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基于卷积神经网络和集成池化模块的自动化图像多变量混凝土缺陷识别

An Automated Image-Based Multivariant Concrete Defect Recognition Using a Convolutional Neural Network with an Integrated Pooling Module.

机构信息

Department of Robot and Smart System Engineering, Kyungpook National University, 80 Daehak-ro, Buk-gu, Daegu 41566, Korea.

Department of Architectural Engineering, Daegu Catholic University, Hayang-ro 13-13, Hayang-eup, Gyeongasan-si 38430, Korea.

出版信息

Sensors (Basel). 2022 Apr 19;22(9):3118. doi: 10.3390/s22093118.

DOI:10.3390/s22093118
PMID:35590810
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9105078/
Abstract

Buildings and infrastructure in congested metropolitan areas are continuously deteriorating. Various structural flaws such as surface cracks, spalling, delamination, and other defects are found, and keep on progressing. Traditionally, the assessment and inspection is conducted by humans; however, due to human physiology, the assessment limits the accuracy of image evaluation, making it more subjective rather than objective. Thus, in this study, a multivariant defect recognition technique was developed to efficiently assess the various structural health issues of concrete. The image dataset used was comprised of 3650 different types of concrete defects, including surface cracks, delamination, spalling, and non-crack concretes. The proposed scheme of this paper is the development of an automated image-based concrete condition recognition technique to categorize, not only non-defective concrete into defective concrete, but also multivariant defects such as surface cracks, delamination, and spalling. The developed convolution-based model multivariant defect recognition neural network can recognize different types of defects on concretes. The trained model observed a 98.8% defect detection accuracy. In addition, the proposed system can promote the development of various defect detection and recognition methods, which can accelerate the evaluation of the conditions of existing structures.

摘要

在人口密集的大都市地区,建筑物和基础设施不断恶化。各种结构缺陷,如表面裂缝、剥落、分层和其他缺陷不断出现并持续发展。传统上,评估和检查是由人来进行的;然而,由于人类的生理学,评估限制了图像评估的准确性,使其更为主观而不是客观。因此,在这项研究中,开发了一种多变量缺陷识别技术,以有效地评估混凝土的各种结构健康问题。所使用的图像数据集由 3650 种不同类型的混凝土缺陷组成,包括表面裂缝、分层、剥落和无裂缝混凝土。本文提出的方案是开发一种基于图像的自动化混凝土状况识别技术,不仅可以将无缺陷的混凝土分类为有缺陷的混凝土,还可以将表面裂缝、分层和剥落等多种缺陷进行分类。基于卷积的模型多变量缺陷识别神经网络可以识别混凝土上的不同类型的缺陷。经过训练的模型观察到缺陷检测的准确率为 98.8%。此外,该系统可以促进各种缺陷检测和识别方法的发展,从而加速对现有结构状况的评估。

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