A Weighted Randomized Kaczmarz Method for Solving Linear Systems

Abstract

The Kaczmarz method for solving a linear system Ax = b interprets such a system as a collection of equations ai, x = bi, where ai is the i-th row of A, then picks such an equation and corrects xk+1 = xk + λ ai where λ is chosen so that the i-th equation is satisfied. Convergence rates are difficult to establish. Assuming the rows to be normalized, \|ai\|2=1, Strohmer \& Vershynin established that if the order of equations is chosen at random, E~ \|xk - x\|2 converges exponentially. We prove that if the i-th row is selected with likelihood proportional to | ai, xk - bi|p, where 0<p<∞, then E~\|xk - x\|2 converges faster than the purely random method. As p → ∞, the method de-randomizes and explains, among other things, why the maximal correction method works well. We empirically observe that the method computes approximations of small singular vectors of A as a byproduct.