Accurate and efficient small-signal modeling of active devices using artificial neural networks

GaAs IC Symposium. IEEE Gallium Arsenide Integrated Circuit Symposium. 20th Annual. Technical Digest 1998 (Cat. No.98CH36260) Pub Date : 1998-11-01 DOI:10.1109/GAAS.1998.722636

P. Watson, M. Weatherspoon, L. Dunleavy, G. Creech

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引用次数: 22

Abstract

Artificial neural networks (ANNs) are presented for the accurate and efficient small-signal modeling of active devices. Models are developed using measured data and are valid over ranges of parameters such as frequency, bias, and ambient temperature. Once generated, these ANN models are inserted into commercial microwave circuit simulators where they can be used for computer-aided design (CAD) and optimization of microwave/MM-wave circuits. Also, the developed ANN models can give physical insight into device behavior and scaling properties when used in conjunction with an equivalent circuit approach. An advantage of the ANN modeling approach is that it provides substantial data storage reduction over previously used modeling techniques without loss of accuracy. With increased model accuracy, the potential of first-pass design success may be realized, resulting in cost savings and decreased time-to-market for new products.

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基于人工神经网络的有源器件精确高效的小信号建模

为了实现有源器件精确、高效的小信号建模，提出了人工神经网络。模型是使用测量数据开发的，并且在频率、偏置和环境温度等参数范围内有效。一旦生成，这些人工神经网络模型被插入商用微波电路模拟器中，在那里它们可以用于计算机辅助设计(CAD)和微波/毫米波电路的优化。此外，当与等效电路方法结合使用时，开发的人工神经网络模型可以提供对设备行为和缩放特性的物理洞察。人工神经网络建模方法的一个优点是，与以前使用的建模技术相比，它提供了大量的数据存储减少，而不会损失准确性。随着模型精度的提高，可能会实现首过设计成功的潜力，从而节省成本并缩短新产品的上市时间。

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GaAs IC Symposium. IEEE Gallium Arsenide Integrated Circuit Symposium. 20th Annual. Technical Digest 1998 (Cat. No.98CH36260)

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