The regularization theory of the Krylov iterative solvers LSQR and CGLS for linear discrete ill-posed problems, part I: the simple singular value case

Abstract

For the large-scale linear discrete ill-posed problem \|Ax-b\| or Ax=b with b contaminated by a white noise, the Lanczos bidiagonalization based LSQR method and its mathematically equivalent Conjugate Gradient (CG) method for ATAx=ATb are most commonly used. They have intrinsic regularizing effects, where the number k of iterations plays the role of regularization parameter. However, there has been no answer to the long-standing fundamental concern by Björck and Eldén in 1979: for which kinds of problems LSQR and CGLS can find best possible regularized solutions? Here a best possible regularized solution means that it is at least as accurate as the best regularized solution obtained by the truncated singular value decomposition (TSVD) method or standard-form Tikhonov regularization. In this paper, assuming that the singular values of A are simple, we analyze the regularization of LSQR for severely, moderately and mildly ill-posed problems. We establish accurate estimates for the 2-norm distance between the underlying k-dimensional Krylov subspace and the k-dimensional dominant right singular subspace of A. For the first two kinds of problems, we then prove that LSQR finds a best possible regularized solution at semi-convergence occurring at iteration k0 and that, for k=1,2,…,k0, (i) the k-step Lanczos bidiagonalization always generates a near best rank k approximation to A; (ii) the k Ritz values always approximate the first k large singular values in natural order; (iii) the k-step LSQR always captures the k dominant SVD components of A. For the third kind of problem, we prove that LSQR generally cannot find a best possible regularized solution. Numerical experiments confirm our theory.