单片和堆叠结构的热瞬态表征方法

Semiconductor Thermal Measurement and Management IEEE Twenty First Annual IEEE Symposium, 2005. Pub Date : 2005-03-15 DOI:10.1109/STHERM.2005.1412198

O. Steffens, P. Szabó, M. Lenz, G. Farkas

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引用次数: 55

摘要

高功率半导体封装通常表现出3D热流，导致芯片和外壳表面温度的巨大横向变化。对于单芯片器件，我们建议使用结壳热阻的明确定义作为关键参数，该定义基于具有更高可重复性的瞬态测量技术，并且与两点热阻测量相比，也适用于非常低的热阻。以功率mosfet的热瞬态测量为例说明了该技术的应用。不同的热耦合环境之间的比较被用来证明该方法的能力，甚至揭示了微妙的内部细节的封装。这个概念被扩展到多芯片和堆叠芯片结构，在这些结构中必须引入传输阻抗。在这里，封装的动态特性是重要的，复杂的阻抗映射是表征封装的合适方法。

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Thermal transient characterization methodology for single-chip and stacked structures

High-power semiconductor packages typically exhibit a 3D heat flow, resulting in large lateral changes in chip and case surface temperature. For single-chip devices we propose to use an unambiguous definition for the junction-to-case thermal resistance as a key parameter, based on a transient measurement technique with much higher repeatability, also for very low thermal resistances compared to a two-point thermal resistance measurement. The technique is illustrated on thermal transient measurements of power MOSFETs. A comparison between different thermal coupling to the ambient is used to demonstrate the method's capability to reveal even subtle internal details of the package. The concept is extended to multichip and stacked-chip structures, where transfer impedances have to be introduced. Here, the dynamic properties of the package are important and complex impedance mapping is the proper way to characterize the package.

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Semiconductor Thermal Measurement and Management IEEE Twenty First Annual IEEE Symposium, 2005.

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