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Wireless Networks
Erschienen in: Wireless Networks 3/2011

01.04.2011

Coordinated and controlled mobility of multiple sinks for maximizing the lifetime of wireless sensor networks

verfasst von: Stefano Basagni, Alessio Carosi, Chiara Petrioli, Cynthia A. Phillips

Erschienen in: Wireless Networks | Ausgabe 3/2011

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Abstract

We define scalable models and distributed heuristics for the concurrent and coordinated movement of multiple sinks in a wireless sensor network, a case that presents significant challenges compared to the widely investigated case of a single mobile sink. Our objective is that of maximizing the network lifetime defined as the time from the start of network operations till the failure of the first node. We contribute to this problem providing three new results. We first define a linear program (LP) whose solution provides a provable upper bound on the maximum lifetime possible for any given number of sinks. We then develop a centralized heuristic that runs in polynomial time given the solution to the LP. We also define a deployable distributed heuristic for coordinating the motion of multiple sinks through the network. We demonstrate the performance of the proposed heuristics via ns2-based simulations. The observed results show that our distributed heuristic achieves network lifetimes that are remarkably close to the optimum ones, resulting also in significant improvements over the cases of deploying the sinks statically, of random sink mobility and of heuristics previously proposed for restricted sink movements.
Vorheriger Artikel Efficient cross-layer protocol for bandwidth-satisfied multicast in multi-rate MANETs
Nächster Artikel Flow admission control for multi-channel multi-radio wireless networks

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Fußnoten
1
Definitions of network lifetime vary, and depend on applications. In this paper we adopt the widely used definition introduced in [2] and used in many works (see [3, 4] and references therein) where lifetime is defined as the time until the failure (here for energy depletion) of the first node. This definition may seem too pessimistic, and many advocate definitions based on the failure of a certain percentage of the nodes. However, robust, energy-efficient protocols for WSNs tend to balance energy consumption among the nodes. So when the first node dies, many other nodes are also about to die.
 
2
One might expect that an optimal schedule will use all stationary sinks at all times. However, there may be times when it is best not to use one even if it is available. This is because the extra sink will affect packet routes, possibly affecting energy balance negatively.
 
3
If the protocol involves a training phase, i.e., a phase through which the sensors and the sinks learn about parameters needed to start protocol operations, e p is the energy after the training.
 
4
Holding major configurations for a longer time allows routes to stabilize and run for enough time to justify the cost of changing the configuration.
 
5
Note that these weights are a metric. Weighting only by the number of transient states does not satisfy the triangle inequality.
 
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Metadaten
Titel
Coordinated and controlled mobility of multiple sinks for maximizing the lifetime of wireless sensor networks
verfasst von
Stefano Basagni
Alessio Carosi
Chiara Petrioli
Cynthia A. Phillips
Publikationsdatum
01.04.2011
Verlag
Springer US
Erschienen in
Wireless Networks / Ausgabe 3/2011
Print ISSN: 1022-0038
Elektronische ISSN: 1572-8196
DOI
https://doi.org/10.1007/s11276-010-0313-8

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