A cooperative approach to sensor localisation in distributed fusion networks
A cooperative approach to sensor localisation in distributed fusion networks
We consider self-localisation of networked sensor platforms, which are located disparately and collect cluttered and noisy measurements from an unknown number of objects (or, targets). These nodes perform local filtering of their measurements and exchange posterior densities of object states over the network to improve upon their myopic performance. Sensor locations need to be known, however, in order to register the incoming information in a common coordinate frame for fusion. In this work, we are interested in scenarios in which these locations need to be estimated solely based on the multi-object scene. We propose a cooperative scheme which features nodes using only the information they already receive for distributed fusion: we first introduce node-wise separable parameter likelihoods for sensor pairs, which are recursively updated using the incoming multi-object information and the local measurements. Second, we establish a network coordinate system through a pairwise Markov random field model which has the introduced likelihoods as its edge potentials. The resulting algorithm consists of consecutive edge potential updates and Belief Propagation message passing operations. These potentials are capable of incorporating multi-object information without the need to find explicit object-measurement associations and updated in linear complexity with the number of measurements. We demonstrate the efficacy of our algorithm through simulations with multiple objects and complex measurement models
1187- 1199
Üney, Murat
f704f6e8-3ff8-4ec3-a670-708cf2079051
Mulgrew, Bernard
95a3fbda-7de2-4583-b1f2-0a54a69b414a
Clark, D.E.
537f80e8-cbe6-41eb-b1d4-31af1f0e6393
1 March 2016
Üney, Murat
f704f6e8-3ff8-4ec3-a670-708cf2079051
Mulgrew, Bernard
95a3fbda-7de2-4583-b1f2-0a54a69b414a
Clark, D.E.
537f80e8-cbe6-41eb-b1d4-31af1f0e6393
Üney, Murat, Mulgrew, Bernard and Clark, D.E.
(2016)
A cooperative approach to sensor localisation in distributed fusion networks.
IEEE Transactions on Signal Processing, 64 (5), .
(doi:10.1109/TSP.2015.2493981).
Abstract
We consider self-localisation of networked sensor platforms, which are located disparately and collect cluttered and noisy measurements from an unknown number of objects (or, targets). These nodes perform local filtering of their measurements and exchange posterior densities of object states over the network to improve upon their myopic performance. Sensor locations need to be known, however, in order to register the incoming information in a common coordinate frame for fusion. In this work, we are interested in scenarios in which these locations need to be estimated solely based on the multi-object scene. We propose a cooperative scheme which features nodes using only the information they already receive for distributed fusion: we first introduce node-wise separable parameter likelihoods for sensor pairs, which are recursively updated using the incoming multi-object information and the local measurements. Second, we establish a network coordinate system through a pairwise Markov random field model which has the introduced likelihoods as its edge potentials. The resulting algorithm consists of consecutive edge potential updates and Belief Propagation message passing operations. These potentials are capable of incorporating multi-object information without the need to find explicit object-measurement associations and updated in linear complexity with the number of measurements. We demonstrate the efficacy of our algorithm through simulations with multiple objects and complex measurement models
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Published date: 1 March 2016
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Local EPrints ID: 474469
URI: http://eprints.soton.ac.uk/id/eprint/474469
ISSN: 1053-587X
PURE UUID: 9d8e4255-da16-44c2-a494-90532a5c7b07
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Date deposited: 22 Feb 2023 21:08
Last modified: 16 Mar 2024 23:15
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Author:
Murat Üney
Author:
Bernard Mulgrew
Author:
D.E. Clark
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