Wavelet-based Galerkin Scheme with Arbitrarily High-Order Convergence for 1D Elliptic Interface Problems
Abstract
The solution u of an elliptic interface problem in a domain is often smooth away from the interface ⊂ , but its gradient is discontinuous across , resulting in low regularity; in particular, u H1.5(). This paper focuses on 1D elliptic interface problems using wavelet methods. We propose a Galerkin method using locally supported biorthogonal wavelet bases on bounded intervals with mth approximation order for any integer m 2. Additionally, we rigorously prove that its convergence rates are of order m-1 in the H1()-norm and order m in the L2()-norm, which are optimal with respect to the scheme's approximation order m. Our approach involves incorporating wavelet basis functions from higher scale levels to capture the singularity in the neighbourhood of the interface . The results in this paper both complement and sharply contrast our findings in Han and Michelle (2024), where we consider a similar wavelet-based method for solving d-dimensional elliptic interface problems with d 2.
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