GaAs射频器件的多尺度热分析

Semiconductor Thermal Measurement and Management IEEE Twenty First Annual IEEE Symposium, 2005. Pub Date : 2005-03-15 DOI:10.1109/STHERM.2005.1412189

L. Li, R. Coccioli, K. Nary, P. Canfield

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引用次数: 15

摘要

提出了一种多尺度建模方法，并应用于研究GaAs MMIC中的热问题。热分析下降到信号晶体管水平是有可能的发展，这种方法使用有限元技术。然后利用红外测温技术(红外微热成像技术)对多尺度建模结果进行验证。模型和实验结果都表明，由于其固有的低导热性，GaAs MMIC芯片的自热非常局限于FET栅极手指周围，特别是集中在GaAs射频器件的输出级内。封装和系统级的热管理解决方案需要将芯片工作温度保持在器件的最大允许通道温度以下。讨论了多尺度热建模的步骤和影响GaAs MMIC热特性的参数。

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Multi-scale thermal analysis of GaAs RF device

A multi-scale modeling approach is proposed and employed to investigate thermal issues in GaAs MMIC. Thermal analysis down to the signal transistor level was made possible with the development of this approach using the finite element technique. The multi-scale modeling results are then verified with an infrared temperature measurement technique (infrared micro-thermal imaging technique). Both modeling and experiment results have shown that due to its intrinsic low thermal conductivity, self-heating of the GaAs MMIC chip is very localized around the FET gate fingers especially concentrated within the output stage of the GaAs RF device. Thermal management solutions at both the package and system level are needed to keep chip operating temperature under the maximum allowable channel temperature of the device. Steps involved with the multi-scale thermal modeling and parameters affecting thermal characteristics of GaAs MMIC are also discussed.

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来源期刊

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

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