English

PDE-SHARP: PDE Solver Hybrids through Analysis and Refinement Passes

Machine Learning 2025-11-06 v2

Abstract

Current LLM-driven approaches using test-time computing to generate PDE solvers execute a large number of solver samples to identify high-accuracy solvers. These paradigms are especially costly for complex PDEs requiring substantial computational resources for numerical evaluation. We introduce PDE-SHARP, a framework to reduce computational costs by replacing expensive scientific computation by cheaper LLM inference that achieves superior solver accuracy with 60-75% fewer computational evaluations. PDE-SHARP employs three stages: (1) Analysis: mathematical chain-of-thought analysis including PDE classification, solution type detection, and stability analysis; (2) Genesis: solver generation based on mathematical insights from the previous stage; and (3) Synthesis: collaborative selection-hybridization tournaments in which LLM judges iteratively refine implementations through flexible performance feedback. To generate high-quality solvers, PDE-SHARP requires fewer than 13 solver evaluations on average compared to 30+ for baseline methods, improving accuracy uniformly across tested PDEs by 4×4\times on average, and demonstrates robust performance across LLM architectures, from general-purpose to specialized reasoning models.

Cite

@article{arxiv.2511.00183,
  title  = {PDE-SHARP: PDE Solver Hybrids through Analysis and Refinement Passes},
  author = {Shaghayegh Fazliani and Madeleine Udell},
  journal= {arXiv preprint arXiv:2511.00183},
  year   = {2025}
}
R2 v1 2026-07-01T07:16:24.809Z