English

An efficient and stable diffusion generated method for quadrilateral mesh generation in general domains

Numerical Analysis 2026-05-28 v1 Numerical Analysis

Abstract

This paper introduces a novel, robust, and computationally efficient framework for high-quality quadrilateral mesh generation on general two-dimensional domains. The core of the proposed approach is a novel method for computing cross fields by minimizing a modified and relaxed Ginzburg--Landau-type energy functional. A key innovation is the extension of the problem from the original, potentially complex domain to a larger regular computational domain. This extension transforms the central computational procedure into an iterative scheme that requires only two straightforward and efficient operations: linear diffusion solved globally via the Fast Fourier Transform (FFT) and point-wise normalization. Notably, our method eliminates the conventional need for generating an intermediate triangular mesh or solving complex nonlinear optimization problems on the irregular domain. We provide a rigorous theoretical analysis, proving that the proposed iterative algorithm guarantees unconditional monotonic decay of the objective functional. Comprehensive numerical experiments demonstrate the method's robustness across a wide range of complex geometries, its significant computational efficiency afforded by the FFT-based diffusion, and its consistent generation of high-quality quadrilateral meshes. This work presents a reliable and theoretically sound alternative to existing mesh generation techniques, with strong potential for practical applications in scientific computing.

Keywords

Cite

@article{arxiv.2605.27854,
  title  = {An efficient and stable diffusion generated method for quadrilateral mesh generation in general domains},
  author = {Jingwen Dai and Zhonghua Qiao and Dong Wang},
  journal= {arXiv preprint arXiv:2605.27854},
  year   = {2026}
}