English

Regularization of inverse problems via box constrained minimization

Optimization and Control 2018-07-31 v1 Functional Analysis

Abstract

In the present paper we consider minimization based formulations of inverse problems (x,Φ)\mboxargmin{J(x,Φ;y) ⁣:(x,Φ)Mad(y)}(x,\Phi)\in\mbox{argmin}\{\mathcal{J}(x,\Phi;y)\colon(x,\Phi)\in M_{ad}(y) \} for the specific but highly relevant case that the admissible set Madδ(yδ)M_{ad}^\delta(y^\delta) is defined by pointwise bounds, which is the case, e.g., if LL^\infty constraints on the parameter are imposed in the sense of Ivanov regularization, and the LL^\infty noise level in the observations is prescribed in the sense of Morozov regularization. As application examples for this setting we consider three coefficient identification problems in elliptic boundary value problems. Discretization of (x,Φ)(x,\Phi) with piecewise constant and piecewise linear finite elements, respectively, leads to finite dimensional nonlinear box constrained minimization problems that can numerically be solved via Gauss-Newton type SQP methods. In our computational experiments we revisit the suggested application examples. In order to speed up the computations and obtain exact numerical solutions we use recently developed active set methods for solving strictly convex quadratic programs with box constraints as subroutines within our Gauss-Newton type SQP approach.

Keywords

Cite

@article{arxiv.1807.11316,
  title  = {Regularization of inverse problems via box constrained minimization},
  author = {Philipp Hungerländer and Barbara Kaltenbacher and Franz Rendl},
  journal= {arXiv preprint arXiv:1807.11316},
  year   = {2018}
}
R2 v1 2026-06-23T03:18:54.846Z