Distributed Maximum Likelihood Sensor Network Localization

Distributed Maximum Likelihood Sensor Network Localization

We propose a class of convex relaxations to solve the sensor network localization problem, based on a maximum likelihood (ML) formulation. This class, as well as the tightness of the relaxations, depends on the noise probability density function (PDF) of the collected measurements. We derive a compu...

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Veröffentlicht in:IEEE transactions on signal processing 2014-03, Vol.62 (6), p.1424-1437
Hauptverfasser: Simonetto, Andrea, Leus, Geert
Format: Artikel
Sprache:eng
Schlagworte:
ADMM
Algorithms
Applied sciences
Computation
convex relaxations
Detection, estimation, filtering, equalization, prediction
Distributed algorithms
distributed localization
Distributed optimization
Exact sciences and technology
Information, signal and communications theory
Localization
Mathematical models
maximum likelihood
Maximum likelihood estimation
Monte Carlo simulation
Networks
Noise
Optimization
Pattern recognition
Position (location)
Probability density function
Probability density functions
Robot sensing systems
sensor network localization
sensor networks
Sensors
Signal and communications theory
Signal processing
Signal processing algorithms
Signal, noise
Telecommunications and information theory
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Zusammenfassung:We propose a class of convex relaxations to solve the sensor network localization problem, based on a maximum likelihood (ML) formulation. This class, as well as the tightness of the relaxations, depends on the noise probability density function (PDF) of the collected measurements. We derive a computational efficient edge-based version of this ML convex relaxation class and we design a distributed algorithm that enables the sensor nodes to solve these edge-based convex programs locally by communicating only with their close neighbors. This algorithm relies on the alternating direction method of multipliers (ADMM), it converges to the centralized solution, it can run asynchronously, and it is computation error-resilient. Finally, we compare our proposed distributed scheme with other available methods, both analytically and numerically, and we argue the added value of ADMM, especially for large-scale networks.
ISSN:1053-587X
1941-0476
DOI:10.1109/TSP.2014.2302746