Consensus-based joint target tracking and sensor localization
For distributed sensor networks, it solves the practical problem of joint target tracking and sensor self-localization with minimal overhead, but the approach is incremental.
The paper extends consensus-based Kalman filtering to jointly track a target and localize sensors in a distributed wireless sensor network, using an online technique to minimize an approximated Kullback-Leibler divergence cost without additional data exchanges. Simulations on tree and cyclic networks with linear and nonlinear sensors demonstrate effectiveness.
In this paper, consensus-based Kalman filtering is extended to deal with the problem of joint target tracking and sensor self-localization in a distributed wireless sensor network. The average weighted Kullback-Leibler divergence, which is a function of the unknown drift parameters, is employed as the cost to measure the discrepancy between the fused posterior distribution and the local distribution at each sensor. Further, a reasonable approximation of the cost is proposed and an online technique is introduced to minimize the approximated cost function with respect to the drift parameters stored in each node. The remarkable features of the proposed algorithm are that it needs no additional data exchanges, slightly increased memory space and computational load comparable to the standard consensus-based Kalman filter. Finally, the effectiveness of the proposed algorithm is demonstrated through simulation experiments on both a tree network and a network with cycles as well as for both linear and nonlinear sensors.