Hyoung Suk Suh scite author profile

Supervised machine learning via artificial neural network (ANN) has gained significant popularity for many geomechanics applications that involves multi‐phase flow and poromechanics. For unsaturated poromechanics problems, the multi‐physics nature and the complexity of the hydraulic laws make it difficult to design the optimal setup, architecture, and hyper‐parameters of the deep neural networks. This paper presents a meta‐modeling approach that utilizes deep reinforcement learning (DRL) to automatically discover optimal neural network settings that maximize a pre‐defined performance metric for the machine learning constitutive laws. This meta‐modeling framework is cast as a Markov Decision Process (MDP) with well‐defined states (subsets of states representing the proposed neural network (NN) settings), actions, and rewards. Following the selection rules, the artificial intelligence (AI) agent, represented in DRL via NN, self‐learns from taking a sequence of actions and receiving feedback signals (rewards) within the selection environment. By utilizing the Monte Carlo Tree Search (MCTS) to update the policy/value networks, the AI agent replaces the human modeler to handle the otherwise time‐consuming trial‐and‐error process that leads to the optimized choices of setup from a high‐dimensional parametric space. This approach is applied to generate two key constitutive laws for the unsaturated poromechanics problems: (1) the path‐dependent retention curve with distinctive wetting and drying paths. (2) The flow in the micropores, governed by an anisotropic permeability tensor. Numerical experiments have shown that the resultant ML‐generated material models can be integrated into a finite element (FE) solver to solve initial‐boundary‐value problems as replacements of the hand‐craft constitutive laws.

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Particle shape effect on thermal conductivity and shear wave velocity in sands

Lee

Suh

Yoon

et al. 2017

Acta Geotech.

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Capillary pressure at irregularly shaped pore throats: Implications for water retention characteristics

Suh

Kang

Jang

et al. 2017

Advances in Water Resources

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Asynchronous phase field fracture model for porous media with thermally non-equilibrated constituents

Suh

Sun

2021

Computer Methods in Applied Mechanics and Engineering

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A phase field model for cohesive fracture in micropolar continua

Suh

Sun

O’Connor

2020

Computer Methods in Applied Mechanics and Engineering

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Hyoung Suk Suh

An offline multi‐scale unsaturated poromechanics model enabled by self‐designed/self‐improved neural networks

Particle shape effect on thermal conductivity and shear wave velocity in sands

Capillary pressure at irregularly shaped pore throats: Implications for water retention characteristics

Asynchronous phase field fracture model for porous media with thermally non-equilibrated constituents

A phase field model for cohesive fracture in micropolar continua

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