Randomized Algorithms for Distributed Nonlinear Optimization Under Sparsity Constraints

Distributed optimization in multi-agent systems under sparsity constraints has recently received a lot of attention. In this paper, we consider the in-network minimization of a continuously differentiable nonlinear function which is a combination of local agent objective functions subject to sparsit...

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Bibliographic Details
Published inIEEE transactions on signal processing Vol. 64; no. 6; pp. 1420 - 1434
Main Authors Ravazzi, Chiara, Fosson, Sophie M., Magli, Enrico
Format Journal Article
LanguageEnglish
Published New York IEEE 15.03.2016
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Algorithms
Compressed sensing
Convergence
Distributed optimization
Heuristic algorithms
Links
Mathematical analysis
Mathematical models
Monitoring
Multi-agent systems
Networks
nonlinear optimization
Nonlinearity
Optimization
randomized algorithms
Signal processing algorithms
sparse signal recovery
Sparsity
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Summary:Distributed optimization in multi-agent systems under sparsity constraints has recently received a lot of attention. In this paper, we consider the in-network minimization of a continuously differentiable nonlinear function which is a combination of local agent objective functions subject to sparsity constraints on the variables. A crucial issue of in-network optimization is the handling of the communications, which may be expensive. This calls for efficient algorithms, that are able to reduce the number of required communication links and transmitted messages. To this end, we focus on asynchronous and randomized distributed techniques. Based on consensus techniques and iterative hard thresholding methods, we propose three methods that attempt to minimize the given function, promoting sparsity of the solution: asynchronous hard thresholding (AHT), broadcast hard thresholding (BHT), and gossip hard thresholding (GHT). Although similar in many aspects, it is difficult to obtain a unified analysis for the proposed algorithms. Specifically, we theoretically prove the convergence and characterize the limit points of AHT in regular networks under some proper assumptions on the functions to be minimized. For BHT and GHT, instead, we characterize the fixed points of the maps that rule their dynamics in terms of stationary points of original problem. Finally, we illustrate the implementation of our techniques in compressed sensing and present several numerical results on performance and number of transmissions required for convergence.
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ISSN:1053-587X
1941-0476
DOI:10.1109/TSP.2015.2500887