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Main Authors: Sun, Peng, Wang, Ruoyu, Luo, Xue
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.02738
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author Sun, Peng
Wang, Ruoyu
Luo, Xue
author_facet Sun, Peng
Wang, Ruoyu
Luo, Xue
contents This paper focuses on the state estimation problem in distributed sensor networks, where intermittent packet dropouts, corrupted observations, and unknown noise covariances coexist. To tackle this challenge, we formulate the joint estimation of system states, noise parameters, and network reliability as a Bayesian variational inference problem, and propose a novel variational Bayesian adaptive Kalman filter (VB-AKF) to approximate the joint posterior probability densities of the latent parameters. Unlike existing AKF that separately handle missing data and measurement outliers, the proposed VB-AKF adopts a dual-mask generative model with two independent Bernoulli random variables, explicitly characterizing both observable communication losses and latent data authenticity. Additionally, the VB-AKF integrates multiple concurrent multiple observations into the adaptive filtering framework, which significantly enhances statistical identifiability. Comprehensive numerical experiments verify the effectiveness and asymptotic optimality of the proposed method, showing that both parameter identification and state estimation asymptotically converge to the theoretical optimal lower bound with the increase in the number of sensors.
format Preprint
id arxiv_https___arxiv_org_abs_2604_02738
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle State estimations and noise identifications with intermittent corrupted observations via Bayesian variational inference
Sun, Peng
Wang, Ruoyu
Luo, Xue
Machine Learning
Optimization and Control
Computation
This paper focuses on the state estimation problem in distributed sensor networks, where intermittent packet dropouts, corrupted observations, and unknown noise covariances coexist. To tackle this challenge, we formulate the joint estimation of system states, noise parameters, and network reliability as a Bayesian variational inference problem, and propose a novel variational Bayesian adaptive Kalman filter (VB-AKF) to approximate the joint posterior probability densities of the latent parameters. Unlike existing AKF that separately handle missing data and measurement outliers, the proposed VB-AKF adopts a dual-mask generative model with two independent Bernoulli random variables, explicitly characterizing both observable communication losses and latent data authenticity. Additionally, the VB-AKF integrates multiple concurrent multiple observations into the adaptive filtering framework, which significantly enhances statistical identifiability. Comprehensive numerical experiments verify the effectiveness and asymptotic optimality of the proposed method, showing that both parameter identification and state estimation asymptotically converge to the theoretical optimal lower bound with the increase in the number of sensors.
title State estimations and noise identifications with intermittent corrupted observations via Bayesian variational inference
topic Machine Learning
Optimization and Control
Computation
url https://arxiv.org/abs/2604.02738