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Bibliographic Details
Main Authors: Houssineau, Jeremie, Cai, Han, Uney, Murat, Delande, Emmanuel
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2209.12245
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author Houssineau, Jeremie
Cai, Han
Uney, Murat
Delande, Emmanuel
author_facet Houssineau, Jeremie
Cai, Han
Uney, Murat
Delande, Emmanuel
contents Fusing and sharing information from multiple sensors over a network is a challenging task, partly due to the absence of a foundational rule for fusing probability distributions that preserves the independence of sources. To address this, we propose a decentralised inference framework based on possibility theory. Unlike probabilistic approaches that rely on ad-hoc averaging, we derive a principled fusion rule that is proven to be asymptotically exact, meaning it recovers the posterior of the optimal centralised possibilistic approach. We apply this rule to the possibilistic Bernoulli filter, leveraging its hierarchical nature to jointly infer data association and state estimation, distinct from standard decentralised Kalman filtering. We demonstrate that the proposed approach maintains the independence of local posteriors during fusion and, even under necessary approximations to handle Gaussian mixtures, significantly outperforms probabilistic geometric and arithmetic average fusion baselines in terms of cardinality and localisation error.
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institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Decentralised possibilistic inference with applications to target tracking
Houssineau, Jeremie
Cai, Han
Uney, Murat
Delande, Emmanuel
Signal Processing
Fusing and sharing information from multiple sensors over a network is a challenging task, partly due to the absence of a foundational rule for fusing probability distributions that preserves the independence of sources. To address this, we propose a decentralised inference framework based on possibility theory. Unlike probabilistic approaches that rely on ad-hoc averaging, we derive a principled fusion rule that is proven to be asymptotically exact, meaning it recovers the posterior of the optimal centralised possibilistic approach. We apply this rule to the possibilistic Bernoulli filter, leveraging its hierarchical nature to jointly infer data association and state estimation, distinct from standard decentralised Kalman filtering. We demonstrate that the proposed approach maintains the independence of local posteriors during fusion and, even under necessary approximations to handle Gaussian mixtures, significantly outperforms probabilistic geometric and arithmetic average fusion baselines in terms of cardinality and localisation error.
title Decentralised possibilistic inference with applications to target tracking
topic Signal Processing
url https://arxiv.org/abs/2209.12245