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Main Authors: He, Tianlong, Karamian-Surville, Philippe, Choï, Daniel
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.02268
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author He, Tianlong
Karamian-Surville, Philippe
Choï, Daniel
author_facet He, Tianlong
Karamian-Surville, Philippe
Choï, Daniel
contents In this paper, we introduce the Phantom Domain Finite Element Method (PDFEM), a novel computational approach tailored for the efficient analysis of heterogeneous and composite materials. Inspired by fictitious domain methods, this method employs a structured mesh to discretize the entire material domain while utilizing separate, independent meshes for the inclusions. These inclusion meshes are coupled to the structured mesh via a substitution matrix, enabling them to act as phantom meshes that do not directly contribute to the final system of equations. This framework offers significant advantages, including enhanced flexibility in handling complex inclusion geometries and improved computational efficiency. To assess the accuracy and robustness of the proposed method, numerical experiments are conducted on structures containing inclusions of various geometries. In order to emphasize the efficiency of the PDFEM method, a numerical simulation is presented to highlight its advantages in the case of long natural fibers, such as flax and linen. These simulations are compared against FEM calculations, demonstrating the efficiency of PDFEM. Indeed, meshing such fine structures requires an extremely high number of elements, and in some cases, meshing becomes particularly challenging due to the complexity of the geometries.
format Preprint
id arxiv_https___arxiv_org_abs_2505_02268
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Phantom Domain Finite Element Method: A novel approach for heterogeneous materials
He, Tianlong
Karamian-Surville, Philippe
Choï, Daniel
Numerical Analysis
In this paper, we introduce the Phantom Domain Finite Element Method (PDFEM), a novel computational approach tailored for the efficient analysis of heterogeneous and composite materials. Inspired by fictitious domain methods, this method employs a structured mesh to discretize the entire material domain while utilizing separate, independent meshes for the inclusions. These inclusion meshes are coupled to the structured mesh via a substitution matrix, enabling them to act as phantom meshes that do not directly contribute to the final system of equations. This framework offers significant advantages, including enhanced flexibility in handling complex inclusion geometries and improved computational efficiency. To assess the accuracy and robustness of the proposed method, numerical experiments are conducted on structures containing inclusions of various geometries. In order to emphasize the efficiency of the PDFEM method, a numerical simulation is presented to highlight its advantages in the case of long natural fibers, such as flax and linen. These simulations are compared against FEM calculations, demonstrating the efficiency of PDFEM. Indeed, meshing such fine structures requires an extremely high number of elements, and in some cases, meshing becomes particularly challenging due to the complexity of the geometries.
title Phantom Domain Finite Element Method: A novel approach for heterogeneous materials
topic Numerical Analysis
url https://arxiv.org/abs/2505.02268