the classic OMSV including incorporation of full covariance in closed form, adjusting for asymmetric failure distributions, and capturing multiple failure regions, each of which contributes to a progressive improvement of more than 2x. Inheriting the simplicity of OMSV, the proposed method retains simplicity and robustness yet achieves up to 29.03x speedup over the state-of-the-art (SOTA) methods. We also demonstrate how the SOTA yield optimization, ASAIS, can immediately benefit from our True OMSV, delivering a 1.20x and 1.27x improvement in performance and efficiency, respectively, without additional computational overhead.
Cite
@article{arxiv.2407.00711,
title = {Beyond the Yield Barrier: Variational Importance Sampling Yield Analysis},
author = {Yanfang Liu and Lei He and Wei W. Xing},
journal= {arXiv preprint arXiv:2407.00711},
year = {2024}
}
Comments
2024 43rd ACM/IEEE International Conference on Computer-Aided Design (ICCAD)