Logo
ScienceStack
Table of Contents
Fetching ...
Sign In

Topology-aware Mamba for Crack Segmentation in Structures

Xin Zuo, Yu Sheng, Jifeng Shen, Yongwei Shan

TL;DR

Experiments show that CrackMamba achieves state-of-the-art (SOTA) performance on the CrackSeg9k and SewerCrack datasets, and demonstrates competitive performance on the retinal vessel segmentation dataset CHASE\underline{~}DB1, highlighting its generalization capability.

Abstract

CrackMamba, a Mamba-based model, is designed for efficient and accurate crack segmentation for monitoring the structural health of infrastructure. Traditional Convolutional Neural Network (CNN) models struggle with limited receptive fields, and while Vision Transformers (ViT) improve segmentation accuracy, they are computationally intensive. CrackMamba addresses these challenges by utilizing the VMambaV2 with pre-trained ImageNet-1k weights as the encoder and a newly designed decoder for better performance. To handle the random and complex nature of crack development, a Snake Scan module is proposed to reshape crack feature sequences, enhancing feature extraction. Additionally, the three-branch Snake Conv VSS (SCVSS) block is proposed to target cracks more effectively. Experiments show that CrackMamba achieves state-of-the-art (SOTA) performance on the CrackSeg9k and SewerCrack datasets, and demonstrates competitive performance on the retinal vessel segmentation dataset CHASE\underline{~}DB1, highlighting its generalization capability. The code is publicly available at: {https://github.com/shengyu27/CrackMamba.}

Topology-aware Mamba for Crack Segmentation in Structures

TL;DR

Experiments show that CrackMamba achieves state-of-the-art (SOTA) performance on the CrackSeg9k and SewerCrack datasets, and demonstrates competitive performance on the retinal vessel segmentation dataset CHASE\underline{~}DB1, highlighting its generalization capability.

Abstract

CrackMamba, a Mamba-based model, is designed for efficient and accurate crack segmentation for monitoring the structural health of infrastructure. Traditional Convolutional Neural Network (CNN) models struggle with limited receptive fields, and while Vision Transformers (ViT) improve segmentation accuracy, they are computationally intensive. CrackMamba addresses these challenges by utilizing the VMambaV2 with pre-trained ImageNet-1k weights as the encoder and a newly designed decoder for better performance. To handle the random and complex nature of crack development, a Snake Scan module is proposed to reshape crack feature sequences, enhancing feature extraction. Additionally, the three-branch Snake Conv VSS (SCVSS) block is proposed to target cracks more effectively. Experiments show that CrackMamba achieves state-of-the-art (SOTA) performance on the CrackSeg9k and SewerCrack datasets, and demonstrates competitive performance on the retinal vessel segmentation dataset CHASE\underline{~}DB1, highlighting its generalization capability. The code is publicly available at: {https://github.com/shengyu27/CrackMamba.}

Paper Structure

This paper contains 27 sections, 8 equations, 9 figures, 5 tables.

Table of Contents

  1. Introduction
  2. Preliminaries
  3. State space models
  4. Selective state space models
  5. Method
  6. 2D-Snake-Scan
  7. Encoder
  8. SnakeVSS block
  9. Spatial and Channel Attention
  10. Decoder
  11. Experiment
  12. Dataset
  13. CrackSeg9K
  14. SewerCrack
  15. CHASE DB1
  16. ...and 12 more sections

Figures (9)

  • Figure 1: (a) is the Cross Scan method, and (b) is our proposed Snake Scan method, with the red border indicating the tokens belonging to semantic proximity.
  • Figure 2: Overall structure of the CrackMamba model.
  • Figure 3: Overall structure of the SCVSS module.
  • Figure 4: Details of SnakeVSS and VSS structure.
  • Figure 5: Details of spatial and channel attention structure.
  • ...and 4 more figures