Multiscale simulation of polymeric fluids using the sparse grid combination technique
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摘要
We present a computationally efficient sparse grid approach to allow for multiscale simulations of non-Newtonian polymeric fluids. Multiscale approaches for polymeric fluids often involve model equations of high dimensionality. A conventional numerical treatment of such equations leads to computing times in the order of months even on massively parallel computers.For a reduction of this enormous complexity, we propose the sparse grid combination technique. Compared to classical full grid approaches, the combination technique strongly reduces the computational complexity of a numerical scheme but only slightly decreases its accuracy.Here, we use the combination technique in a general formulation that balances not only different discretization errors but also considers the accuracy of the mathematical model. For an optimal weighting of these different problem dimensions, we employ a dimension-adaptive refinement strategy. We finally verify substantial cost reductions of our approach for simulations of non-Newtonian Couette and extensional flow problems.
论文关键词:Sparse grids,Combination technique,Dimension-adaptivity,Multiscale simulation,Brownian configuration fields,Multi-bead spring-chains
论文评审过程:Received 1 October 2016, Revised 1 March 2017, Accepted 16 April 2017, Available online 16 May 2017, Version of Record 31 October 2017.
论文官网地址:https://doi.org/10.1016/j.amc.2017.04.025