English

Quantile-RK and Double Quantile-RK Error Horizon Analysis

Numerical Analysis 2025-07-14 v2 Numerical Analysis

Abstract

In solving linear systems of equations of the form Ax=bAx=b, corruptions present in bb affect stochastic iterative algorithms' ability to reach the true solution xx^\ast to the uncorrupted linear system. The randomized Kaczmarz method converges in expectation to xx^\ast up to an error horizon dependent on the conditioning of AA and the supremum norm of the corruption in bb. To avoid this error horizon in the sparse corruption setting, previous works have proposed quantile-based adaptations that make iterative methods robust. Our work first establishes a new convergence rate for the quantile-based random Kaczmarz (qRK) and double quantile-based random Kaczmarz (dqRK) methods, which, under certain conditions, improves upon known bounds. We further consider the more practical setting in which the vector bb includes both non-sparse ``noise" and sparse ``corruption". Error horizon bounds for qRK and dqRK are derived and shown to produce a smaller error horizon compared to their non-quantile-based counterparts, further demonstrating the advantages of quantile-based methods.

Keywords

Cite

@article{arxiv.2505.00258,
  title  = {Quantile-RK and Double Quantile-RK Error Horizon Analysis},
  author = {Emeric Battaglia and Anna Ma},
  journal= {arXiv preprint arXiv:2505.00258},
  year   = {2025}
}
R2 v1 2026-06-28T23:17:34.875Z