Abstract
Traditional methods for seismic damage evaluation require manual extractions of intensity measures (IMs) to properly represent the record-to-record variation of ground motions. Contemporary methods such as convolutional neural networks (CNNs) for time series classification and seismic damage evaluation face a challenge in training due to a huge task of ground-motion image encoding. Presently, no consensus has been reached on the understanding of the most suitable encoding technique and image size (width × height × channel) for CNN-based seismic damage evaluation. In this study, we propose and develop a new image encoding technique based on time-series segmentation (TS) to transform acceleration (A), velocity (V), and displacement (D) ground motion records into a three-channel AVD image of the ground motion event with a pre-defined size of width × height. The proposed TS technique is compared with two time-series image encoding techniques, namely recurrence plot (RP) and wavelet transform (WT). The CNN trained through the TS technique is also compared with the IM-based machine learning approach. The CNN-based feature extraction has comparable classification performance to the IM-based approach. WT 1,000 × 100 results in the highest 79.5% accuracy in classification while TS 100 × 100 with a classification accuracy of 76.8% is most computationally efficient. Both the WT 1,000 × 100 and TS 100 × 100 three-channel AVD image encoding methods are promising for future studies of CNN-based seismic damage evaluation.
Highlights
Traditional seismic fragility curves based on a scalar intensity measure (IM) have been widely used to generate fragility estimates in earthquake events (Hwang et al, 2001; Baker and Cornell, 2005; Cimellaro et al, 2010; Xu et al, 2020a)
Xu et al (2020b) recommended several IMs from a pool of 48 IMs to be used in the machine-learning models for effective damage evaluation, including the spectral acceleration at the fundamental period of a target structure, effective peak acceleration, Housner intensity, effective peak velocity, and peak ground velocity, that are used in this study to train the logistic regression (LR) and decision tree (DT) machine learning models
The convolutional neural networks (CNNs) models based on the recurrence plot (RP) 500 × 500 and timeseries segmentation (TS) 100 × 100 AVD images and the machine-learning DT model generate the second-best results
Summary
Traditional seismic fragility curves based on a scalar intensity measure (IM) have been widely used to generate fragility estimates in earthquake events (Hwang et al, 2001; Baker and Cornell, 2005; Cimellaro et al, 2010; Xu et al, 2020a). Mangalathu and Jeon (2020) proposed to use CNNs to rapidly evaluate the damage of structures They used the wavelet transform (WT) to format 320 ground acceleration records as one-channel images to characterize the temporal and spectral nonlinearity of ground motions. We propose a new image encoding technique based on time-series segmentation (TS) to transform the acceleration (A), velocity (V), and displacement (D) records of each ground motion event to a three-channel AVD image with a predefined size of width × height. The damage state of the target structure caused by a future earthquake event can be predicted by the previously trained CNN seismic classifier based on the proposed image encoding technique with the input of the ground motion recorded during the earthquake event. The F−measure and accuracy of the validation dataset are used to evaluate and compare the performance of various CNN models based on different image encoding techniques in section “Results and Discussion.” A F−measure and accuracy closer to 1 means better classification results
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