Image Enhanced Mask R-CNN: A Deep Learning Pipeline with New Evaluation Measures for Wind Turbine Blade Defect Detection and Classification

Zhang, Jiajun; Cosma, Georgina; Watkins, J. Foster

doi:10.3390/jimaging7030046

Cited by 35 publications

(11 citation statements)

References 42 publications

(46 reference statements)

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“…e fully connected layer in the VGG16 model needs to be modified on the basis of the VGG16 model. In order to reduce the computational overhead, the number of neurons in the last two fully connected layers is reduced to 512 and 5, and the last fully connected layer corresponds to the five types of weld inspection data: porous, cracked, unfused, unperforated, and defect free [20]. e VGG16 model is first trained on the ImageNet source domain data set to obtain the weight parameters of convolutional layers C1-C4, pooling layers P1-P4, and fully connected layers FC6-FC8.…”

Section: Interdomain Heterogeneous Transfer Learningmentioning

confidence: 99%

Image Defect Recognition Method Based on Deep Learning Network

2022

Mobile Information Systems

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Deep learning techniques are used to identify weld image defects in the process of image defect recognition. In this paper, a transfer learning method based on convolutional neural networks is proposed for the recognition problem of deep neural network models on weld flaw detection image data sets. Designing interdomain heterogeneous transfer learning with the pretrained model on the large data set, the interdomain heterogeneous transfer learning is used to transfer the pretrained model in the source data domain to the weld inspection image data set according to the difference of the content in the source and target data domains, and the effectiveness of the transfer learning in weld inspection image defect recognition is verified by fine-tuning the whole network by training the parameters of different layers using the frozen layer method. The effect of freezing different layers on the recognition performance of the model is also investigated.

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Section: Interdomain Heterogeneous Transfer Learningmentioning

confidence: 99%

Image Defect Recognition Method Based on Deep Learning Network

2022

Mobile Information Systems

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“…Some modifications to the existing one-stage neural network net are also highlighted. The two-stage network model is a more accurate architecture than the one-stage network model; even though R-CNN [16] and R-FCN [21] are faster networks, neither is more accurate or faster than the YOLOv4 model. Both the Faster R-CNN and the R-CNN models can take advantage of a better feature extractor but are less significant with the SSD and DetectNet algorithms.…”

Section: Techniques and Methodsmentioning

confidence: 99%

YOLOv4 Object Detection Model for Nondestructive Radiographic Testing in Aviation Maintenance Tasks

Chen

Juang

2021

AIAA Journal

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“…Tong et al [10] improved the backbone network and feature fusion of Faster R-CNN, thereby enhancing the accuracy of blade damage detection. Zhang et al [11] proposed an image enhancement detection process based on Mask R-CNN, outperforming You Only Look Once version 3 (YOLOv3) and YOLOv4, and introduced new evaluation criteria. Zhang et al [12] developed the Mask-MRNet network for blade fault detection, which improved detection performance by combining Mask R-CNN-512 and MRNet, selecting DenseNet-121 as the optimal classifier.…”

Section: Introductionmentioning

confidence: 99%

WTBD-YOLOv8: An Improved Method for Wind Turbine Generator Defect Detection

Tong,

Fan,

Peng

et al. 2024

Sustainability

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Wind turbine blades are the core components responsible for efficient wind energy conversion and ensuring stability. To address challenges in wind turbine blade damage detection using image processing techniques such as complex image backgrounds, decreased detection performance due to high image resolution, prolonged inference time, and insufficient recognition accuracy, this study introduces an enhanced wind turbine blade damage detection model named WTDB-YOLOv8. Firstly, by incorporating the GhostCBS and DFSB-C2f modules, the aim is to reduce the number of model parameters while enhancing feature extraction capability. Secondly, by integrating the MHSA-C2f module, which incorporates a multi-head self-attention mechanism, the focus on global information is enabled, thereby mitigating irrelevant background interference and reducing the impact of complex backgrounds on damage detection. Lastly, adopting the Mini-BiFPN structure improves the retention of features for small target objects in shallow networks and reinforces the propagation of these features in deep networks, thereby enhancing the detection accuracy of small target damage and reducing false negative rates. Through training and testing on the Wind Turbine Blade Damage Dataset (WTBDD), the WTDB-YOLOv8 model achieves an average precision of 98.3%, representing a 2.2 percentage point improvement over the original YOLOv8 model. Particularly noteworthy is the increase in precision from 93.1% to 97.9% in small target damage detection. Moreover, the total parameter count of the model decreases from 3.22 million in YOLOv8 to 1.99 million, marking a reduction of 38.2%. Therefore, the WTDB-YOLOv8 model not only enhances the detection performance and efficiency of wind turbine blade damage but also significantly reduces the model parameter count, showcasing its practical advantages in engineering applications.

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Image Enhanced Mask R-CNN: A Deep Learning Pipeline with New Evaluation Measures for Wind Turbine Blade Defect Detection and Classification

Cited by 35 publications

References 42 publications

Image Defect Recognition Method Based on Deep Learning Network

Image Defect Recognition Method Based on Deep Learning Network

YOLOv4 Object Detection Model for Nondestructive Radiographic Testing in Aviation Maintenance Tasks

WTBD-YOLOv8: An Improved Method for Wind Turbine Generator Defect Detection

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