Multi-Fidelity Surrogate-Based Optimization for Electromagnetic Simulation Acceleration

ACM Transactions on Design Automation of Electronic Systems (TODAES) Pub Date : 2020-08-13 DOI:10.1145/3398268

Yi Wang, P. Franzon, D. Smart, Brian Swahn

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引用次数: 6

Abstract

As circuits’ speed and frequency increase, fast and accurate capture of the details of the parasitics in metal structures, such as inductors and clock trees, becomes more critical. However, conducting high-fidelity 3D electromagnetic (EM) simulations within the design loop is very time consuming and computationally expensive. To address this issue, we propose a surrogate-based optimization methodology flow, namely multi-fidelity surrogate-based optimization with candidate search (MFSBO-CS), which integrates the concept of multi-fidelity to reduce the full-wave EM simulation cost in analog/RF simulation-based optimization problems. To do so, a statistical co-kriging model is adapted as the surrogate to model the response surface, and a parallelizable perturbation-based adaptive sampling method is used to find the optima. Within the proposed method, low-fidelity fast RC parasitic extraction tools and high-fidelity full-wave EM solvers are used together to model the target design and then guide the proposed adaptive sample method to achieve the final optimal design parameters. The sampling method in this work not only delivers additional coverage of design space but also helps increase the accuracy of the surrogate model efficiently by updating multiple samples within one iteration. Moreover, a novel modeling technique is developed to further improve the multi-fidelity surrogate model at an acceptable additional computation cost. The effectiveness of the proposed technique is validated by mathematical proofs and numerical test function demonstration. In this article, MFSBO-CS has been applied to two design cases, and the result shows that the proposed methodology offers a cost-efficient solution for analog/RF design problems involving EM simulation. For the two design cases, MFSBO-CS either reaches comparably or outperforms the optimization result from various Bayesian optimization methods with only approximately one- to two-thirds of the computation cost.

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基于多保真度代理的电磁仿真加速优化

随着电路的速度和频率的增加，快速准确地捕捉金属结构(如电感器和时钟树)中寄生的细节变得更加关键。然而，在设计回路中进行高保真三维电磁(EM)模拟非常耗时且计算成本昂贵。为了解决这一问题，我们提出了一种基于代理的优化方法流程，即基于候选搜索的多保真度代理优化(MFSBO-CS)，它集成了多保真度的概念，以降低基于模拟/射频仿真的优化问题中的全波EM仿真成本。为此，采用统计共克里格模型作为代理模型来模拟响应面，并使用基于并行微扰的自适应采样方法来寻找最优解。在该方法中，低保真快速RC寄生提取工具和高保真全波EM求解器一起对目标设计进行建模，然后指导所提出的自适应样本方法获得最终的最优设计参数。本工作中的采样方法不仅提供了额外的设计空间覆盖，而且通过在一次迭代中更新多个样本，有助于有效地提高代理模型的准确性。此外，在可接受的额外计算成本下，开发了一种新的建模技术来进一步改进多保真度代理模型。通过数学证明和数值测试函数演示验证了该方法的有效性。在本文中，MFSBO-CS已应用于两个设计案例，结果表明，所提出的方法为涉及EM仿真的模拟/RF设计问题提供了一种经济高效的解决方案。对于这两种设计情况，MFSBO-CS的计算成本仅为各种贝叶斯优化方法的1 - 2 / 3，达到或超过了这些方法的优化结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ACM Transactions on Design Automation of Electronic Systems (TODAES)

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