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Resolution of subgrid microscale interactions enhances the discretisation of nonautonomous partial differential equations

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 Added by Judith Bunder
 Publication date 2013
  fields
and research's language is English




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Coarse grained, macroscale, spatial discretisations of nonlinear nonautonomous partial differentialdifference equations are given novel support by centre manifold theory. Dividing the physical domain into overlapping macroscale elements empowers the approach to resolve significant subgrid microscale structures and interactions between neighbouring elements. The crucial aspect of this approach is that centre manifold theory organises the resolution of the detailed subgrid microscale structure interacting via the nonlinear dynamics within and between neighbouring elements. The techniques and theory developed here may be applied to soundly discretise on a macroscale many dissipative nonautonomous partial differentialdifference equations, such as the forced Burgers equation, adopted here as an illustrative example.



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