A framework for automated time-lapse thermography data processing

• Published in: Construction & building materials Vol. 227; p. 116507
• Main Authors: Al Gharawi, Mohanned, Adu-Gyamfi, Yaw, Washer, Glenn
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 10.12.2019
• Subjects: Automatic detection; Four-point approach; Signal-to-noise ratio (SNR); Sub-surface defects; Thermography; Time-lapse; Wavelet transform; Wavelet transform; Time-lapse; Four-point approach; Signal-to-noise ratio (SNR); Sub-surface defects; Thermography; Automatic detection
• ISSN: 0950-0618; 1879-0526
• DOI: 10.1016/j.conbuildmat.2019.07.233

•Continuous IR data acquisition improves the detectability of deeper subsurface defects.•The depth of subsurface defects can be uniquely extracted by multiscale data decomposition.•Defects beyond 3 inches from the surface are detectable within 3 – 5 days of IR data acquisition. The current research develops a framework to automatically extract sub-surface defects from time-lapse thermography (TLT) images of reinforced concrete bridge components. Traditional approaches for processing TLT data typically require manual interventions that are not easily scaled to a large network of concrete bridges. A backbone of robust algorithms for detecting and analyzing deep sub-surface defects in concrete is needed to support condition assessment of concrete structures such as bridges. The current paper leverages advances in adaptive signal and image processing to develop a fully automated TLT data processing pipeline that is capable of efficiently detecting defects at different depths in concrete. The methodology decomposes raw TLT datasets into narrow band time-frequency domains via a multiscale data analysis approach called a wavelet transform. The resulting decomposed modes are mined to extract defect information using thermal contrast enhancement routines. An objective measure of effectiveness based on signal-to-noise ratio was developed and used to compare the current framework with traditional approaches for processing TLT data. Active contour models were also designed to automatically extract the boundary location and geometric properties of the sub-surface defects. The results of this study show that the detection of deeper defects (3 in. and beyond) can be improved by analyzing the time-frequency response of surface temperature variations over a period of time. Compared to traditional lock-in algorithms and conventional infrared thermography images, the proposed framework is more effective at removing noisy information and produces images with greater contrast between intact and defective areas of concrete.