Abstract. We study multi-parameter regularization (multiple penalties) for solving linear inverse problems to promote simultaneously distinct features of the sought-for objects. We revisit a balancing principle for choosing regularization parameters from the viewpoint of augmented Tikhonov regularization, and derive a new parameter choice strategy called the balanced discrepancy principle. A priori and a posteriori error estimates are provided to theoretically justify the principles, and numerical algorithms for efficiently implementing the principles are also provided. Numerical results on denoising are presented to illustrate the feasibility of the balanced discrepancy principle
Discretization of linear inverse problems generally gives rise to very ill-conditioned linear system...
Parameter identification problems for partial differential equations (PDEs) often lead to large-scal...
We present a discrepancy-based parameter choice and stopping rule for iterative algorithms performin...
Tikhonov regularization is a cornerstone technique in solving inverse problems with applications in ...
We address the classical issue of appropriate choice of the regularization and dis-cretization level...
In this paper, we propose a new strategy for a priori choice of reg-ularization parameters in Tikhon...
A Generalized Tikhonov Regularization Using Two Parameters Applied to Linear Inverse Ill-Posed Probl...
AbstractIn this paper, we study the multi-parameter Tikhonov regularization method which adds multip...
This paper introduces a new strategy for setting the regularization parameter when solving large-sca...
Multiplicative regularization solves a linear inverse problem by minimizing the product of the norm ...
summary:We give a derivation of an a-posteriori strategy for choosing the regularization parameter i...
For the solution of linear ill-posed problems, in this paper we introduce a simple algorithm for the...
AbstractWe discuss adaptive strategies for choosing regularization parameters in Tikhonov–Phillips r...
Tikhonov regularization is a popular method to approximate solutions of linear discrete ill-posed pr...
Tikhonov regularization is one of the most popular approaches to solve discrete ill-posed problems w...
Discretization of linear inverse problems generally gives rise to very ill-conditioned linear system...
Parameter identification problems for partial differential equations (PDEs) often lead to large-scal...
We present a discrepancy-based parameter choice and stopping rule for iterative algorithms performin...
Tikhonov regularization is a cornerstone technique in solving inverse problems with applications in ...
We address the classical issue of appropriate choice of the regularization and dis-cretization level...
In this paper, we propose a new strategy for a priori choice of reg-ularization parameters in Tikhon...
A Generalized Tikhonov Regularization Using Two Parameters Applied to Linear Inverse Ill-Posed Probl...
AbstractIn this paper, we study the multi-parameter Tikhonov regularization method which adds multip...
This paper introduces a new strategy for setting the regularization parameter when solving large-sca...
Multiplicative regularization solves a linear inverse problem by minimizing the product of the norm ...
summary:We give a derivation of an a-posteriori strategy for choosing the regularization parameter i...
For the solution of linear ill-posed problems, in this paper we introduce a simple algorithm for the...
AbstractWe discuss adaptive strategies for choosing regularization parameters in Tikhonov–Phillips r...
Tikhonov regularization is a popular method to approximate solutions of linear discrete ill-posed pr...
Tikhonov regularization is one of the most popular approaches to solve discrete ill-posed problems w...
Discretization of linear inverse problems generally gives rise to very ill-conditioned linear system...
Parameter identification problems for partial differential equations (PDEs) often lead to large-scal...
We present a discrepancy-based parameter choice and stopping rule for iterative algorithms performin...