4.6 Article

Monitoring of a landmark bridge using SAR interferometry coupled with engineering data and forensics

期刊

INTERNATIONAL JOURNAL OF REMOTE SENSING
卷 43, 期 1, 页码 95-119

出版社

TAYLOR & FRANCIS LTD
DOI: 10.1080/01431161.2021.2003468

关键词

SAR interferometry; Bridge monitoring; Seasonal thermal response; Displacement decomposition; Remote sensing measurements interpretation

资金

  1. National Key Research and Development Program of China [2017YFE0134400]

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Infrastructure monitoring is essential for evaluating capacity and functionality loss, and this study proposes a hybrid approach using D-TomoSAR techniques and engineering forensics to assess the structural condition of a landmark bridge. By analyzing displacement products and deformation trends, potential deterioration issues and vulnerable deck locations are identified, providing valuable evidence for decision-making.
Infrastructure monitoring can facilitate the evaluation of capacity and functionality loss and therefore provide valuable data and evidence for reliable, lifetime and automated risk assessments. Terrestrial monitoring systems can provide information about assets and their condition. Yet, they fall short of engineering requirements related to the history of the asset loading, deterioration and potential damage, which is of paramount importance in risk-based decision-making by infrastructure operators. This capability gap can be filled by Persistent Scatterer Interferometry (PSI) Monitoring in conjunction with engineering forensics and judgment. This paper puts forward this hybrid approach to assess the structural condition of a landmark bridge by coupling advanced Differential SAR Tomography (D-TomoSAR) techniques with an adaptive deformation model, environmental measurements and engineering evidence and evaluations. A dataset of 360 Sentinel A &B images covering the period between 10/2014 and 2/2020 and temperature records to account for seasonal deformation were deployed. Displacement products, such as the development of annual displacement and time series were calculated demonstrating a strong correlation with temperature variation and resulting deformations of the asset. The spatiotemporally evolving deformation trends of the bridge superstructure were derived, and vulnerable deck locations were identified on the basis of engineering forensics, judgment and progressive displacements calculated from the D-TomoSAR technique. The vertical displacement profile at the critical deck location was developed reaching a displacement velocity of 1.8 mm/year and potential deterioration issues are manifested as potential causes of the observed geometric alterations. Based on the D-TomoSAR results matched with engineering evidence and on-site visual inspections and judgment, this study contributed to the decision-making process. This research is a pilot showcase of D-TomoSAR for the bridge monitoring, not only providing mm-level quantitative measurements of the bridge in a 6-year observation span using medium resolution Sentinel-1 SAR images alone but also indirectly identifying potential structural defects in the north section of the bridge. This research is a primer example of how we can deploy diverse evidence to facilitate targeted adaptation measures and prioritize restoration strategies to facilitate asset owners in better decision making.

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