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A Structure-Preserving Graph Neural Solver for Parametric Hyperbolic Conservation Laws

Computational Physics 2026-04-20 v1 Machine Learning Numerical Analysis Numerical Analysis

Abstract

Hyperbolic conservation laws govern a wide range of transport-driven dynamics featuring shocks, contact discontinuities, and complex wave interactions, posing distinct challenges for deep-learning-based surrogate modeling. While classical numerical methods provide robust and physically admissible solutions, their computational cost restricts applicability in many-query tasks such as parametric studies and design optimization. Conversely, existing neural surrogates offer rapid inference but often fail to respect intrinsic PDE structures, leading to non-physical artifacts, rollout instability, and poor generalization. We present an interpretable, structure-preserving graph neural solver that bridges classical numerical principles with graph neural networks (GNNs). The network is designed as a learned reconstruction-and-flux operator rather than a black-box state updater, thereby inherently preserving key properties such as local conservation and upwinding. Inspired by Arbitrary high-order DERivatives schemes, we further recast message-passing GNNs as high-order space-time predictors, enabling conservative and stable neural updates with large time steps. Evaluation is performed on challenging supersonic flow benchmarks spanning broad parametric variations in geometry, initial/boundary conditions, and flow regimes. The neural solver achieves superior long-horizon rollout stability and accuracy compared with strong surrogate baselines, outperforms low-order discretizations, and delivers orders-of-magnitude runtime speedups over high-resolution simulations.

Keywords

Cite

@article{arxiv.2604.15617,
  title  = {A Structure-Preserving Graph Neural Solver for Parametric Hyperbolic Conservation Laws},
  author = {Jiamin Jiang and Shanglin Lv and Jingrun Chen},
  journal= {arXiv preprint arXiv:2604.15617},
  year   = {2026}
}
R2 v1 2026-07-01T12:13:42.089Z