Automated Sewer Defects Detection Using Style-Based Generative Adversarial Networks and Fine-Tuned Well-Known CNN Classifier

Situ, Zuxiang; Chen, Gongfa; Liu, Hanlin; Luo, Jin; Zhou, Qianqian

doi:10.1109/access.2021.3073915

Cited by 18 publications

(14 citation statements)

References 45 publications

(84 reference statements)

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“…Using the Sewer-ML dataset Haurum and Moeslund showed that the sewer defect classification tasks are far from solved, comparing the leading sewer defect classification methods from Kumar et al [18], Meijer et al [19], Xie et al [20], Chen et al [21], Hassan et al [22], and Myrans et al [23]. Concurrent research directions in the sewer defect classification subfield have focused on the usage of StyleGAN-based approaches to increase the effective size of small training dataset [24,25], developing and deploying networks on embedded devices [26,27], and providing defect localization information without explicit localization labels [28,29].…”

Section: Automated Sewer Inspectionsmentioning

confidence: 99%

“…Recently, the field has also started investigating other parts of the sewer inspection process [30,32,17,[37][38][39][40][41], such as Haurum et al [37] proposing a multi-task classification approach for simultaneously classifying defects, water level, pipe material, and pipe shape, and Wang et al [30] proposed a framework to accurately determine the severity of defects related to the operation and maintenance of the pipes. The field has also adopted recent trends from the general computer vision field such as selfsupervised learning [39], synthetic data generation [25,24,[42][43][44], neural architecture search [45], and usage of the Transformer architecture [17,46], indicating that the automated sewer inspection field is catching up to the general computer vision domain.…”

Section: Automated Sewer Inspectionsmentioning

confidence: 99%

See 1 more Smart Citation

Multi-scale hybrid vision transformer and Sinkhorn tokenizer for sewer defect classification

Haurum

Madadi

Escalera

et al. 2022

Automation in Construction

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Section: Automated Sewer Inspectionsmentioning

confidence: 99%

Section: Automated Sewer Inspectionsmentioning

confidence: 99%

Multi-scale hybrid vision transformer and Sinkhorn tokenizer for sewer defect classification

Haurum

Madadi

Escalera

et al. 2022

Automation in Construction

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“…Recent studies have shown that GANs, especially StyleGAN2, 24 are highly effective in producing synthetic data for defect detection tasks. 25,26 Our research also leverages StyleGAN2 to create synthetic defects superimposed on real background images. These images are then used to train an inspection network.…”

Section: Introductionmentioning

confidence: 99%

Enhancing titanium spacer defect detection through reinforcement learning-optimized digital twin and synthetic data generation

Mohanty,

Su,

2024

J. Electron. Imag.

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In the field of automatic defect detection, a major challenge in training accurate classifiers using supervised learning is the insufficient and limited diversity of datasets. Obtaining an adequate amount of image data depicting defective surfaces in an industrial setting can be costly and time-consuming. Furthermore, the collected dataset may suffer from selection bias, resulting in an underrepresentation of certain defect classes. Our research aims to address surface defect detection in titanium metal spacer rings by introducing an approach leveraging a digital twin framework. The behavior of the digital twin is optimized using a reinforcement learning (RL) algorithm. The optimized digital twin is then used to generate synthetic data, which is employed to train a spacer defect detection classifier. The classifier's performance is evaluated using real-world data. The results show that the model trained with synthetic data outperforms the one trained on a limited amount of real data. Our work highlights the potential of digital twin-based synthetic data generation and RL optimization in enhancing spacer surface defect detection and addressing the data scarcity challenge in the field. When the inspection network is trained solely using generated synthetic data, it achieves an inspection precision of 96.10%, with a recall of 85.77%. Incorporating real data alongside synthetic data for training further enhances performance, yielding an inspection precision of 93.07% and a recall of 94.20%. This surpasses the defect detection capabilities observed when training the inspection network exclusively with real data.

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“…The classic GAN model has evolved into various forms and architectures, such as DCGAN [ 13 , 14 , 15 , 16 ], Pix2Pix [ 17 , 18 , 19 ], CycleGAN [ 20 , 21 , 22 ], and StyleGAN [ 23 , 24 , 25 , 26 , 27 , 28 ]. There have been several attempts to generate surface defects using these models.…”

Section: Introductionmentioning

confidence: 99%

“…Lastly, StyleGAN includes mixing regularization by using two random latent codes to generate a given percentage of images, allowing the model to localize the style to specific image regions. Situ et al [ 26 ] integrated the StyleGAN model with adaptive discriminator augmentation (ADA) to generate synthetic images of surface defects on water sewers. The model was capable of generating high-resolution images.…”

Section: Introductionmentioning

confidence: 99%

Image Generation and Recognition for Railway Surface Defect Detection

Xia

Han

Kwon

2023

Sensors

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Railway defects can result in substantial economic and human losses. Among all defects, surface defects are the most common and prominent type, and various optical-based non-destructive testing (NDT) methods have been employed to detect them. In NDT, reliable and accurate interpretation of test data is vital for effective defect detection. Among the many sources of errors, human errors are the most unpredictable and frequent. Artificial intelligence (AI) has the potential to address this challenge; however, the lack of sufficient railway images with diverse types of defects is the major obstacle to training the AI models through supervised learning. To overcome this obstacle, this research proposes the RailGAN model, which enhances the basic CycleGAN model by introducing a pre-sampling stage for railway tracks. Two pre-sampling techniques are tested for the RailGAN model: image-filtration, and U-Net. By applying both techniques to 20 real-time railway images, it is demonstrated that U-Net produces more consistent results in image segmentation across all images and is less affected by the pixel intensity values of the railway track. Comparison of the RailGAN model with U-Net and the original CycleGAN model on real-time railway images reveals that the original CycleGAN model generates defects in the irrelevant background, while the RailGAN model produces synthetic defect patterns exclusively on the railway surface. The artificial images generated by the RailGAN model closely resemble real cracks on railway tracks and are suitable for training neural-network-based defect identification algorithms. The effectiveness of the RailGAN model can be evaluated by training a defect identification algorithm with the generated dataset and applying it to real defect images. The proposed RailGAN model has the potential to improve the accuracy of NDT for railway defects, which can ultimately lead to increased safety and reduced economic losses. The method is currently performed offline, but further study is planned to achieve real-time defect detection in the future.

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Automated Sewer Defects Detection Using Style-Based Generative Adversarial Networks and Fine-Tuned Well-Known CNN Classifier

Cited by 18 publications

References 45 publications

Multi-scale hybrid vision transformer and Sinkhorn tokenizer for sewer defect classification

Multi-scale hybrid vision transformer and Sinkhorn tokenizer for sewer defect classification

Enhancing titanium spacer defect detection through reinforcement learning-optimized digital twin and synthetic data generation

Image Generation and Recognition for Railway Surface Defect Detection

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