Abstract
This paper investigates the problem of a scalable distributed state estimation for a class of discrete time-variant systems with state-saturation, quantization effects, and two redundant channels over a sensor network. In transmission data from a sensor to its estimator, two phenomena are considered together. First, the data of each sensor is transmitted to its estimator through two redundant communication channels. Second, innovation data is quantized before being used by the estimator. These phenomena are beneficial in alleviating the negative effects on measurements and reducing the energy consumption and bandwidth. In the structure of proposed filter consensus is used on estimations in which consensus is first achieved on the prediction estimation, then the accuracy of computed estimation is improved by two recursive equations. The parameters of the proposed filter are obtained for each sensor node by employing an upper bound for common error covariance, therefore less computational burden is required. Eventually, the comparative simulation results are presented to show that our method has better performance compared with a rival one recently published.
Highlights
Distributed state estimation problem is a fundamental issue over wireless sensor networks in control engineering and signal processing
MAIN RESULTS first a novel scalable distributed state estimation is presented for a linear system with state-saturated, we obtain upper bounds for common, prediction and filter error covariances and the parameters of proposed filter are calculated such that the upper bounds of the estimation error covariances are minimized
In this paper, a novel scalable distributed state estimation has been presented for a class of state-saturated systems with quantization effects and two redundant channels
Summary
Distributed state estimation problem is a fundamental issue over wireless sensor networks in control engineering and signal processing. In [17], the problem of an event-triggered distributed state estimation over sensor networks is derived for a class of discrete time-varying nonlinear systems, where noises and sensor saturations are supposed to be unknown and bounded. A distributed recursive filtering is derived for the timevarying state-saturated systems under round-robin communication protocol over sensor networks in [19]. Another phenomenon that inevitably occurs in networked systems due to limited bandwidth is quantization. Motivated by the aforementioned discussions, this paper is purposed to derive a novel distributed state estimation for a class of state-saturated systems subject to both quantization effects and two redundant channels over a sensor network.
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