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A Bionic Visual Perception Optimization Method Adapted to Multiple Signal Intensities Within GIS

A Bionic Visual Perception Optimization Method Adapted to Multiple Signal Intensities Within GIS
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Author(s): Jie Huang (Electric Power Intelligent Sensing Technology Laboratory of State Grid Corporation, China Electric Power Research Institute, China)
 Copyright: 2025
 Volume: 16
 Issue: 1
 Pages: 23
 Source title: International Journal of Mobile Computing and Multimedia Communications (IJMCMC)
Editor(s)-in-Chief: Agustinus Waluyo (Monash University, Australia)
 DOI: 10.4018/IJMCMC.370404

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Abstract

Bionic visual perception technology captures optical signals from gas insulated metal enclosed switchgear (GIS) partial discharge by mimicking the biological visual system, achieving real-time detection and recognition of partial discharge phenomena under complex electromagnetic environments. However, existing technologies often consider only a single spectrum and do not account for differentiated thresholds for various discharge phenomena, affecting imaging accuracy. This paper proposes a multi-spectral bionic visual perception optimization method for GIS. First, a multi-spectral bionic visual perception framework is constructed. Second, an optimization problem is formulated to maximize the average imaging accuracy of all GIS discharge phenomena. Next, a two-stage event-driven deep Q-network (DQN) optimization method is proposed, learning the optimal light intensity change threshold through two-stage closed-loop feedback, including offline and online learning. Finally, the superior performance of the proposed method is validated through simulations.

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