Distributed Optimization Over Time-Varying Directed Graphs

We consider distributed optimization by a collection of nodes, each having access to its own convex function, whose collective goal is to minimize the sum of the functions. The communications between nodes are described by a time-varying sequence of directed graphs, which is uniformly strongly conne...

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Bibliographic Details
Published inIEEE transactions on automatic control Vol. 60; no. 3; pp. 601 - 615
Main Authors Nedić, Angelia, Olshevsky, Alex
Format Journal Article
LanguageEnglish
Published IEEE 01.03.2015
Subjects
Convergence
Convex functions
Equations
Optimization
Protocols
Vectors
Time-varying
UAVs
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Summary:We consider distributed optimization by a collection of nodes, each having access to its own convex function, whose collective goal is to minimize the sum of the functions. The communications between nodes are described by a time-varying sequence of directed graphs, which is uniformly strongly connected. For such communications, assuming that every node knows its out-degree, we develop a broadcast-based algorithm, termed the subgradient-push, which steers every node to an optimal value under a standard assumption of subgradient boundedness. The subgradient-push requires no knowledge of either the number of agents or the graph sequence to implement. Our analysis shows that the subgradient-push algorithm converges at a rate of O(\ln t √t). The proportionality constant in the convergence rate depends on the initial values at the nodes, the subgradient norms and, more interestingly, on both the speed of the network information diffusion and the imbalances of influence among the nodes.
ISSN:0018-9286
1558-2523
DOI:10.1109/TAC.2014.2364096