A robust structural parameter estimation method using seismic response measurements

Kuleli, Muge; Nagayama, Tomonori

doi:10.1002/stc.2475

Cited by 16 publications

(9 citation statements)

References 32 publications

(34 reference statements)

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“…This could be resolved by measuring displacements directly (which was also suggested by Skolnik and Wallace 42 ) of which potential solutions are currently being researched, 44 though the use of displacement sensors might increase the cost of implementing SHM, which might be viewed as unfavorable. More advanced methods to extract displacements from acceleration results could be used (e.g., Kalman filters 11–14 ), though these techniques are still not widely and readily available for current use in practice for reasons previously stated in the introduction.…”

Section: Discussionmentioning

confidence: 99%

“…Additionally, the effect of damage on dynamic properties may not be significant or differentiable from environmental or operational effects. Another approach is to track hysteretic behavior using nonlinear methods 9–14 . For example, one could use the equation of motion and the recorded accelerations at a given time‐step t i to predict the response at the next time‐step t i +1 , and adjust predictions based on the recorded accelerations at t i +1 .…”

Section: Introductionmentioning

confidence: 99%

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Unbiased rank selection for automatic hysteretic response extraction of RC frame buildings using acceleration recordings for post‐earthquake safety evaluations

Yeow

Kusunoki

2021

Earthq Engng Struct Dyn

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A framework to extract a building's hysteretic response based on decomposing floor acceleration recordings into different ranks (i.e., decomposition levels) using the discrete wavelet transform (DWT) and then reconstructing signals considering only ranks which corresponded to the building's predominant response mode was recently proposed. However, current rank selection approaches require subjective judgment. This study looks to develop an unbiased rank selection method to enable automation of the hysteresis extraction framework for easier adoption in practice. The selection methodology was developed using response history analysis of several multistory reinforced concrete (RC) frame buildings and validated using data from large‐scale shake‐table tests performed at the E‐Defense testing facility. It was observed that the proposed approach was able to accurately capture the response of RC frame buildings well in majority of cases. The exception to this was for significantly damaged buildings as the use of double integration of accelerations to estimate displacements and the DWT method meant that residual deformations were not well captured. However, significant strength degradation was still observed in the extracted hysteresis behavior for these cases, and thus these buildings would have been correctly classified as being heavily damaged. The step‐by‐step process to automatically select ranks is presented in the paper, and possible revenues for further improvement of the hysteretic response extraction framework are discussed.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Unbiased rank selection for automatic hysteretic response extraction of RC frame buildings using acceleration recordings for post‐earthquake safety evaluations

Yeow

Kusunoki

2021

Earthq Engng Struct Dyn

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“…Structural health monitoring (SHM) technologies [ 1 ] have been extensively researched and used to assess structures. In particular, SHM technologies for identifying the structural parameters, state, and input [ 2 , 3 , 4 ] have received considerable attention, and numerous algorithms have been developed that use response data recorded by sensors.…”

Section: Introductionmentioning

confidence: 99%

Absolute Displacement-Based Formulation for Peak Inter-Story Drift Identification of Shear Structures Using Only One Accelerometer

Mita

2021

Sensors

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Only one accelerometer is used in this paper for estimating the maximum inter-story drifts and time histories of the relative displacements of all stories of multi-degree-of-freedom (MDOF) shear structures under seismic excitation. The calculation based on the data of one sensor using a conventional method is unstable, and when modal coordinates are used, higher modes should be included, which is different from the estimation based on the responses recorded by many accelerometers. However, the parameters of the higher modes of structures are difficult to obtain from structures under small excitations. To overcome this difficulty, the recorded absolute acceleration is converted into the absolute displacement, and a state-space equation is formulated. Numerical simulations of a nine-story structure were conducted to check the applicability, robustness against environmental noise, and optimal installation location of the accelerometer of the proposed approach. In addition, the effects of the higher modes were analyzed in terms of the number of accelerometers and type of response. Finally, the proposed approach was validated in a simple experiment. The results indicate that it can accurately estimate the time histories of the relative displacements and maximum inter-story drifts of all floors when one accelerometer is used and just the first two modal parameters are incorporated in the model. Furthermore, the approach is robust against environmental noise.

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“…Structural health monitoring (SHM) 1 has been extensively developed over the last few decades as a means of assessing the states of structures. Structural identification based on vibration data measured by sensors is one of the main aspects of SHM, and parameter identification, 2 responses estimation, 3 and input reconstruction 4 have received the most attention.…”

Section: Introductionmentioning

confidence: 99%

Estimation of maximum drift of multi‐degree‐of‐freedom shear structures with unknown parameters using only one accelerometer

Mita

2021

Structural Contr & Hlth

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Summary When a multi‐degree‐of‐freedom (MDOF) shear structure is excited by seismic excitation, the connections between structural and non‐structural members may become loose or slight structural damage may arise, which cause the natural frequencies identified from the healthy structure shift. However, it is not easy to accurately re‐identify the natural frequencies from the response recorded by one sensor. This paper presents a method to estimate the maximum inter‐story drift and time histories of the relative displacement of all stories of the structure from the measured absolute response. First, the absolute acceleration and relative displacement are formulated in modal coordinates, and a state‐space expression is derived. Then, a scheme to reduce the modeling error arising from shifts in the structural frequencies is devised that uses the genetic algorithm (GA) and a reasonably chosen fitness function. The applicability of this approach was investigated by conducting numerical simulations focusing on the rate of change in natural frequencies and selection of the lower bound of GA variables. Further simulations were conducted to investigate the robustness, installation location, and truncation error of the proposed method. Finally, the proposed approach was validated in a simple experiment. The results indicate that it can accurately estimate the time histories of the relative displacement and maximum inter‐story drifts of all floors in the case of a significant change in natural frequencies and a large search range of GA variables. In addition, it is robust against environmental noise and performs well even when the model includes only lower modal responses.

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A robust structural parameter estimation method using seismic response measurements

Cited by 16 publications

References 32 publications

Unbiased rank selection for automatic hysteretic response extraction of RC frame buildings using acceleration recordings for post‐earthquake safety evaluations

Unbiased rank selection for automatic hysteretic response extraction of RC frame buildings using acceleration recordings for post‐earthquake safety evaluations

Absolute Displacement-Based Formulation for Peak Inter-Story Drift Identification of Shear Structures Using Only One Accelerometer

Estimation of maximum drift of multi‐degree‐of‐freedom shear structures with unknown parameters using only one accelerometer

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