Abstract
Wireless sensor networks (WSNs) have several important applications, both in research and domestic use. Generally, their main role is to collect and transmit data from an ROI (region of interest) to a base station for processing and analysis. Therefore, it is vital to ensure maximum coverage of the chosen area and communication between the nodes forming the network. A major problem in network design is the deployment of sensors with the aim to ensure both maximum coverage and connectivity between sensor node. The maximum coverage problem addressed here focuses on calculating the area covered by the deployed sensor nodes. Thus, we seek to cover any type of area (regular or irregular shape) with a predefined number of homogeneous sensors using a genetic algorithm to find the best placement to ensure maximum network coverage under the constraint of connectivity between the sensors. Therefore, this paper tackles the dual problem of maximum coverage and connectivity between sensor nodes. We define the maximum coverage and connectivity problems and then propose a mathematical model and a complex objective function. The results show that the algorithm, called GAFACM (Genetic Algorithm For Area Coverage Maximization), covers all forms of the area for a given number of sensors and finds the best positions to maximize coverage within the area of interest while guaranteeing the connectivity between the sensors.
Highlights
Wireless sensor networks (WSN) have been the subject of numerous research studies since the first known deployment of the SOund SUrveillance System (SOSUS) 1950s [1,2]
All cases are based on actual maps of cities or parts of cities taken from Google Maps
This paper proposed a genetic algorithm (GA)-based scheme to find the best positions for sensor node placement in wireless sensor networks, respecting the coverage and connectivity between the sensor nodes
Summary
Wireless sensor networks (WSN) have been the subject of numerous research studies since the first known deployment of the SOund SUrveillance System (SOSUS) 1950s [1,2]. As new wireless technologies progress, their range of applications increases. Among these innovative technologies, wireless sensor networks (WSN) have become very flexible and dynamic facets deployed in almost all types of environments whether rural, suburban, or urban [1]. A WSN is a collection of sensor nodes that communicate using wireless technologies. The data captured by the nodes are routed through a multi-hop routing to a node, considered to be a “collection point”, called sink-node (or sink). The latter can be connected to the network user (via the Internet, a satellite, or another system). A sensor node can be a detection node, a transmission node, a relay node, or a combination of theses nodes
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