Saved in:
Bibliographic Details
Main Authors: Yan, Shi, Liang, Yan, Zhang, Huayu, Zheng, Le, Zou, Difan, Wang, Binglu
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.11163
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916289684963328
author Yan, Shi
Liang, Yan
Zhang, Huayu
Zheng, Le
Zou, Difan
Wang, Binglu
author_facet Yan, Shi
Liang, Yan
Zhang, Huayu
Zheng, Le
Zou, Difan
Wang, Binglu
contents Through integrating the evolutionary correlations across global states in the bidirectional recursion, an explainable Bayesian recurrent neural smoother (EBRNS) is proposed for offline data-assisted fixed-interval state smoothing. At first, the proposed model, containing global states in the evolutionary interval, is transformed into an equivalent model with bidirectional memory. This transformation incorporates crucial global state information with support for bi-directional recursive computation. For the transformed model, the joint state-memory-trend Bayesian filtering and smoothing frameworks are derived by introducing the bidirectional memory iteration mechanism and offline data into Bayesian estimation theory. The derived frameworks are implemented using the Gaussian approximation to ensure analytical properties and computational efficiency. Finally, the neural network modules within EBRNS and its two-stage training scheme are designed. Unlike most existing approaches that artificially combine deep learning and model-based estimation, the bidirectional recursion and internal gated structures of EBRNS are naturally derived from Bayesian estimation theory, explainably integrating prior model knowledge, online measurement, and offline data. Experiments on representative real-world datasets demonstrate that the high smoothing accuracy of EBRNS is accompanied by data efficiency and a lightweight parameter scale.
format Preprint
id arxiv_https___arxiv_org_abs_2406_11163
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Explainable Bayesian Recurrent Neural Smoother to Capture Global State Evolutionary Correlations
Yan, Shi
Liang, Yan
Zhang, Huayu
Zheng, Le
Zou, Difan
Wang, Binglu
Signal Processing
Through integrating the evolutionary correlations across global states in the bidirectional recursion, an explainable Bayesian recurrent neural smoother (EBRNS) is proposed for offline data-assisted fixed-interval state smoothing. At first, the proposed model, containing global states in the evolutionary interval, is transformed into an equivalent model with bidirectional memory. This transformation incorporates crucial global state information with support for bi-directional recursive computation. For the transformed model, the joint state-memory-trend Bayesian filtering and smoothing frameworks are derived by introducing the bidirectional memory iteration mechanism and offline data into Bayesian estimation theory. The derived frameworks are implemented using the Gaussian approximation to ensure analytical properties and computational efficiency. Finally, the neural network modules within EBRNS and its two-stage training scheme are designed. Unlike most existing approaches that artificially combine deep learning and model-based estimation, the bidirectional recursion and internal gated structures of EBRNS are naturally derived from Bayesian estimation theory, explainably integrating prior model knowledge, online measurement, and offline data. Experiments on representative real-world datasets demonstrate that the high smoothing accuracy of EBRNS is accompanied by data efficiency and a lightweight parameter scale.
title Explainable Bayesian Recurrent Neural Smoother to Capture Global State Evolutionary Correlations
topic Signal Processing
url https://arxiv.org/abs/2406.11163