AbstractSIRT and CG-type methods have been successfully employed for the approximate solution of least-squares problems arising in tomography. In this paper we study and compare their convergence and regularization properties. It is pointed out that SIRT methods apply an uncontrollable implicit rescaling which affects the statistical characteristics of the system, whereas CG-type methods do not. For a large class of model problems it is shown that virtually the same solutions as obtained by SIRT methods can be obtained by applying a CG-type method to a properly rescaled system, but with an amount of work proportional to the square root of the amount of work with SIRT
During the last two decades, iterative computerized tomography (CT) algorithms, such as ART (Algebra...
Abstract—In this paper, we propose a novel algorithm for analysis-based sparsity reconstruction. It ...
In an earlier paper, we generalized the CGME (Conjugate Gradient Minimal Error) algorithm to the ℓ2-...
AbstractSIRT and CG-type methods have been successfully employed for the approximate solution of lea...
Tomography in seismology often leads to underdetermined and inconsistent systems of linear equations...
This research investigates iterative methods for solving large and sparse least squares problems, as...
In this paper, we consider a regularized least squares problem subject to convex constraints. Our al...
AbstractWe present a MATLAB package with implementations of several algebraic iterative reconstructi...
In this work we solve inverse problems coming from the area of Computed Tomography by means of regul...
We investigate a constrained version of simultaneous iterative reconstruction techniques(SIRT) from ...
We introduce and compare new compression approaches to obtain regularized solutions of large linear ...
One approach to the image reconstruction problem in Computed Tomography (CT) is to solve a least sq...
A problem frequently encountered in the earth sciences requires deducing physical parameters of the ...
AbstractThe equivalence of minimum-norm least-squares solutions of systems of linear equations and s...
We present a discrepancy-like stopping criterium for iterative regularization methods for the soluti...
During the last two decades, iterative computerized tomography (CT) algorithms, such as ART (Algebra...
Abstract—In this paper, we propose a novel algorithm for analysis-based sparsity reconstruction. It ...
In an earlier paper, we generalized the CGME (Conjugate Gradient Minimal Error) algorithm to the ℓ2-...
AbstractSIRT and CG-type methods have been successfully employed for the approximate solution of lea...
Tomography in seismology often leads to underdetermined and inconsistent systems of linear equations...
This research investigates iterative methods for solving large and sparse least squares problems, as...
In this paper, we consider a regularized least squares problem subject to convex constraints. Our al...
AbstractWe present a MATLAB package with implementations of several algebraic iterative reconstructi...
In this work we solve inverse problems coming from the area of Computed Tomography by means of regul...
We investigate a constrained version of simultaneous iterative reconstruction techniques(SIRT) from ...
We introduce and compare new compression approaches to obtain regularized solutions of large linear ...
One approach to the image reconstruction problem in Computed Tomography (CT) is to solve a least sq...
A problem frequently encountered in the earth sciences requires deducing physical parameters of the ...
AbstractThe equivalence of minimum-norm least-squares solutions of systems of linear equations and s...
We present a discrepancy-like stopping criterium for iterative regularization methods for the soluti...
During the last two decades, iterative computerized tomography (CT) algorithms, such as ART (Algebra...
Abstract—In this paper, we propose a novel algorithm for analysis-based sparsity reconstruction. It ...
In an earlier paper, we generalized the CGME (Conjugate Gradient Minimal Error) algorithm to the ℓ2-...