Abstract The homogenization approach is widely used in lattice structure design to simplify modeling of complex geometries by representing them as simple solid elements in Finite Element Analysis (FEA). Homogenized material properties are obtained through microscale analysis of a Representative Volume Element (RVE). Several methods exist to compute effective properties, including beam theory, asymptotic homogenization, and the finite element method. FEA is commonly used for its ability to model arbitrary lattice geometries accurately. However, for complex structures, conventional FEA is computationally expensive, requiring extensive preprocessing and producing large stiffness matrices, which reduces efficiency in multiscale analysis and optimization. This study introduces an image-based machine learning framework for efficient microscale modeling of arbitrarily shaped lattice structures. Unlike traditional surrogate modeling approaches that rely solely on machine learning, the novelty of this method lies in maintaining consistency between physical modeling and machine learning representations. Specifically, the binary matrix obtained via image processing is used to generate the finite element model for asymptotic homogenization (AH)–based microscale analyses, whose outputs train a Convolutional Neural Network (CNN). This eliminates the need for conventional mesh generation and ensures the network learns from physically consistent data. The CNN framework enables rapid and accurate prediction of effective material properties from image-based RVE representations. The developed CNN model showed a Mean Absolute Error of 1.60% and a Mean Squared Error of 0.08% for predicting the homogenized material properties at the fraction of computational time for traditional FEA.
Mahdi et al. (Tue,) studied this question.