English

Regularization of Inverse Problems by Filtered Diagonal Frame Decomposition under general source

Numerical Analysis 2025-08-01 v1 Numerical Analysis Analysis of PDEs

Abstract

Let XX and YY be Hilbert spaces, and K:domKXY\mathbf{K}: \text{dom} \mathbf{K} \subset X \to Y a bounded linear operator. This paper addresses the inverse problem Kx=y\mathbf{K}x = y, where exact data yy is replaced by noisy data yδy^\delta satisfying yδyYδ\|y^\delta - y\|_Y \leq \delta. Due to the ill-posedness of such problems, we employ regularization methods to stabilize solutions. While singular value decomposition (SVD) provides a classical approach, its computation can be costly and impractical for certain operators. We explore alternatives via Diagonal Frame Decomposition (DFD), generalizing SVD-based techniques, and introduce a regularized solution xαδ=λΛκλgα(κλ2)yδ,vλuλx^\delta_\alpha = \sum_{\lambda \in \Lambda} \kappa_\lambda g_\alpha(\kappa_\lambda^2) \langle y^\delta, v_\lambda \rangle \overline{u}_\lambda. Convergence rates and optimality are analyzed under a generalized source condition Mφ,E={xdomK:λΛ[φ(κλ2)]1x,uλ2E2}\mathbf{M}_{\varphi, E} = \{ x \in \text{dom} \mathbf{K} : \sum_{\lambda \in \Lambda} [\varphi(\kappa_\lambda^2)]^{-1} |\langle x, u_\lambda \rangle|^2 \leq E^2 \}. Key questions include constructing DFD systems, relating DFD and SVD singular values, and extending source conditions. We present theoretical results, including modulus of continuity bounds and convergence rates for a priori and a posteriori parameter choices, with applications to polynomial and exponentially ill-posed problems.

Keywords

Cite

@article{arxiv.2507.23651,
  title  = {Regularization of Inverse Problems by Filtered Diagonal Frame Decomposition under general source},
  author = {Dang Duc Trong and Nguyen Dang Minh and Luu Xuan Thang and Luu Dang Khoa},
  journal= {arXiv preprint arXiv:2507.23651},
  year   = {2025}
}
R2 v1 2026-07-01T04:28:03.287Z