Dynamic Bit Allocation for Object Tracking in Wireless Sensor Networks

Maşazade, Engin; Niu, Ruixin; Varshney, Pramod K.

doi:10.1109/tsp.2012.2204257

Cited by 74 publications

(73 citation statements)

References 24 publications

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“…Moreover, if we drop the source statistics Σ from the MSE matrix (5) and impose the assumption s ≥ n, the proposed formulation (P0) is then applicable for sensor selection in a non-Bayesian framework, where the unknown parameter is estimated through the best linear unbiased estimator [24].…”

Section: Formulation Of the Optimal Sensor Selection Problemmentioning

confidence: 99%

“…We also remark that although the dynamical system (36)-(37) is assumed to be linear, it will be evident later that the proposed sensor scheduling framework is also applicable to non-linear dynamical systems. The PDF of the initial state x 0 at time step t 0 is assumed to be Gaussian with meanx 0 and covariance matrixP 0 , wherex 0 andP 0 are estimates of the initial state and error covariance from the previous measurements obtained using filtering algorithms, such as a particle filter or a Kalman filter [37], [38]. At time step t 0 , we aim to find the optimal sensor schedule over the next τ time steps t 0 + 1, t 0 + 2, .…”

Section: Non-myopic Sensor Schedulingmentioning

confidence: 99%

“…Therefore, the problem of sensor selection/scheduling arises, which aims to strike a balance between estimation accuracy and sensor activations over space and/or time. The importance of sensor selection has been discussed extensively in the context of various applications, such as target tracking [4], bit allocation [5], field monitoring [6], [7], optimal control [8], power allocation [9], [10], optimal experiment design [11], and leader selection in consensus networks [12].…”

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confidence: 99%

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Sensor Selection for Estimation with Correlated Measurement Noise

Liu

Chepuri

Fardad

et al. 2016

IEEE Trans. Signal Process.

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159

107

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Abstract-In this paper, we consider the problem of sensor selection for parameter estimation with correlated measurement noise. We seek optimal sensor activations by formulating an optimization problem, in which the estimation error, given by the trace of the inverse of the Bayesian Fisher information matrix, is minimized subject to energy constraints. Fisher information has been widely used as an effective sensor selection criterion. However, existing information-based sensor selection methods are limited to the case of uncorrelated noise or weakly correlated noise due to the use of approximate metrics. By contrast, here we derive the closed form of the Fisher information matrix with respect to sensor selection variables that is valid for any arbitrary noise correlation regime, and develop both a convex relaxation approach and a greedy algorithm to find near-optimal solutions. We further extend our framework of sensor selection to solve the problem of sensor scheduling, where a greedy algorithm is proposed to determine non-myopic (multi-time step ahead) sensor schedules. Lastly, numerical results are provided to illustrate the effectiveness of our approach, and to reveal the effect of noise correlation on estimation performance.

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Section: Formulation Of the Optimal Sensor Selection Problemmentioning

confidence: 99%

Section: Non-myopic Sensor Schedulingmentioning

confidence: 99%

mentioning

confidence: 99%

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Sensor Selection for Estimation with Correlated Measurement Noise

Liu

Chepuri

Fardad

et al. 2016

IEEE Trans. Signal Process.

Self Cite

159

107

View full text Add to dashboard Cite

show abstract

“…When there is a constraint on the total number of bits that can be transmitted, bit allocation becomes necessary. In [142], a dynamic bit allocation algorithm based on approximate dynamic programming has been presented. It is shown that the proposed algorithm can save much of the computational cost while achieving comparable accuracy with other existing methods.…”

Section: Centralized Particle Filteringmentioning

confidence: 99%

Particle filtering with applications in networked systems: a survey

Wang

Yuan

2016

Complex Intell. Syst.

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The particle filtering algorithm was introduced in the 1990s as a numerical solution to the Bayesian estimation problem for nonlinear and non-Gaussian systems and has been successfully applied in various fields including physics, economics, engineering, etc. As is widely recognized, the particle filter has broad application prospects in networked systems, but network-induced phenomena and limited computing resources have led to new challenges to the design and implementation of particle filtering algorithms. In this survey paper, we aim to review the particle filtering method and its applications in networked systems. We first provide an overview of the particle filtering methods as well as networked systems, and then investigate the recent progress inThe work of W. Li, Y. Yuan and L.

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“…In (10), the FIM is decomposed into two parts, where, J D t represents the FIM corresponding to the sensor measurements, and J P t represents the FIM corresponding to the a priori information. The FIM corresponding to the sensor measurements, J D t , can be further written as the summation of each sensor's individual FIM [18], [21] as,…”

Section: B Fisher Information With Quantized Measurementsmentioning

confidence: 99%

Target Tracking via Crowdsourcing: A Mechanism Design Approach

Cao

Brahma

Varshney

2015

IEEE Trans. Signal Process.

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Abstract-In this paper, we propose a crowdsourcing based framework for myopic target tracking by designing an incentivecompatible mechanism based optimal auction in a wireless sensor network (WSN) containing sensors that are selfish and profitmotivated. For typical WSNs which have limited bandwidth, the fusion center (FC) has to distribute the total number of bits that can be transmitted from the sensors to the FC among the sensors. To accomplish the task, the FC conducts an auction by soliciting bids from the selfish sensors, which reflect how much they value their energy cost. Furthermore, the rationality and truthfulness of the sensors are guaranteed in our model. The final problem is formulated as a multiple-choice knapsack problem (MCKP), which is solved by the dynamic programming method in pseudopolynomial time. Simulation results show the effectiveness of our proposed approach in terms of both the tracking performance and lifetime of the sensor network.

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Dynamic Bit Allocation for Object Tracking in Wireless Sensor Networks

Cited by 74 publications

References 24 publications

Sensor Selection for Estimation with Correlated Measurement Noise

Sensor Selection for Estimation with Correlated Measurement Noise

Particle filtering with applications in networked systems: a survey

Target Tracking via Crowdsourcing: A Mechanism Design Approach

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