PowerSynth-Guided Reliability Optimization of Multi-Chip Power Module

2021 IEEE Applied Power Electronics Conference and Exposition (APEC) Pub Date : 2021-06-14 DOI:10.1109/APEC42165.2021.9487161

Imam Al Razi, D. Huitink, Yarui Peng

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引用次数: 3

Abstract

High-performance Multi-Chip Power Modules (MCPMs) are essential for high-density and efficient power conversion. Meanwhile, the chip layout and design methodology fundamentally determine thermal and reliability performance. Hign-density power modules typically consist of wide-bandgap (WBG) semiconductor die, soldering materials, baseplate, and heatsink packed on a single substrate. To a great extent, the reliability of power modules depends on these material electrothermal-mechanical properties during variable operating conditions. Appropriate thermal management can reduce stress and enhance the component lifetime by controlling junction temperature. In this work, a fast, generic, and scalable transient thermal model has been developed for the PowerSynth layout synthesis tool to optimize layer material, thickness, and layer stack configurations by minimizing thermal stress due to thermal cycling. This model has shown approximately 3,489 times speed up with less than 10% mismatch compared to ANSYS simulation. A PowerSynth-guided design-for-reliability computer-aided design (CAD) flow is presented to optimize both the layer stack and the layout simultaneously.

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基于powersynth的多芯片电源模块可靠性优化

高性能多芯片电源模块(mcpm)是实现高密度、高效的电源转换必不可少的器件。同时，芯片布局和设计方法从根本上决定了散热和可靠性性能。高密度功率模块通常由宽带隙(WBG)半导体芯片、焊接材料、基板和封装在单一基板上的散热器组成。在很大程度上，电源模块的可靠性取决于这些材料在可变工作条件下的电热机械性能。适当的热管理可以通过控制结温来减少应力和提高元件寿命。在这项工作中，为PowerSynth布局合成工具开发了一个快速、通用、可扩展的瞬态热模型，通过最小化热循环引起的热应力来优化层材料、厚度和层堆叠配置。与ANSYS仿真相比，该模型的速度提高了约3489倍，误差小于10%。提出了一种以powersynth为指导的可靠性设计计算机辅助设计(CAD)流程，以同时优化层栈和布局。

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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2021 IEEE Applied Power Electronics Conference and Exposition (APEC)

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