A novel model-based dynamic distributed state estimator is proposed using sensor networks. The estimator consists of a ltering step { which uses a weighted combination of sensors information { and a model-based predictor of the system's state. The ltering weights and the model-based prediction parameters jointly minimize both the bias and the variance of the prediction error in a Pareto framework at each time-step. The simultaneous distributed design of the ltering weights and of the model-based prediction parameters is considered, dierently from what is normally done in the literature. It is assumed that the weights of the ltering step are in general unequal for the dierent state components, unlike existing consensus- based approaches. The state, the measurements, and the noise components are allowed to be individually correlated, but no probability distribution knowledge is assumed for the noise variables. Each sensor can measure only a subset of the state variables. The convergence properties of the mean and of the variance of the prediction error are demonstrated, and they hold both for the global and the local estimation errors at any network node. Simulation results illustrate the performance of the proposed method, obtaining better results than the state of the art distributed estimation approaches.
Distributed Pareto-Optimal State Estimation Using Sensor Networks
T. Parisini
2018-01-01
Abstract
A novel model-based dynamic distributed state estimator is proposed using sensor networks. The estimator consists of a ltering step { which uses a weighted combination of sensors information { and a model-based predictor of the system's state. The ltering weights and the model-based prediction parameters jointly minimize both the bias and the variance of the prediction error in a Pareto framework at each time-step. The simultaneous distributed design of the ltering weights and of the model-based prediction parameters is considered, dierently from what is normally done in the literature. It is assumed that the weights of the ltering step are in general unequal for the dierent state components, unlike existing consensus- based approaches. The state, the measurements, and the noise components are allowed to be individually correlated, but no probability distribution knowledge is assumed for the noise variables. Each sensor can measure only a subset of the state variables. The convergence properties of the mean and of the variance of the prediction error are demonstrated, and they hold both for the global and the local estimation errors at any network node. Simulation results illustrate the performance of the proposed method, obtaining better results than the state of the art distributed estimation approaches.File | Dimensione | Formato | |
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