基于层次可逆神经传递网络的嵌入式电感器反设计

2022 IEEE 31st Conference on Electrical Performance of Electronic Packaging and Systems (EPEPS) Pub Date : 2022-10-09 DOI:10.1109/EPEPS53828.2022.9947131

O. Akinwande, O. W. Bhatti, Madhavan Swaminathan

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引用次数: 1

摘要

配电网络中稳压器的异构集成是一个日益发展的趋势，采用嵌入式电感器作为关键部件显著改善配电。在这项工作中，我们提出了一种称为分层可逆神经传递的神经网络框架，用于嵌入式电感器的逆向设计。利用这种可逆方法，我们得到了最可能满足期望规格的嵌入式电感器设计空间参数的概率分布。在正向设计中，我们还免费学习了阻抗响应。在正向设计中，与全波电磁模拟器的输出响应相比，我们的结果显示归一化均方误差为2.14%。

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Inverse Design of Embedded Inductor with Hierarchical Invertible Neural Transport Net

Heterogeneous integration of voltage regulators in power delivery networks is a growing trend that employs em-bedded inductor as a key component in significantly improving the power distribution. In this work, we propose a neural network framework called the hierarchical invertible neural transport for the inverse design of an embedded inductor. With this invertible method, we obtain the probability distributions of the parameters of the embedded inductor design space that most likely satisfy the desired specifications. We also learn the impedance response for free in the forward design. In the forward design, our results show a 2.14% normalized mean square error when compared with the output response of a full wave EM simulator.

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2022 IEEE 31st Conference on Electrical Performance of Electronic Packaging and Systems (EPEPS)

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