DocumentCode
1083936
Title
Stochastic Event Capture Using Mobile Sensors Subject to a Quality Metric
Author
Bisnik, Nabhendra ; Abouzeid, Alhussein A. ; Isler, Volkan
Author_Institution
Rensselaer Polytech. Inst., Troy
Volume
23
Issue
4
fYear
2007
Firstpage
676
Lastpage
692
Abstract
Mobile sensors cover more area over a fixed period of time than do the same number of stationary sensors. However, the quality of coverage (QoC) achieved by mobile sensors depends on the velocity, mobility pattern, number of mobile sensors deployed, and the dynamics of the phenomenon being sensed. The gains attained by mobile sensors over static sensors and the optimal motion strategies for mobile sensors are not well understood. In this paper, we consider the following event capture problem: the events of interest arrive at certain points in the sensor field and disappear according to known arrival and departure time distributions. An event is said to be captured if it is sensed by one of the mobile sensors before it fades away. We analyze how the QoC scales with velocity, path, and number of mobile sensors. We characterize cases where the deployment of mobile sensors has no advantage over static sensors, and find the optimal velocity pattern that a mobile sensor should adopt. We also present algorithms for two motion planning problems: 1) for a single sensor, what is the sensor trajectory and the minimum speed required to satisfy a bound on the event loss probability and 2) for sensors with fixed speed, what is the minimum number of sensors required to satisfy a bound on the event loss probability. When the robots are restricted to move along a line or a closed curve, our algorithms return the optimal velocity for the minimum velocity problem. For the minimum sensor problem, the number of sensors used is within a factor of 2 of the optimal solution. For the case where the events occur at arbitrary points on a plane, we present heuristic algorithms for the aforementioned motion planning problems and bound their performance with respect to the optimal.
Keywords
mobile robots; path planning; probability; stochastic processes; wireless sensor networks; arrival time distribution; departure time distribution; event loss probability; heuristic algorithm; mobile robot; mobile sensors; mobility pattern; motion planning; optimal motion strategy; optimal velocity pattern; quality metric; quality of coverage; sensor trajectory; stochastic event capture; wireless sensor network; Mobile robots; Monitoring; Motion planning; Robot sensing systems; Sensor phenomena and characterization; Sensor systems; Stochastic processes; Surveillance; Trajectory; Wireless sensor networks; Algorithms; mobile robot motion planning; mobile sensor networks; robot sensing systems;
fLanguage
English
Journal_Title
Robotics, IEEE Transactions on
Publisher
ieee
ISSN
1552-3098
Type
jour
DOI
10.1109/TRO.2007.900628
Filename
4285841
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