핵심 개념
The authors propose a low-dimensional coarse approximation space based on a coarse polygonal partitioning of the domain to efficiently solve diffusion problems in perforated domains. The coarse space is spanned by locally discrete harmonic basis functions with piecewise polynomial traces along the subdomain boundaries. The method provides superconvergence for a specific edge refinement procedure, even if the true solution has low regularity.
초록
The content presents a numerical strategy for solving diffusion problems in perforated domains, which arise in applications such as urban flood modeling. The key aspects are:
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Coarse Mesh and Space Decomposition:
- The domain is partitioned into a coarse polygonal mesh Ω𝑗.
- The solution is decomposed into a locally harmonic component 𝑢Δ and a local "bubble" component 𝑢𝑏.
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Continuous Trefftz Approximation:
- A finite-dimensional coarse space 𝑉𝐻,𝑝is introduced, spanned by functions that are piecewise polynomial on the coarse skeleton Γ.
- An error estimate is provided, showing that the error in approximating 𝑢Δ by the Trefftz space depends only on the regularity of the solution along the coarse edges.
- For a specific edge refinement procedure, the error analysis establishes superconvergence of the method.
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Discrete Trefftz Space and Two-level Schwarz Method:
- The continuous Trefftz space is discretized using a finite element approach.
- The discrete Trefftz space is combined with a two-level domain decomposition method, leading to an efficient iterative linear solver.
- The coarse Trefftz space can also be used as a preconditioner for Krylov methods, providing robustness and scalability with respect to the number of subdomains.
The proposed method aims to achieve computational efficiency compared to classical fine-scale solution methods, while handling the multiscale features of the urban geometries.