Open Access

ARTICLE

Hybrid CNN Architecture for Hot Spot Detection in Photovoltaic Panels Using Fast R-CNN and GoogleNet

Carlos Quiterio Gómez Muñoz¹, Fausto Pedro García Márquez^2,*, Jorge Bernabé Sanjuán³

1 HCTLab Research Group, Electronics and Communications Technology Department, Universidad Autónoma de Madrid, Madrid, 28049, Spain
2 Ingenium Research Group, Universidad de Castilla-La Mancha, Ciudad Real, 13071, Spain
3 Department of Engineering, School of Architecture, Engineering and Design, Universidad Europea de Madrid, Villaviciosa de Odon, 28670, Spain

* Corresponding Author: Fausto Pedro García Márquez. Email:

(This article belongs to the Special Issue: Advanced Data Analysis Techniques in Renewable Energy)

Computer Modeling in Engineering & Sciences 2025, 144(3), 3369-3386. https://doi.org/10.32604/cmes.2025.069225

Received 18 June 2025; Accepted 11 August 2025; Issue published 30 September 2025

Abstract

Due to the continuous increase in global energy demand, photovoltaic solar energy generation and associated maintenance requirements have significantly expanded. One critical maintenance challenge in photovoltaic installations is detecting hot spots, localized overheating defects in solar cells that drastically reduce efficiency and can lead to permanent damage. Traditional methods for detecting these defects rely on manual inspections using thermal imaging, which are costly, labor-intensive, and impractical for large-scale installations. This research introduces an automated hybrid system based on two specialized convolutional neural networks deployed in a cascaded architecture. The first convolutional neural network efficiently detects and isolates individual solar panels from high-resolution aerial thermal images captured by drones. Subsequently, a second, more advanced convolutional neural network accurately classifies each isolated panel as either defective or healthy, effectively distinguishing genuine thermal anomalies from false positives caused by reflections or glare. Experimental validation on a real-world dataset comprising thousands of thermal images yielded exceptional accuracy, significantly reducing inspection time, costs, and the likelihood of false defect detections. This proposed system enhances the reliability and efficiency of photovoltaic plant inspections, thus contributing to improved operational performance and economic viability.

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