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Novel Distributed Algorithms Design for Nonsmooth Resource Allocation on Weight-Balanced Digraphs

In this paper, the distributed resource allocation problem on strongly connected and weight-balanced digraphs is investigated, where the decisions of each agent are restricted to satisfy the coupled network resource constraints and heterogeneous general convex sets. Moreover, the local cost function can be non-smooth. In order to achieve the exact optimum of the nonsmooth resource allocation problem, a novel continuous-time distributed algorithm based on the gradient descent scheme and differentiated projection operators is proposed. With the help of the set-valued LaSalle invariance principle and nonsmooth analysis, it is demonstrated that the algorithm converges asymptotically to the global optimal allocation. Moreover, for the situation where local constraints are not involved and the cost functions are differentiable with Lipschitz gradients, the convergence of the algorithm to the exact optimal solution is exponentially fast. Finally, the effectiveness of the proposed algorithms is illustrated by simulation examples.

preprint2022arXivOpen access
Xiaohong NianFan LiDongxin Liu
math.OC
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Xiaohong NianFan LiDongxin Liu

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