A Review on Defect Detection of Electroluminescence-Based Photovoltaic Cell Surface Images Using Computer Vision

Abstract: The past two decades have seen an increase in the deployment of photovoltaic installations as nations around the world try to play their part in dampening the impacts of global warming. The manufacturing of solar cells can be defined as a rigorous process starting with silicon extraction. The increase in demand has multiple implications for manual quality inspection. With automated inspection as the ultimate goal, researchers are actively experimenting with convolutional neural network architectures. This revi… Show more

“…Along with open-source deep learning software frameworks (TensorFlow 2.6.2 [14] and PyTorch 2.0.0 [15]), an explosion in the availability of high-performance computing infrastructures (especially GPUs [16]), new network architectures [17], and training techniques [18] means that neural networks can be trained much deeper. The latest advances in deep learning techniques based on convolutional neural networks have led to significant progress in object localization and recognition under natural conditions, such as regions with convolutional neural network (R-CNN) features [19], spatial pyramid pooling networks [20], fast region convolutional neural networks [21], faster region CNN [22], single shot multibox detectors [23], you only look once [24], region-based fully convolutional networks (FCN) [25], and other extended variants of networks [26,27]. For example, an intelligent algorithm utilizing both a high-resolution network (HRNet) and self-fusion network (SeFNet) for automatic defect identification of PV modules using EL images has been proposed, demonstrating enhanced feature fusion and classification accuracy for superior defect recognition performance [28].…”

Automatic Classification of Defective Solar Panels in Electroluminescence Images Based on Random Connection Network

“…Along with open-source deep learning software frameworks (TensorFlow 2.6.2 [14] and PyTorch 2.0.0 [15]), an explosion in the availability of high-performance computing infrastructures (especially GPUs [16]), new network architectures [17], and training techniques [18] means that neural networks can be trained much deeper. The latest advances in deep learning techniques based on convolutional neural networks have led to significant progress in object localization and recognition under natural conditions, such as regions with convolutional neural network (R-CNN) features [19], spatial pyramid pooling networks [20], fast region convolutional neural networks [21], faster region CNN [22], single shot multibox detectors [23], you only look once [24], region-based fully convolutional networks (FCN) [25], and other extended variants of networks [26,27]. For example, an intelligent algorithm utilizing both a high-resolution network (HRNet) and self-fusion network (SeFNet) for automatic defect identification of PV modules using EL images has been proposed, demonstrating enhanced feature fusion and classification accuracy for superior defect recognition performance [28].…”

Automatic Classification of Defective Solar Panels in Electroluminescence Images Based on Random Connection Network

Variant Histogram Equalization-Based Enhancement to Deep Transfer Learning for Automatic Detection of Photovoltaic Cell Defects in Electroluminescence Images

Enhancing photovoltaic cell classification through mamdani fuzzy logic: a comparative study with machine learning approaches employing electroluminescence images