2020
DOI: 10.1002/dac.4679
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Optimization for connectivity and coverage issue in target‐based wireless sensor networks using an effective multiobjective hybrid tunicate and salp swarm optimizer

Abstract: Summary The two main important issues in designing target‐based wireless sensor networks (WSNs) are coverage and connectivity maximization. In order to tackle the coverage and connectivity problems, we have proposed a hybrid optimization‐based model. Thereby, the target‐based WSNs can include the sensor nodes which are placed based on determining minimum number of selected potential positions. To do that, an optimization approach based on a hybrid tunicate swarm optimizer (TSO) and salp swarm optimizer (SSO) i… Show more

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Cited by 12 publications
(12 citation statements)
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“…Wireless Communications and Mobile Computing further shaping in calendering forming [8,9]. The quantity of stock and the state of stock rotation should affect product quality.…”
Section: Editing Distance and Stockmentioning
confidence: 99%
“…Wireless Communications and Mobile Computing further shaping in calendering forming [8,9]. The quantity of stock and the state of stock rotation should affect product quality.…”
Section: Editing Distance and Stockmentioning
confidence: 99%
“…The optimal results of the EAOA were compared with the other selected schemes—i.e., the SSA [ 44 ], PSO [ 45 ], GWO [ 46 ], SCA [ 47 ], and AOA [ 48 ]—for the coverage optimization of WSN node deployment to verify the adequate performance of the algorithm. Figure 1 displays a graphical diagram of the nodes’ initialization with the EAOA for the statistical coverage optimization scheme with different numbers of sensor nodes: (a) 20, (b) 40, (c) 50, and (d) 60.…”
Section: Optimal Wsn Node Coverage Based On Eaoamentioning
confidence: 99%
“…The work in [12] focused on the optimization of the deployment of SNs using a Biogeography Based Optimization where the objectives are the minimization of the sensing interference and the number of deployed SNs, and the maximization of the target coverage, under the the connectivity constraint. Authors in [7], proposed a hybrid meta-heuristic based on the tunicate swarm optimizer and the salp swarm optimizer, with the main aim of determining a minimum number of potential positions selected to place SNs and maximize the target coverage and network connectivity. In [9], the work addressed the deployment of SNs for target coverage using improved gravitational search algorithm (GSA) called oppositional GSA.…”
Section: Related Workmentioning
confidence: 99%
“…where CSP OP T is the set of the CSPs chosen and sink is the index of the sink node. To solve this problem, we transform it into a mono-objective problem F using the weighted sum approach [7]:…”
Section: Notationsmentioning
confidence: 99%