Trans-DCN: A High-Efficiency and Adaptive Deep Network for Bridge Cable Surface Defect Segmentation

• Published in: Remote sensing (Basel, Switzerland) Vol. 16; no. 15; p. 2711
• Main Authors: Huang, Zhihai, Guo, Bo, Deng, Xiaolong, Guo, Wenchao, Min, Xing
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.08.2024
• Subjects: Ablation; Algorithms; Analysis; Artificial intelligence; bridge cable surface defects; Bridges; Cable networks (Television); Cable-stayed bridges; Cables; Climbing; Computational linguistics; Corrosion and anti-corrosives; Deep learning; defect segmentation; Defects; Deformation effects; Effectiveness; Embedded systems; Formability; Image analysis; Image processing; Image segmentation; Language processing; Learning strategies; Lighting; Load bearing components; Load bearing elements; Natural language interfaces; Neural networks; non-destructive cable health assessment; Robots; Segmentation; State-of-the-art reviews; Surface defects; Surface stability; Unmanned aerial vehicles; China; Germany
• ISSN: 2072-4292; 2072-4292
• DOI: 10.3390/rs16152711

Cables are vital load-bearing components of cable-stayed bridges. Surface defects can lead to internal corrosion and fracturing, significantly impacting the stability of the bridge structure. The detection of surface defects from bridge cable images faces numerous challenges, including shadow disturbances due to uneven lighting and difficulties in addressing multiscale defect features. To address these challenges, this paper proposes a novel and cost-effective deep learning segmentation network, named Trans-DCN, to detect defects in the surface of the bridge cable. The network leverages an efficient Transformer-based encoder and integrates multiscale features to overcome the limitations associated with local feature inadequacy. The decoder implements an atrous Deformable Convolution (DCN) pyramid and dynamically fuses low-level feature information to perceive the complex distribution of defects. The effectiveness of Trans-DCN is evaluated by comparing it with state-of-the-art segmentation baseline models using a dataset comprising cable bridge defect images. Experimental results demonstrate that our network outperforms the state-of-the-art network SegFormer, achieving a 27.1% reduction in GFLOPs, a 1.2% increase in mean Intersection over Union, and a 1.5% increase in the F1 score. Ablation experiments confirmed the effectiveness of each module within our network, further substantiating the significant validity and advantages of Trans-DCN in the task of bridge cable defect segmentation. The network proposed in this paper provides an effective solution for downstream cable bridge image analysis.