Lakshmi Narayana Thalluri, Aravind Kumar Madam, Kota Venkateswara Rao, Ch V. Ravi Sankar, Koushik Guha, Jacopo Iannacci, Massimo Donelli, Debashis Dev Misra
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引用次数: 0
摘要
人工神经网络(ANN)在微型射频设备的优化中正变得非常突出,而微型射频设备在无线通信应用中意义重大。在本手稿中,我们介绍了使用 ANN 对射频 MEMS 开关进行优化,以及具有频率可重构性的天线设计。我们提出了一种独特的程序,利用方差网络设计带有射频 MEMS 开关的可重构天线。这项工作的新颖之处在于通过有限元工具仿真为所考虑的射频 MEMS 开关创建专用数据集,并利用级联前馈神经网络进行优化。数据集的设计和使用神经网络对射频 MEMS 开关进行不同方面的优化是这项工作的主要贡献。使用神经网络对设计的数据集进行了综合分析。与其他神经网络相比,级联前馈神经网络具有很高的效率。网络的权重和偏置是通过 Xavier 方法选择的。使用 LM 训练算法对级联前馈神经网络进行优化。优化后的级联前馈神经网络进一步用于预测所需应用的优化射频 MEMS 开关尺寸。该网络的准确率达到 94.9%。根据级联前馈神经网络预测的尺寸,设计出了射频 MEMS 开关。所设计的开关具有 - 55 dB 隔离度和 - 0.2 dB 插入度。最后,还设计出了一种天线,将具有频率可重构性的相同开关结合在一起。
RF MEMS switch optimization using ANN and design of antenna with frequency reconfigurability
Artificial neural networks (ANN) are becoming highly prominent in the optimization of micro-RF devices, which are very significant in wireless communication applications. In this manuscript, we present the optimization of RF MEMS switches using ANN and the design of an antenna with frequency reconfigurability. A unique procedure is proposed to design reconfigurable antennas with RF MEMS switches using ANN. The novelty of this work lies in the creation of a dedicated dataset for the considered RF MEMS switch with FEM tool simulation and the utilization of cascade feed-forward neural networks for optimization. The design of the dataset and the optimization of RF MEMS switches in different aspects using ANN are the key contributions of this work. Comprehensive analysis was performed using a neural network with the designed dataset. Cascade feed-forward neural networks are highly efficient when compared with other neural networks. The weights and biases of the network were selected using the Xavier approach. The cascade feed-forward neural network is optimized using the LM training algorithm. The optimized cascade feed-forward neural network is further used to predict the optimized RF MEMS switch dimensions for the desired application. The network produces an accuracy of 94.9%. An RF MEMS switch was designed from the dimensions predicted by the cascade feed-forward neural network. The designed switch offers – 55 dB Isolation and – 0.2 dB Insertion. Eventually, an antenna was designed by incorporating identical switches which offer frequency reconfigurability.