Image-based adaptive domain decomposition for continuum damage models

TL;DR

This paper introduces an innovative image-based adaptive domain decomposition FEM framework that leverages image processing to efficiently solve continuum damage mechanics problems by dynamically identifying damage interfaces and optimizing computational effort.

Contribution

The novel aspect is the integration of image-processing techniques with FEM for adaptive domain decomposition in damage modeling, enabling efficient and accurate simulations of propagating damage.

Findings

Demonstrates accuracy and efficiency over single domain methods

Ensures robustness across various damage laws and mesh types

Compatible with complex damage propagation scenarios

Abstract

We present a novel image-based adaptive domain decomposition FEM framework to accelerate the solution of continuum damage mechanics problems. The key idea is to use image-processing techniques in order to identify the moving interface between the healthy subdomain and unhealthy subdomain as damage propagates, and then use an iterative Schur complement approach to efficiently solve the problem. The implementation of the algorithm consists of several modular components. Following the FEM solution of a load increment, the damage detection module is activated, a step that is based on several image-processing operations including colormap manipulation and morphological convolution-based operations. Then, the damage tracking module is invoked, to identify the crack growth direction using geometrical operations and ray casting algorithm. This information is then passed into the domain decomposition module, where the domain is divided into the healthy subdomain which contains only undamaged elements, and the unhealthy subdomain which comprises both damaged and undamaged elements. Continuity between the two regions is restored using penalty constraints. The computational savings of our method stem from the Schur complement, which allows for the iterative solution of the system of equations appertaining only to the unhealthy subdomain. Through an exhaustive comparison between our approach and single domain computations, we demonstrate the accuracy, efficiency, and robustness of the framework. We ensure its compatibility against local and non-local damage laws, structured and unstructured meshes, as well as in cases where different damage paths eventually merge. Since the key novelty lies in using image processing tools to inform the decomposition, our framework can be readily extended beyond damage mechanics and model several classes of non-linear problems such as plasticity and phase-field.