A GENERIC-guided active learning SPH method for viscoelastic fluids using Gaussian process regression

TL;DR

This paper introduces a GENERIC-guided active learning SPH method that uses Gaussian process regression to efficiently learn viscoelastic constitutive relations, improving simulation accuracy and reducing data requirements.

Contribution

The paper proposes a novel GENERIC-guided active learning approach combined with GPR and SPH for better viscoelastic fluid modeling, emphasizing data efficiency and accuracy.

Findings

Accurately simulates viscoelastic flows with fewer data points.

Reduces training data needs via a new relative uncertainty metric.

Validates method with Poiseuille and cylinder flow simulations.

Abstract

When applying machine learning methods to learn viscoelastic constitutive relations, the polymer history dependence in viscoelastic fluids and the generalization ability of machine learning models are challenging. In this paper, guided by the general equation for nonequilibrium reversible-irreversible coupling (GENERIC) framework, a novel GENERIC-guided active learning smoothed particle hydrodynamics (${\rm{G^2ALSPH}}$) method is proposed to obtain effective constitutive relations for reliable simulations of viscoelastic flows. By utilizing the GENERIC framework, the target viscoelastic constitutive relation is reduced to a simple functional relation between the eigenvalues of the conformation tensor and the eigenvalues of its thermodynamically conjugated tensorial variable, which incorporates the flow-history-dependent memory effect. Based on data and Gaussian process regression (GPR), a new active learning strategy is developed to obtain the simplified constitutive relation, in which the generalization ability is ensured by actively acquiring more data points when needed. Moreover, a novel relative uncertainty is devised to establish an accuracy evaluation tool for the GPR prediction results, which reduces the number of required training data points while maintaining accuracy. Furthermore, the SPH method combined with the latest techniques serves as an effective macroscopic numerical method. Eventually, the Poiseuille flows and the flows around a periodic array of cylinders at different Weissenberg numbers are simulated to validate the effectiveness and accuracy of the ${\rm{G^2ALSPH}}$ method. The Oldroyd-B model is used as the ground truth constitutive relation to provide data for GPR, bringing analytical solutions for comparison. The excellent performance demonstrates that the ${\rm{G^2ALSPH}}$ method has promising applications in data-driven simulations of viscoelastic fluids.