Sensor Network Localization, Euclidean Distance Matrix Completions, and Graph Realization
Abstract
We study Semidefinite Programming, relaxations for Sensor Network Localization, with anchors and with noisy distance information. The main point of the paper is to view as a (nearest) Euclidean Distance Matrix, , completion problem and to show the advantages for using this latter, well studied model. We first show that the current popular relaxation is equivalent to known relaxations in the literature for completions. The existence of anchors in the problem is not special. The set of anchors simply corresponds to a given fixed clique for the graph of the problem. We next propose a method of projection when a large clique or a dense subgraph is identified in the underlying graph. This projection reduces the size, and improves the stability, of the relaxation. In addition, viewing the problem as an completion problem yields better low rank approximations for the low dimensional realizations. And, the projection/reduction procedure can be repeated for other given cliques of sensors or for sets of sensors, where many distances are known. Thus, further size reduction can be obtained. Optimality/duality conditions and a primal-dual interior-exterior path following algorithm are derived for the relaxations We discuss the relative stability and strength of two formulations and the corresponding algorithms that are used. In particular, we show that the quadratic formulation arising from the relaxation is better conditioned than the linearized form, that is used in the literature and that arises from applying a Schur complement.
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