Crack detection above buildings based on the infrared thermal imaging technology

doi:10.6046/gtzyyg.2013.02.10

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Abstract Aimed at solving the problem of crack detection on buildings, the author has designed a method of crack detection based on the temperature observation above buildings by using the infrared thermal imaging technology. The method utilizes Matlab and other software to conduct related processing of thermal images collected by external industry so as to enhance the display of cracks, thus achieving the purpose of detection and simplifying the image processing process. An analogue experiment on a chapped building in Hangzhou was carried out to examine the reliability of this method. The experimental results show that the theory and method put forward by this paper have some practical value.

Keywords reomte sensing glacier lake dynamic change West Kunlun Mountains

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	P237

Issue Date: 28 April 2013

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	JI Peng
	GUO Huadong
	ZHANG Lu

Cite this article:

JI Peng,GUO Huadong,ZHANG Lu. Crack detection above buildings based on the infrared thermal imaging technology[J]. REMOTE SENSING FOR LAND & RESOURCES, 2013, 25(2): 53-56.

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https://www.gtzyyg.com/EN/10.6046/gtzyyg.2013.02.10 OR https://www.gtzyyg.com/EN/Y2013/V25/I2/53

[1] Park S,Lee C.Reference-free crack detection using transfer impedances[J].Journal of Sound and Vibration,2010,329(12):2337-2348.
[2] 郑小宝,王仕成,廖守亿,等.Vega中的传感器模块在红外成像仿真中的应用[J].计算机应用与软件,2010,27(4):18-22. Zheng X B,Wang S C,Liao S Y,et al.Applying sensor modules of vega in infrared imaging simulation[J].Computer Applications and Software,2010,27(4):18-22.
[3] 汤鹏.建筑物裂缝处理及加固问题研究[J].科技致富向导,2010(3):113-114. Tang P.Crack proceeding of buildings and research[J].Science and Technology Guide,2010(3):113-114.
[4] 董世武,宋跃明.简述建筑物裂缝的形成原因与防止问题[J].黑龙江科技信息,2010(7):232. Dong S W,Song Y M.The causes of building cracks and the solutions[J].Science and Technology Information,2010(7):232.
[5] 赵洋洋,徐常胜.基于文本的自动视频摘要[C]//第七届和谐人机环境联合学术会议(HHME2011)论文集,2011. Zhao Y Y,Xu C S.Abstract of auto-videos based on text[C]//HHME2011,2011.
[6] 孙晓刚,李云红.红外热像仪测温技术发展综述[J].激光与红外,2008,32(2):101-104. Sun X G,Li Y H.Review of the development of temperature measurement technology with infrared thermal imager[J].Laser and Infrared,2008,32(2):101-104.
[7] 袁华,王召巴.红外探测技术的原理及发展前景[J].科技信息,2008(4):15. Yuan H,Wang Z B.Principles and directions of infrared detections[J].Science and Technology Information,2008(4):15.
[8] 阮秋琦.数字图像处理基础[M].北京:清华大学出版社,2009. Ruan Q Q.Digital images proceeding foundations[M].Beijing:Tsinghua University Publish House,2009.
[9] Sykes D J,Couvillion J S,Cromiak,et al.The use of digital infrared thermal imaging to detect estrus in gilts[J].Theriogenology,2012,78(1):147-152.

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