Distributed Solvers for Network Linear Equations with Scalarized Compression

In this paper, we study distributed solvers for network linear equations over a network with node-to-node communication messages compressed as scalar values. Our key idea lies in a dimension compression scheme including a dimension compressing vector that applies to individual node states to generate a real-valued message for node communication as an inner product, and a data unfolding step in the local computations where the scalar message is plotted along the subspace generated by the compression vector. We first present a compressed average consensus flow that relies only on such scalar communication, and show that exponential convergence can be achieved with well excited signals for the compression vector. We then employ such a compressed consensus flow as a fundamental consensus subroutine to develop distributed continuous-time and discrete-time solvers for network linear equations, and prove their exponential convergence properties under scalar node communications. With scalar communications, a direct benefit would be the reduced node-to-node communication channel capacity requirement for distributed computing. Numerical examples are presented to illustrate the effectiveness of the established theoretical results.