Temizer, I.Wu, T.Wriggers, P.2016-02-082016-02-0820130020-7225http://hdl.handle.net/11693/21078The window method, where the microstructural sample is embedded into a frame of a homogeneous material, offers an alternative to classical boundary conditions in computational homogenization. Experience with the window method, which is essentially the self-consistent scheme but with a finite surrounding medium instead of an infinite one, indicates that it delivers faster convergence of the macroscopic response with respect to boundary conditions of pure essential or natural type as the microstructural sample size is increased to ensure statistical representativeness. In this work, the variational background for this observed optimal convergence behavior of the homogenization results with the window method is provided and the method is compared with periodic boundary conditions that it closely resembles. © 2013 Elsevier Ltd. All rights reserved.EnglishComputational homogenizationSelf-consistent schemeThermal conductionComputational homogenizationFaster convergenceHomogeneous materialsMacroscopic responseMicro-structuralOptimal convergenceOptimalityPeriodic boundary conditionsSample sizesSelf-consistent schemeThermal conductionWindow methodsBoundary conditionsOptimizationHomogenization methodOn the optimality of the window method in computational homogenizationArticle10.1016/j.ijengsci.2012.12.007