Phasor-based analysis of a neuromorphic architecture for microwave sensing

This article presents a design procedure for implementing artificial neural networks (ANNs) using conventional microwave components at the hardware level with potential applications in radar and remote sensing. The main objective is to develop structured hardware design methods for implementing arti...

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Bibliographic Details
Published in:Scientific reports 2024-07, Vol.14 (1), p.15590-12, Article 15590
Main Authors: Soleimani, Ashkan, Forooraghi, Keyvan, Atlasbaf, Zahra
Format: Article
Language:English
Subjects:
639/166/987
639/705/1042
639/766/930/1032
Electromagnetic radiation
Frequency dependence
Humanities and Social Sciences
Information processing
Microwave radiation
multidisciplinary
Neural networks
Principal components analysis
Remote sensing
Science
Science (multidisciplinary)
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Summary:This article presents a design procedure for implementing artificial neural networks (ANNs) using conventional microwave components at the hardware level with potential applications in radar and remote sensing. The main objective is to develop structured hardware design methods for implementing artificial neurons, utilizing microwave devices to create neuromorphic devices compatible with high-frequency electromagnetic waves. The research aims to address the challenge of encoding and modulating information in electromagnetic waves into a format suitable for the neuromorphic device by using frequency-modulated information instead of intensity-modulated information. It also proposes a method for integrating principal component analysis as a dimensionality reduction technique with the implementation of ANNs on a single hardware. As a dummy task, the process outlined here is used to implement an artificial neural network at the hardware level, with a specific emphasis on creating hardware that is capable of performing matrix multiplications in the form of dot products while also being able to extract the resulting data in an interpretable manner. The proposed implementation involves the use of directional couplers to implement weights and sample the resulting signal at specific intervals to obtain the multiplication result.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-024-66156-0