Towards accelerated rates for distributed optimization over time-varying networks

Abstract

We study the problem of decentralized optimization over time-varying networks with strongly convex smooth cost functions. In our approach, nodes run a multi-step gossip procedure after making each gradient update, thus ensuring approximate consensus at each iteration, while the outer loop is based on accelerated Nesterov scheme. The algorithm achieves precision > 0 in O(g2(1/)) communication steps and O(g(1/)) gradient computations at each node, where g is the global function number and characterizes connectivity of the communication network. In the case of a static network, = 1/γ where γ denotes the normalized spectral gap of communication matrix W. The complexity bound includes g, which can be significantly better than the worst-case condition number among the nodes.