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Iterative Refinement for Diagonalizable Non-Hermitian Eigendecompositions

Numerical Analysis 2026-04-06 v1 Numerical Analysis

Abstract

This paper develops matrix-multiplication-based iterative refinement for diagonalizable non-Hermitian eigendecompositions. The main theory concerns simple eigenvalues and distinguishes two input regimes. In the right-only regime, where only approximate right eigenvectors and eigenvalues are available, a first-order derivation selects the update and the resulting post-update residual identity is exact, yielding a quadratic residual bound. In the left-right regime, where approximate left and right eigenvectors are both available, the computable driving matrix is an exact perturbation of the inverse-based one and the biorthogonality correction satisfies an exact Newton--Schulz-type error identity. Under a small biorthogonality error, these relations yield a local second-order estimate for the resulting WW-method. Clustered eigenvalues are handled separately by a stabilization extension based on clusterwise re-diagonalization and suppression of intracluster corrections, whose effect is verified on controlled matrices with ill-conditioned cluster bases. The method is intended as post-processing for an already accurate eigendecomposition. The attraction region is not analyzed, and no complete theory is given for the clustered case.

Keywords

Cite

@article{arxiv.2604.02840,
  title  = {Iterative Refinement for Diagonalizable Non-Hermitian Eigendecompositions},
  author = {Takeshi Terao},
  journal= {arXiv preprint arXiv:2604.02840},
  year   = {2026}
}
R2 v1 2026-07-01T11:52:32.506Z