Arriving at estimates of a rate and state fault friction model parameter using Bayesian inference and Markov chain Monte Carlo

Artificial Intelligence in Geosciences Pub Date : 2021-12-01 DOI:10.1016/j.aiig.2022.02.003

Saumik Dana , Karthik Reddy Lyathakula

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Abstract

The critical slip distance in rate and state model for fault friction in the study of potential earthquakes can vary wildly from micrometers to few me-ters depending on the length scale of the critically stressed fault. This makes it incredibly important to construct an inversion framework that provides good estimates of the critical slip distance purely based on the observed ac-celeration at the seismogram. To eventually construct a framework that takes noisy seismogram acceleration data as input and spits out robust estimates of critical slip distance as the output, we first present the performance of the framework for synthetic data. The framework is based on Bayesian inference and Markov chain Monte Carlo methods. The synthetic data is generated by adding noise to the acceleration output of spring-slider-damper idealization of the rate and state model as the forward model.

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利用贝叶斯推理和马尔可夫链蒙特卡罗方法得到了速率和状态故障摩擦模型参数的估计

在潜在地震研究中，断层摩擦速率和状态模型中的临界滑动距离可以根据临界应力断层的长度范围从微米到几米不等。这使得构建一个反演框架变得非常重要，该框架可以完全基于地震记录上观察到的加速度来提供对临界滑动距离的良好估计。为了最终构建一个以噪声地震加速度数据为输入并输出临界滑移距离的鲁棒估计的框架，我们首先介绍了该框架对合成数据的性能。该框架基于贝叶斯推理和马尔可夫链蒙特卡罗方法。将速率状态模型理想化为正演模型，在弹簧-滑块-阻尼器的加速度输出中加入噪声生成合成数据。

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来源期刊

Artificial Intelligence in Geosciences

CiteScore

4.20

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0.00%

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