Sublinear-Time Algorithms for Diagonally Dominant Systems and Applications to the Friedkin-Johnsen Model

Abstract

We study sublinear-time algorithms for solving linear systems Sz = b, where S is a diagonally dominant matrix, i.e., |Sii| ≥ δ + Σj i |Sij| for all i ∈ [n], for some δ ≥ 0. We present randomized algorithms that, for any u ∈ [n], return an estimate zu of z*u with additive error or z*∞, where z* is some solution to Sz* = b, and the algorithm only needs to read a small portion of the input S and b. For example, when the additive error is and assuming δ>0, we give an algorithm that runs in time O( \|b\|∞2 Sδ3 2 \| b \|∞δ ), where S = i ∈ [n] |Sii|. We also prove a matching lower bound, showing that the linear dependence on S is optimal. Unlike previous sublinear-time algorithms, which apply only to symmetric diagonally dominant matrices with non-negative diagonal entries, our algorithm works for general strictly diagonally dominant matrices (δ > 0) and a broader class of non-strictly diagonally dominant matrices (δ = 0). Our approach is based on analyzing a simple probabilistic recurrence satisfied by the solution. As an application, we obtain an improved sublinear-time algorithm for opinion estimation in the Friedkin--Johnsen model.