Litcius/Paper detail

Imposing different boundary conditions for thermal computational homogenization problems with FFT‐ and tensor‐train‐based Green's operator methods

Lennart Risthaus, Matti Schneider

2024International Journal for Numerical Methods in Engineering19 citationsDOIOpen Access PDF

Abstract

Abstract To compute the effective properties of random heterogeneous materials, a number of different boundary conditions are used to define the apparent properties on cells of finite size. Typically, depending on the specific boundary condition, different numerical methods are used. The article at hand provides a unified framework for Lippmann–Schwinger solvers in thermal conductivity and Dirichlet (prescribed temperature), Neumann (prescribed normal heat flux) as well as periodic boundary conditions. We focus on the explicit jump finite‐difference discretization and discuss different techniques for computing the discrete Green's operator. These include Fourier‐type methods, that is, based on discrete sine, cosine and Fourier transformations, as well as low‐rank tensor methods, that is, the tensor‐train approximation, whose computational prowess was demonstrated recently. We use the developed computational technology to investigate a number of interesting random materials and assess different microstructure‐generation techniques in terms of their compatibility with the prescribed boundary conditions.

Topics & Concepts

MathematicsDiscretizationBoundary value problemHomogenization (climate)Mathematical analysisPeriodic boundary conditionsFast Fourier transformApplied mathematicsAlgorithmBiodiversityEcologyBiologyComposite Material MechanicsNumerical methods in engineeringAdvanced Mathematical Modeling in Engineering