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Title
Japanese:Nonlinear seismic response and residual drift determination combining ground acceleration data with recorded videos 
English:Nonlinear seismic response and residual drift determination combining ground acceleration data with recorded videos 
Author
Japanese: BOROSCHEK Ruben, YEOW Trevor Zhiqing, 楠浩一.  
English: Ruben Boroschek, Trevor Zhiqing Yeow, Koichi Kusunoki.  
Language English 
Journal/Book name
Japanese:Bulletin of Earthquake Engineering 
English:Bulletin of Earthquake Engineering 
Volume, Number, Page        
Published date Mar. 28, 2025 
Publisher
Japanese: 
English: 
Conference name
Japanese: 
English: 
Conference site
Japanese: 
English: 
DOI https://doi.org/10.1007/s10518-025-02142-9
Abstract While we can only instrument a small number of structures with traditional sensors, cities have become surrounded by video cameras that record response of whatever is in their field of view. In this paper we have a proof of concept that if we combine the seismic response data derived from video cameras with input obtained from accelerometers installed at ground level, the linear and nonlinear response of the structure can be estimated. We present an application and validation in a laboratory environment on a plane steel frame under varying shaking amplitudes. Linear and nonlinear responses are monitored using standard acceleration and displacement sensors and later compared with the displacements derived from videos using standard computer vision techniques. The comparison of computer vision derived displacements with traditional sensor data gives excellent results with differences in maximum values in relative to base displacement time histories of less than 10%. Later, the derived computer vision relative to ground displacements are used in parametric input-output system identification to estimate the evolution of the modal parameters as a function of response amplitude. For this case, the synchronized input from an inertial accelerometer is used. The result from this identification process is nearly identical to the ones obtained using traditional acceleration sensors. To extend its use, double differentiation of the computer vision derived displacement is used to estimate accelerations in a reduced frequency band with practically no difference with acceleration records on the selected band. There are several advantages detected from combining standard sensors and computer vision techniques, like full space definition of possible monitoring points and limiting the distortion of acceleration records due to structural rotations and the possibility to obtain residual displacements. The methodology to obtain reliable displacement is presented together with the determination of varying modal property as a function of shaking intensity and damage level.

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