As the aging of concrete structures becomes increasingly severe, crack detection has become a crucial aspect of maintaining their sustainable use. This paper investigates an automatic detection and analysis method for concrete cracks based on deep convolutional neural network architecture. The study utilized drones equipped with high-definition cameras to capture images of concrete structures such as bridges and roads, collecting over 10,000 original images containing cracks. Using Labelme software for point-by-point image annotation and applying data augmentation techniques like rotation and scaling, the dataset was expanded to 30,000 images to meet the requirements of deep learning model training. An improved AlexNet model was developed, replacing the fully connected layer with global average pooling to enhance robustness and reduce overfitting. The model achieved an average accuracy of 95.42% on the test set, outperforming traditional methods by 15%. The model also proved effective in noisy environments. Additionally, a semantic segmentation model based on Fully Convolutional Network (FCN) was introduced, incorporating atrous convolution and spatial pyramid pooling, achieving a pixel-level accuracy of 97.6%, surpassing benchmark models such as FCN and U-Net. The model accurately estimated crack width, with an error rate within ±2% compared to field measurements. This method improves detection efficiency and accuracy while reducing manual intervention, providing strong support for the maintenance of concrete structures.
AbualigahSMAl-NaimiAFSachdevaG, et al. (2024) IDSDeep-CCD: intelligent decision support system based on deep learning for concrete cracks detection. Multimedia Tools and Applications84: 10013–10026.
2.
AiDMoFHanY, et al. (2022) Automated identification of compressive stress and damage in concrete specimen using convolutional neural network learned electromechanical admittance. Engineering Structures259: 114176.
3.
AliRChuahJHTalipMSA, et al. (2022) Structural crack detection using deep convolutional neural networks. Automation in Construction133: 103989.
4.
ArbaouiAOuahabiAJacquesS, et al. (2021) Concrete cracks detection and monitoring using deep learning-based multiresolution analysis. Electronics10(15): 1772.
5.
ChaiyasarnKBuatikALikitlersuangS (2021) Concrete crack detection and 3D mapping by integrated convolutional neural networks architecture. Advances in Structural Engineering24(7): 1480–1494.
6.
ChenBZhangHWangG, et al. (2023) Automatic concrete infrastructure crack semantic segmentation using deep learning. Automation in Construction152: 104950.
7.
DongYSuCQiaoP, et al. (2020) Microstructural crack segmentation of three-dimensional concrete images based on deep convolutional neural networks. Construction and Building Materials253: 119185.
8.
FanZLiCChenY, et al. (2020) Ensemble of deep convolutional neural networks for automatic pavement crack detection and measurement. Coatings10(2): 152.
9.
FlahMSuleimanARNehdiML (2020) Classification and quantification of cracks in concrete structures using deep learning image-based techniques. Cement and Concrete Composites114: 103781.
10.
GoldingVPGharineiatZMunawarHS, et al. (2022) Crack detection in concrete structures using deep learning. Sustainability14(13): 8117.
11.
HacıefendioğluKBaşağaHB (2022) Concrete road crack detection using deep learning-based faster R-CNN method. Iranian Journal of Science and Technology, Transactions of Civil Engineering46(2): 1621–1633.
12.
HanGKimY-MKimH, et al. (2021) Auto-detection of acoustic emission signals from cracking of concrete structures using convolutional neural networks: upscaling from specimen. Expert Systems with Applications186: 115863.
13.
KimJJKimA-RLeeS-W (2020) Artificial neural network-based automated crack detection and analysis for the inspection of concrete structures. Applied Sciences10(22): 8105.
14.
KimBYuvarajNSri PreethaaKR, et al. (2021) Surface crack detection using deep learning with shallow CNN architecture for enhanced computation. Neural Computing & Applications33(15): 9289–9305.
15.
LiSZhaoX (2020) Automatic crack detection and measurement of concrete structure using convolutional encoder-decoder network. IEEE Access8: 134602–134618.
16.
LiGLiuQZhaoS, et al. (2020) Automatic crack recognition for concrete bridges using a fully convolutional neural network and naive Bayes data fusion based on a visual detection system. Measurement Science and Technology31(7): 075403.
17.
LuoYLuoYWuC, et al. (2024a) RETRACTED: finite element simulation and falling ball impact model for cement concrete pavement considering void under slab. Construction and Building Materials427: 136245.
18.
