Abstract
The problem of moving target tracking in directional sensor networks (DSNs) introduces new research challenges, including optimal selection of sensing and communication sectors of the directional sensor nodes, determination of the precise location of the target and an energy-efficient data collection mechanism. Existing solutions allow individual sensor nodes to detect the target's location through collaboration among neighboring nodes, where most of the sensors are activated and communicate with the sink. Therefore, they incur much overhead, loss of energy and reduced target tracking accuracy. In this paper, we have proposed a clustering algorithm, where distributed cluster heads coordinate their member nodes in optimizing the active sensing and communication directions of the nodes, precisely determining the target location by aggregating reported sensing data from multiple nodes and transferring the resultant location information to the sink. Thus, the proposed target tracking mechanism minimizes the sensing redundancy and maximizes the number of sleeping nodes in the network. We have also investigated the dynamic approach of activating sleeping nodes on-demand so that the moving target tracking accuracy can be enhanced while maximizing the network lifetime. We have carried out our extensive simulations in ns-3, and the results show that the proposed mechanism achieves higher performance compared to the state-of-the-art works.
Highlights
Wireless sensors are miniature devices integrated with data processing, physical sensing and communication units, which provide great research interest for a wide range of applications [1,2,3,4,5].Sensors can be categorized as omnidirectional and directional sensors
To evaluate the robustness of our proposed moving target tracking through distributed clustering (MTDC) mechanism in different environments, we study the performances for varying numbers of sensor nodes deployed in the network and the number of sensing and communication sectors
The accuracy percentage has been achieved by our MTDC algorithm, and compared to real-time distributed target tracking (RDTT) and adaptive basis algorithm (ABA), it is relatively higher
Summary
Sensors can be categorized as omnidirectional and directional sensors. An omnidirectional sensor can detect the surrounding environment in any direction with its omnidirectional antenna. A directional sensor has a limited range of sensing and communication capabilities, since it can detect only a certain field of vision or a limited direction. A good number of practical directional sensor motes are available in the market, including cameras, infrared and ultrasonic sensors [6,7]. In a directional sensor network (DSN), the communication area of a sensor is a sector rather than a disk. Directional sensors improve the quality of sensing and scale down the interference and fading, which, in turn, enhance the network performance, as well as the lifetime [8]
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