Machine Learning Based Damage Detection in Photovoltaic Arrays Using UAV-Acquired Infrared and Visual Imagery

The rapid global expansion of solar panel installations necessitates more efficient and cost-effective methods for performance monitoring and maintenance. The New England Solar Project, Australia's largest solar installation is a prime example of the scale and complexity of modern solar farms,...

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Published in	Conference proceedings (International Conference on Unmanned Aircraft Systems. Online) pp. 264 - 271
Main Authors	Barrett, Aidan, Bratanov, Dmitry, Amarasingam, Narmilan, Sera, Dezso, Gonzalez, Felipe
Format	Conference Proceeding
Language	English
Published	IEEE 04.06.2024
Subjects	Australia deep learning drone Maintenance Manuals Pipelines PVarray imaging solar energy solar panel Solar panels Training Visualization
Online Access	Get full text
ISSN	2575-7296
DOI	10.1109/ICUAS60882.2024.10556847

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Abstract	The rapid global expansion of solar panel installations necessitates more efficient and cost-effective methods for performance monitoring and maintenance. The New England Solar Project, Australia's largest solar installation is a prime example of the scale and complexity of modern solar farms, making it increasingly challenging to rely solely on manual ground-based inspections. This paper addresses the challenge by focusing on the integration of unmanned aerial systems (UAS) based imagery and deep learning (DL) techniques to develop a semi-automated pipeline for accurately identifying and classifying photovoltaic (PV) cell surface damage. The study leverages the YOLOv8 and Faster R-CNN models to achieve this goal. Drone based visual and infrared spectrum imagery collected from a solar installation site in Queensland, Australia, during October 2022 form the basis of the dataset, enabling the training and evaluation of these models. Three distinct damage classifications (Single-Cell, Multi-Cell, and Surface-Anomaly) were established with input from a subject matter expert to ensure accurate categorization of damage types. The research results indicate promising outcomes for classifying the distinct damage classes. The YOLOv8s-seg model achieved a mean average precision (mAP) of 87% to segment the solar panels. The YOLOv8m model, trained with a relatively small dataset, achieved a commendable mAP of 76% for solar panel damage detection. The Faster R-CNN model showed potential in detecting damage with high confidence, although a more comprehensive evaluation is needed. This research contributes to the broader goal of enhancing preventive maintenance practices, thereby reducing damage-related losses, and ensuring the long-term sustainability of solar installations.
AbstractList	The rapid global expansion of solar panel installations necessitates more efficient and cost-effective methods for performance monitoring and maintenance. The New England Solar Project, Australia's largest solar installation is a prime example of the scale and complexity of modern solar farms, making it increasingly challenging to rely solely on manual ground-based inspections. This paper addresses the challenge by focusing on the integration of unmanned aerial systems (UAS) based imagery and deep learning (DL) techniques to develop a semi-automated pipeline for accurately identifying and classifying photovoltaic (PV) cell surface damage. The study leverages the YOLOv8 and Faster R-CNN models to achieve this goal. Drone based visual and infrared spectrum imagery collected from a solar installation site in Queensland, Australia, during October 2022 form the basis of the dataset, enabling the training and evaluation of these models. Three distinct damage classifications (Single-Cell, Multi-Cell, and Surface-Anomaly) were established with input from a subject matter expert to ensure accurate categorization of damage types. The research results indicate promising outcomes for classifying the distinct damage classes. The YOLOv8s-seg model achieved a mean average precision (mAP) of 87% to segment the solar panels. The YOLOv8m model, trained with a relatively small dataset, achieved a commendable mAP of 76% for solar panel damage detection. The Faster R-CNN model showed potential in detecting damage with high confidence, although a more comprehensive evaluation is needed. This research contributes to the broader goal of enhancing preventive maintenance practices, thereby reducing damage-related losses, and ensuring the long-term sustainability of solar installations.
Author	Bratanov, Dmitry Barrett, Aidan Amarasingam, Narmilan Sera, Dezso Gonzalez, Felipe
Author_xml	– sequence: 1 givenname: Aidan surname: Barrett fullname: Barrett, Aidan organization: School of Electrical Engineering & Robotics, Queensland University of Technology,Brisbane,Australia – sequence: 2 givenname: Dmitry surname: Bratanov fullname: Bratanov, Dmitry organization: Queensland University of Technology,Research Engineering Facility,Brisbane,Australia – sequence: 3 givenname: Narmilan surname: Amarasingam fullname: Amarasingam, Narmilan organization: School of Electrical Engineering & Robotics, Queensland University of Technology,Brisbane,Australia – sequence: 4 givenname: Dezso surname: Sera fullname: Sera, Dezso organization: School of Electrical Engineering & Robotics, Queensland University of Technology,Brisbane,Australia – sequence: 5 givenname: Felipe surname: Gonzalez fullname: Gonzalez, Felipe organization: School of Electrical Engineering & Robotics, Queensland University of Technology,Brisbane,Australia
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Snippet	The rapid global expansion of solar panel installations necessitates more efficient and cost-effective methods for performance monitoring and maintenance. The...
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SubjectTerms	Australia deep learning drone Maintenance Manuals Pipelines PVarray imaging solar energy solar panel Solar panels Training Visualization
Title	Machine Learning Based Damage Detection in Photovoltaic Arrays Using UAV-Acquired Infrared and Visual Imagery
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