Saved in:
Bibliographic Details
Main Authors: Coco, Armando, Coclite, Alessandro, Clain, Stéphane, Pereira, Rui Miguel
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.15539
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866911600821141504
author Coco, Armando
Coclite, Alessandro
Clain, Stéphane
Pereira, Rui Miguel
author_facet Coco, Armando
Coclite, Alessandro
Clain, Stéphane
Pereira, Rui Miguel
contents Unfitted boundary methods are widely used to numerically solve partial differential equations (PDEs) on irregular domains, avoiding the computational burden of generating boundary-conforming grids. In the finite-difference framework, structured Cartesian grids offer advantages such as ease of implementation and efficient parallelization, while geometry is represented implicitly, for instance, through level-set functions. In this setting, ghost point methods are commonly employed to enforce boundary conditions by introducing additional relations between interior and ghost nodes. However, constructing these relations becomes challenging for high-order accurate discretizations, which often rely on wide stencils that can reduce computational efficiency and degrade performance in large-scale parallel simulations. In this work, we investigate alternative ghost-point discretizations based on compact stencils. We introduce a formulation based on a boundary operator that locally approximates the boundary condition near each ghost node, replacing it with linear relations involving both interior and ghost points. The operator is constructed via least-squares reconstruction, allowing flexible stencil configurations while preserving the desired order of accuracy. Several strategies for selecting and adapting compact stencils are proposed, guided by conditioning criteria and iterative refinement procedures to improve global stability. Numerical experiments on various geometries and convection-diffusion regimes demonstrate the effectiveness of the proposed approach, showing that it maintains high accuracy even in the presence of boundary layers and improves stencil compactness and conditioning of the resulting linear systems.
format Preprint
id arxiv_https___arxiv_org_abs_2604_15539
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Efficient and well-conditioned ghost-point discretization of boundary operators on unfitted domains
Coco, Armando
Coclite, Alessandro
Clain, Stéphane
Pereira, Rui Miguel
Numerical Analysis
65N06
G.1.8
Unfitted boundary methods are widely used to numerically solve partial differential equations (PDEs) on irregular domains, avoiding the computational burden of generating boundary-conforming grids. In the finite-difference framework, structured Cartesian grids offer advantages such as ease of implementation and efficient parallelization, while geometry is represented implicitly, for instance, through level-set functions. In this setting, ghost point methods are commonly employed to enforce boundary conditions by introducing additional relations between interior and ghost nodes. However, constructing these relations becomes challenging for high-order accurate discretizations, which often rely on wide stencils that can reduce computational efficiency and degrade performance in large-scale parallel simulations. In this work, we investigate alternative ghost-point discretizations based on compact stencils. We introduce a formulation based on a boundary operator that locally approximates the boundary condition near each ghost node, replacing it with linear relations involving both interior and ghost points. The operator is constructed via least-squares reconstruction, allowing flexible stencil configurations while preserving the desired order of accuracy. Several strategies for selecting and adapting compact stencils are proposed, guided by conditioning criteria and iterative refinement procedures to improve global stability. Numerical experiments on various geometries and convection-diffusion regimes demonstrate the effectiveness of the proposed approach, showing that it maintains high accuracy even in the presence of boundary layers and improves stencil compactness and conditioning of the resulting linear systems.
title Efficient and well-conditioned ghost-point discretization of boundary operators on unfitted domains
topic Numerical Analysis
65N06
G.1.8
url https://arxiv.org/abs/2604.15539