Thermodynamically Consistent Machine-Learned Internal State Variable
Approach for Data-Driven Modeling of Path-Dependent Materials
- URL: http://arxiv.org/abs/2205.00578v1
- Date: Sun, 1 May 2022 23:25:08 GMT
- Title: Thermodynamically Consistent Machine-Learned Internal State Variable
Approach for Data-Driven Modeling of Path-Dependent Materials
- Authors: Xiaolong He, Jiun-Shyan Chen
- Abstract summary: Data-driven machine learning models, such as deep neural networks and recurrent neural networks (RNNs), have become viable alternatives.
This study proposes a machine-learned data robustness-driven modeling approach for path-dependent materials based on the measurable material.
- Score: 0.76146285961466
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Characterization and modeling of path-dependent behaviors of complex
materials by phenomenological models remains challenging due to difficulties in
formulating mathematical expressions and internal state variables (ISVs)
governing path-dependent behaviors. Data-driven machine learning models, such
as deep neural networks and recurrent neural networks (RNNs), have become
viable alternatives. However, pure black-box data-driven models mapping inputs
to outputs without considering the underlying physics suffer from unstable and
inaccurate generalization performance. This study proposes a machine-learned
physics-informed data-driven constitutive modeling approach for path-dependent
materials based on the measurable material states. The proposed data-driven
constitutive model is designed with the consideration of universal
thermodynamics principles, where the ISVs essential to the material
path-dependency are inferred automatically from the hidden state of RNNs. The
RNN describing the evolution of the data-driven machine-learned ISVs follows
the thermodynamics second law. To enhance the robustness and accuracy of RNN
models, stochasticity is introduced to model training. The effects of the
number of RNN history steps, the internal state dimension, the model
complexity, and the strain increment on model performances have been
investigated. The effectiveness of the proposed method is evaluated by modeling
soil material behaviors under cyclic shear loading using experimental
stress-strain data.
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