先进的热管理使用近似计算和片上热电冷却

2022 35th SBC/SBMicro/IEEE/ACM Symposium on Integrated Circuits and Systems Design (SBCCI) Pub Date : 2022-08-22 DOI:10.1109/SBCCI55532.2022.9893242

Hammam Kattan, H. Amrouch

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引用次数: 0

摘要

在这项工作中，我们研究了近似计算和片上热电冷却在减轻和管理片上温度方面的有效性。一方面，近似计算在过去十年中作为一种有吸引力的计算范式出现，它提供了在功率和准确性之间的强大权衡。对于深度学习应用程序，计算中的近似可能并不总是导致可观察到的准确性损失。这在很大程度上取决于所执行的深度神经网络模型的灵敏度。另一方面，使用新型超薄膜热电(TE)器件的片上冷却也已成为一种具有吸引力的强大散热手段，以抑制过高的片上功率密度。我们的研究使用商用ANSYS工具流，采用精确的有限元分析(FEA)。这使我们能够准确地研究Peltier效应(用于冷却目的)以及Seebeck效应(用于能量收集目的)，展示了使用热电设备进行片上冷却的前景和有效性。

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Advanced Thermal Management using Approximate Computing and On-Chip Thermoelectric Cooling

In this work, we investigate the effectiveness of approximate computing and on-chip thermoelectric cooling on mitigating and managing the on-chip temperatures. On the first hand, approximate computing has emerged in the last decade as an attractive computing paradigm that offers a powerful trade-off between power and accuracy. For deep learning ap-plications, approximations in computing may not always lead to an observable loss in accuracy. This largely depends on the sensitivity of the executed DNN models. On the other hand, on-chip cooling using novel ultra thin-film Thermoelectric (TE) devices has also emerged as an attractive powerful means for heat dissipation to suppress excessive on-chip power densities. Our investigations are done using commercial ANSYS tool flows that employ accurate Finite Elements Analysis (FEA). This enables us to accurately study the Peltier's effect (for cooling purposes) as well as the Seebeck's effect (for energy harvesting purposes) demonstrating the promise and effectiveness of on-chip cooling using Thermoelectric devices.

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2022 35th SBC/SBMicro/IEEE/ACM Symposium on Integrated Circuits and Systems Design (SBCCI)

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