Predicting the seismic ground-motion parameters: 3D physics-based numerical simulations combined with artificial neural networks

Earthquake Spectra Pub Date : 2024-06-12 DOI:10.1177/87552930241255953

Zhenning Ba, Linghui Lyu, Jingxuan Zhao, Yushan Zhang, Yu Wang

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Abstract

Typically, it is challenging to incorporate near-surface soils into 3D physics-based numerical simulations (PBSs) for ground-motion prediction. The low shear wave speed of near-surface soils, coupled with the complexity of the soil seismic response, poses significant difficulties. To overcome these limitations, a hybrid approach was proposed in this study, combining PBSs with artificial neural networks (ANNs). The essence of the hybrid method can be summarized as follows: (1) development of ANN models, establishing a strong-motion database, training the ANNs on it to predict the ground-motion parameters for East–West (EW), North–South (NS), and Vertical (UD) directions afterward; (2) establishment of 3D PBS model, obtaining the ground-motion parameters of the bedrock face corresponding to a certain shear wave speed; (3) application of the trained ANNs to predict the ground-motion parameters on the ground surface, taking the simulated results and related site parameters as inputs, and the outputs are peak ground acceleration (PGA) and 5% damped spectral accelerations (Sa) at different periods on the ground surface. In this study, ANN models were trained on a strong-motion database based on Kiban–Kyoshin Network (KiK-net). After several verifications of the ANN predictions, a case study of the 21 October 2016 Mw6.2 Central Tottori earthquake was conducted. In addition to the comparison with observations, the broadband (0.1–10 Hz) results of the hybrid method were also compared with the results that obtained by transfer function based on recorded data and Next Generation Attenuation (NGA)-West2 ground-motion prediction equations (GMPEs) to demonstrate the effectiveness and applicability of the proposed method. In addition, the distribution of Sa for four periods in simulated area was presented. The performance of the hybrid method for predicting broadband ground-motion characteristics was generally satisfactory.

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预测地震地动参数：基于三维物理的数值模拟与人工神经网络相结合

通常情况下，将近地表土壤纳入三维物理数值模拟（PBSs）进行地动预测具有挑战性。近地表土壤的剪切波速度较低，再加上土壤地震响应的复杂性，给预测带来了很大困难。为了克服这些局限性，本研究提出了一种混合方法，将物理模拟与人工神经网络（ANN）相结合。该混合方法的精髓可归纳如下：(1) 开发人工神经网络模型，建立强震数据库，训练人工神经网络，然后预测东西（EW）、南北（NS）和垂直（UD）方向的地震动参数；(2) 建立三维 PBS 模型，获取一定剪切波速度对应的基岩面地震动参数；(3) 以模拟结果和相关场地参数为输入，应用训练有素的 ANN 预测地表地动参数，输出为地表不同周期的峰值地加速度（PGA）和 5%阻尼谱加速度（Sa）。在这项研究中，基于 Kiban-Kyoshin 网络（KiK-net）的强运动数据库对 ANN 模型进行了训练。在对 ANN 预测进行多次验证后，对 2016 年 10 月 21 日 Mw6.2 中部鸟取地震进行了案例研究。除了与观测数据进行比较外，还将混合方法的宽带（0.1-10 Hz）结果与基于记录数据的传递函数和下一代衰减（NGA）-West2 地动预测方程（GMPEs）得出的结果进行了比较，以证明所提方法的有效性和适用性。此外，还介绍了模拟区域四个时段的 Sa 分布情况。混合方法在预测宽带地动特性方面的性能总体上令人满意。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Earthquake Spectra

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