Thermal analysis and verification of a mounted monolithic integrated circuit

Proceedings of the IEEE SoutheastCon 2010 (SoutheastCon) Pub Date : 2010-03-18 DOI:10.1109/SECON.2010.5453924

T. R. Harris, S. Melamed, S. Luniya, W. R. Davis, M. Steer, L. Doxsee, Kurt Obermiller, Chad Hawkinson

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引用次数: 4

Abstract

As circuit density increases and high-power applications are facilitated, thermal considerations become paramount a design concern. In this paper, a high power monolithic microwave integrated circuit (MMIC) is modeled by the fREEDA multi-physics simulator and measured for validation. While validation is the crux of any simulation model, it is known that thermal measurements accurate to a high resolution are problematic. As such, the thermal profile of integrated circuits cannot be measured directly with infrared thermal imaging due to unequivalent emissivities of materials. It becomes necessary to use an absorptive ink to approximate a blackbody so that the infrared emissions can be used to infer temperature. The impact and effect of this thermal imaging technique is investigated in this work by comparing measurements with detailed thermal simulations with and without the surface treatment. Thermal analysis uses the finite element method and a reduced-order model based on cuboids with effective thermal conductivities. The end goal is to provide a simulation tool to designers, which can be extended to any project which requires attention to thermal preference.

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单片集成电路的热分析与验证

随着电路密度的增加和高功率应用的便利，热考虑成为最重要的设计问题。本文利用fREEDA多物理场模拟器对大功率单片微波集成电路(MMIC)进行了建模，并进行了测量验证。虽然验证是任何模拟模型的关键，但众所周知，精确到高分辨率的热测量是有问题的。因此，由于材料的发射率不相等，不能用红外热成像直接测量集成电路的热分布。有必要使用吸收性墨水来近似黑体，以便利用红外发射来推断温度。通过对比测量结果和表面处理前后详细的热模拟，研究了这种热成像技术的影响和效果。热分析采用有限元法和基于具有有效导热系数的长方体的降阶模型。最终目标是为设计人员提供一个仿真工具，可以扩展到任何需要注意热偏好的项目中。

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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Proceedings of the IEEE SoutheastCon 2010 (SoutheastCon)

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