Residual-Weighted Randomized Jacobi: Sharpened Bounds via Residual Concentration and Asynchronous Extension

Abstract

We study randomized stationary methods for symmetric positive definite linear systems in which component j is selected with probability proportional to |rj|. This power-weighted family interpolates continuously between uniform randomized Jacobi as 0 and Gauss--Southwell greedy relaxation as ∞. For the central case = 2, we sharpen the standard one-step convergence analysis using the inverse participation ratio (IPR) ν2(r) = n\|r\|44/\|r\|24, which equals 1 when the residual is uniform and grows toward n as it concentrates. The resulting bound amplifies the expected per-step progress by exactly ν2 over the uniform-sampling baseline. The IPR can be computed online at O(n) cost and doubles as a per-iteration diagnostic. We extend the analysis to asynchronous power-weighted Jacobi via the Avron--Druinsky--Gupta framework, obtaining an epoch-based convergence theorem in which the IPR controls both the progress coefficient and the allowed-delay window. Numerical experiments on shared-memory hardware support the sharpened bound and show the IPR trajectory is essentially concurrency-insensitive. Unexpectedly, consistent-reads execution, the easier case for the ADG analysis, destabilizes power-weighted sampling at high concurrency while inconsistent reads remain stable; the same IPR that amplifies progress amplifies a thread-collision rate that inconsistent reads appear to absorb. We propose a feedback-damping mechanism and verify two predictions about its dependence on problem size.