Predicting Fault Slip via Transfer Learning
Abstract
Data-driven machine-learning for predicting instantaneous and future fault-slip in laboratory experiments has recently progressed markedly due to large training data sets. In Earth however, earthquake interevent times range from 10's-100's of years and geophysical data typically exist for only a portion of an earthquake cycle. Sparse data presents a serious challenge to training machine learning models. Here we describe a transfer learning approach using numerical simulations to train a convolutional encoder-decoder that predicts fault-slip behavior in laboratory experiments. The model learns a mapping between acoustic emission histories and fault-slip from numerical simulations, and generalizes to produce accurate results using laboratory data. Notably slip-predictions markedly improve using the simulation-data trained-model and training the latent space using a portion of a single laboratory earthquake-cycle. The transfer learning results elucidate the potential of using models trained on numerical simulations and fine-tuned with small geophysical data sets for potential applications to faults in Earth.
Keywords
Cite
@article{arxiv.2107.05826,
title = {Predicting Fault Slip via Transfer Learning},
author = {Kun Wang and Christopher W. Johnson and Kane C. Bennett and Paul A. Johnson},
journal= {arXiv preprint arXiv:2107.05826},
year = {2022}
}
Comments
12 pages, 8 figures