Chiara Petrioli scite author profile

This paper demonstrates the advantages of using controlled mobility in wireless sensor networks (WSNs) for increasing their lifetime, i.e., the period of time the network is able to provide its intended functionalities. More specifically, for WSNs that comprise a large number of statically placed sensor nodes transmitting data to a collection point (the sink), we show that by controlling the sink movements we can obtain remarkable lifetime improvements. In order to determine sink movements, we first define a Mixed Integer Linear Programming (MILP) analytical model whose solution determines those sink routes that maximize network lifetime. Our contribution expands further by defining the first heuristics for controlled sink movements that are fully distributed and localized. Our Greedy Maximum Residual Energy (GMRE) heuristic moves the sink from its current location to a new site as if drawn toward the area where nodes have the highest residual energy. We also introduce a simple distributed mobility scheme (Random Movement or RM) according to which the sink moves uncontrolled and randomly throughout the network. The different mobility schemes are compared through extensive ns2-based simulations in networks with different nodes deployment, data routing protocols, and constraints on the sink movements. In all considered scenarios, we observe that moving the sink always increases network lifetime. In particular, our experiments show that controlling the mobility of the sink leads to remarkable improvements, which are as high as sixfold compared to having the sink statically (and optimally) placed, and as high as twofold compared to uncontrolled mobility

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CARP: A Channel-aware routing protocol for underwater acoustic wireless networks

Basagni

et al. 2015

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Configuring bluestars: multihop scatternet formation for bluetooth networks

Petrioli

Basagni

Chlamtac

2003

IEEE Trans. Comput.

124

120

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This paper describes a new protocol for the establishment of multihop ad hoc networks based on Bluetooth devices. The protocol proceeds in three phases: device discovery, partitioning of the network into Bluetooth piconets, and interconnection of the piconets into a connected scatternet. The protocol has the following desirable properties: It is executed at each node with no prior knowledge of the network topology, thus being fully distributed. The selection of the Bluetooth masters is driven by the suitability of a node to be the "best fit" for serving as a master. The generated scatternet is a connected mesh with multiple paths between any pair of nodes, thus achieving robustness. Differently from existing solutions, no extra hardware is required to run the protocol at each node and there is no need for a designated node to start the scatternet formation process. Simulation results are provided which evaluate the impact of the Bluetooth device discovery phase on the performance of the protocol.

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Pro-Energy: A novel energy prediction model for solar and wind energy-harvesting wireless sensor networks

2012

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Anticollision Protocols for Single-Reader RFID Systems: Temporal Analysis and Optimization

Porta

Maselli

Petrioli

2011

IEEE Trans. on Mobile Comput.

130

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One of the major challenges in the use of Radio Frequency-based Identification (RFID) on a large scale is the ability to read a large number of tags quickly. Central to solving this problem is resolving collisions that occur when multiple tags reply to the query of a reader. To this purpose, several MAC protocols for passive RFID systems have been proposed. These typically build on traditional MAC schemes, such as aloha and tree-based protocols. In this paper, we propose a new performance metric by which to judge these anticollision protocols: time system efficiency. This metric provides a direct measure of the time taken to read a group of tags. We then evaluate a set of well-known RFID MAC protocols in light of this metric. Based on the insights gained, we propose a new anticollision protocol, and show that it significantly outperforms previously proposed mechanisms

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Localized protocols for ad hoc clustering and backbone formation: a performance comparison

Basagni

Mastrogiovanni

Panconesi

et al. 2006

IEEE Trans. Parallel Distrib. Syst.

130

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This paper concerns the comparative performance evaluation of protocols for clustering and backbone formation in ad hoc networks characterized by a large number of resource-constrained nodes. Our aim is twofold: We provide the first simulation-based detailed investigation of techniques for clustering and backbone formation that are among the most representative of this area of ad hoc research. Second, we delve into the nature of the selected protocols to assess the effects of the "degree of localization" on their operations, i.e., how being able to execute the protocol based only on local information affects the overall protocol performance. Extensive ns2-based simulation results show that highly localized protocols are rewarded with good performance with respect to all metrics of interest which include protocol duration, energy consumption, message overhead, route length, and backbone size.

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Degree-constrained multihop scatternet formation for Bluetooth networks

Petrioli¹,

Basagni

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Chiara Petrioli

Exploiting Sink Mobility for Maximizing Sensor Networks Lifetime

Controlled sink mobility for prolonging wireless sensor networks lifetime

CARP: A Channel-aware routing protocol for underwater acoustic wireless networks

Configuring bluestars: multihop scatternet formation for bluetooth networks

Pro-Energy: A novel energy prediction model for solar and wind energy-harvesting wireless sensor networks

Anticollision Protocols for Single-Reader RFID Systems: Temporal Analysis and Optimization

Localized protocols for ad hoc clustering and backbone formation: a performance comparison

Degree-constrained multihop scatternet formation for Bluetooth networks

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