Data-Driven Approach to Inversion Analysis of Three-Dimensional Inner Soil Structure via Wave Propagation Analysis

Various approaches based on both computational science and data science/machine learning have been proposed with the development of observation systems and network technologies. Computation cost associated with computational science can be reduced by introducing the methods based on data science/machine learning. In the present paper, we focus on a method to estimate inner soil structure via wave propagation analysis. It is regarded as one of the parameter optimization approaches using observation data on the surface. This application is in great demand to ensure better reliability in numerical simulations. Typical optimization requires many forward analyses; thus, massive computation cost is required. We propose an approach to substitute evaluation using neural networks for most cases of forward analyses and to reduce the number of forward analyses. Forward analyses in the proposed method are used for producing the training data for a neural network; thereby they can be computed independently, and the actual elapsed time can be reduced by using a large-scale supercomputer. We demonstrated that the inner soil structure was estimated with the sufficient accuracy for practical damage evaluation. We also confirmed that the proposed method achieved estimating parameters within a shorter timeframe compared to a typical approach based on simulated annealing.

[1]  Franck Cappello,et al.  Big data and extreme-scale computing , 2018, Int. J. High Perform. Comput. Appl..

[2]  L. Ingber Very fast simulated re-annealing , 1989 .

[3]  M. Warner,et al.  Anisotropic 3D full-waveform inversion , 2013 .

[4]  Natalia Gimelshein,et al.  PyTorch: An Imperative Style, High-Performance Deep Learning Library , 2019, NeurIPS.

[5]  Takuya Akiba,et al.  Optuna: A Next-generation Hyperparameter Optimization Framework , 2019, KDD.

[6]  Tsuyoshi Ichimura,et al.  Fast Multi-Step Optimization with Deep Learning for Data-Centric Supercomputing , 2020 .

[7]  Tsuyoshi Ichimura,et al.  An elastic/viscoelastic finite element analysis method for crustal deformation using a 3-D island-scale high-fidelity model , 2016 .

[8]  Alok Choudhary,et al.  A predictive machine learning approach for microstructure optimization and materials design , 2015, Scientific Reports.

[9]  Franz Günter Sander,et al.  Quasi-automatic 3D finite element model generation for individual single-rooted teeth and periodontal ligament , 2004, Comput. Methods Programs Biomed..

[10]  G. Sun,et al.  The footprint of urban heat island effect in China , 2015, Scientific Reports.

[11]  Tsuyoshi Ichimura,et al.  Heuristic Optimization with CPU-GPU Heterogeneous Wave Computing for Estimating Three-Dimensional Inner Structure , 2019, ICCS.

[12]  Jianwen Liang,et al.  Site Effects on Seismic Behavior of Pipelines: A Review , 2000 .

[13]  Pher Errol Balde Quinay,et al.  Waveform Inversion for Modeling Three‐Dimensional Crust Structure with Topographic Effects , 2012 .

[14]  Tsuyoshi Ichimura,et al.  GPU Implementation of a Sophisticated Implicit Low-Order Finite Element Solver with FP21-32-64 Computation Using OpenACC , 2019, WACCPD@SC.