LuoYM YussofMJiangY, et al. (2024b) Experimental study of the chloride-ion permeability of bamboo-fiber-reinforced concrete. Materiali in Tehnologije58(2): 2024.
19.
LuoYYussofMMZhangL (2024c) Study of thermal conductivity of constituent materials for electrically heated bridge decks. Construction and Building Materials453: 139122.
20.
LvZChengCLvH (2023) Automatic identification of pavement cracks in public roads using an optimized deep convolutional neural network model. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences381(2254): 20220169.
21.
MasrourTEl HassaniIBouchamaMS (2020) Deep convolutional neural networks with transfer learning for old buildings pathologies automatic detection. In: EzziyyaniM (ed) Advanced Intelligent Systems for Sustainable Development (AI2SD’2019). Springer International Publishing, Vol. 1104, 204–216.
22.
MiaoPSrimahachotaT (2021) Cost-effective system for detection and quantification of concrete surface cracks by combination of convolutional neural network and image processing techniques. Construction and Building Materials293: 123549.
23.
PadsumbiyaMBrahmbhattVThakkarSP (2022) Automatic crack detection using convolutional neural network. Journal of Soft Computing in Civil Engineering6(3): 1–17.
24.
PalMPalevičiusPLandauskasM, et al. (2021) An overview of challenges associated with automatic detection of concrete cracks in the presence of shadows. Applied Sciences11(23): 11396.
25.
PalevičiusPPalMLandauskasM, et al. (2022) Automatic detection of cracks on concrete surfaces in the presence of shadows. Sensors22(10): 3662.
26.
PhamM-VHaY-SKimY-T (2023) Automatic detection and measurement of ground crack propagation using deep learning networks and an image processing technique. Measurement215: 112832.
27.
QiZLiuDZhangJ, et al. (2022) Micro-concrete crack detection of underwater structures based on convolutional neural network. Machine Vision and Applications33(5): 74.
28.
RajaduraiR-SKangS-T (2021) Automated vision-based crack detection on concrete surfaces using deep learning. Applied Sciences11(11): 5229.
29.
RaoASNguyenTPalaniswamiM, et al. (2021) Vision-based automated crack detection using convolutional neural networks for condition assessment of infrastructure. Structural Health Monitoring20(4): 2124–2142.
30.
RenYHuangJHongZ, et al. (2020) Image-based concrete crack detection in tunnels using deep fully convolutional networks. Construction and Building Materials234: 117367.
31.
SaeedMS (2021) Unmanned aerial vehicle for automatic detection of concrete crack using deep learning. In: 2021 2nd International Conference on Robotics, Electrical and Signal Processing Techniques (ICREST), Dhaka, Bangladesh, 5–7 January 2021, 624–628. https://ieeexplore.ieee.org/abstract/document/9331177/
32.
SongLSunHLiuJ, et al. (2022) Automatic segmentation and quantification of global cracks in concrete structures based on deep learning. Measurement199: 111550.
33.
TabernikDŠucMSkočajD (2023) Automated detection and segmentation of cracks in concrete surfaces using joined segmentation and classification deep neural network. Construction and Building Materials408: 133582.
34.
WangWHuWWangW, et al. (2021) Automated crack severity level detection and classification for ballastless track slab using deep convolutional neural network. Automation in Construction124: 103484.
WeiWDingLLuoH, et al. (2021) Automated bughole detection and quality performance assessment of concrete using image processing and deep convolutional neural networks. Construction and Building Materials281: 122576.
37.
YangQShiWChenJ, et al. (2020) Deep convolution neural network-based transfer learning method for civil infrastructure crack detection. Automation in Construction116: 103199.
38.
YeWDengSRenJ, et al. (2022) Deep learning-based fast detection of apparent concrete crack in slab tracks with dilated convolution. Construction and Building Materials329: 127157.
39.
YuYRashidiMSamaliB, et al. (2022) Crack detection of concrete structures using deep convolutional neural networks optimized by enhanced chicken swarm algorithm. Structural Health Monitoring21(5): 2244–2263.
40.
YuYXuJSuJ, et al. (2024) Investigating specimen size and shape effects on compressive mechanical behaviors of recycled aggregate concrete using discrete element mesoscale modeling. Construction and Building Materials438: 137196.
41.
ZadehSSbirganiSAKhorshidiM, et al. (2024) Concrete surface crack Detection with convolutional-based deep learning models (arXiv:2401.07124). International Journal of Novel Research in Civil Structural and Earth Sciences10(3): 25–35.
