A GRASP Meta-Heuristic for Evaluating the Latency and Lifetime Impact of Critical Nodes in Large Wireless Sensor Networks

Sembroiz, David; Ojaghi, Behnam; Careglio, Davide; Ricciardi, Sergio

doi:10.3390/app9214564

Cited by 4 publications

(6 citation statements)

References 14 publications

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“…Centrality 49,50,51 Centralized 37,40,44 Distributed 20,41,42,43 Data transmission 39 Energy 38,51 k-connected graph 14,45,46,47 F I G U R E 2 Classification of critical nodes variants on WSN…”

Section: Cut Vertexmentioning

confidence: 99%

“…37,40 The cut vertex detection algorithms available in the literature can be divided into two categories: distributed algorithms 20,[41][42][43] and centralized algorithms. 37,40,44 In Reference 14, the authors consider a k-connected graph where a graph (G) has k connectivity if the minimum vertex cut of G has at least k vertices, that is, it remains whenever fewer than k vertices are removed. Decreasing the k value of the network can have a significant impact on the performance of the network.…”

Section: Cut Vertexmentioning

confidence: 99%

“…Although the MIP and LP models provide accurate results, they have some drawbacks due to their high execution time and complexity especially when the number of nodes increases. To overcome these limitations, Sembroiz et al 37 proposed two greedy randomized adaptive search metaheuristics to identify critical nodes when the targeted performance criteria are latency and lifetime. Liu et al 38 proposed an approach to determinate important nodes by considering energy consumption and node lifetime.…”

Section: Related Workmentioning

confidence: 99%

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Fault‐tolerance based on augmenting approach in wireless sensor networks

Belkadi

Lehsaini

Tahraoui

2022

Concurrency and Computation

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A critical node is a sensor whose failure causes loss of connectivity and network fragmentation. In wireless sensor networks, the failure of a critical node, like the failure of all sensor nodes, can be caused by energy depletion or physical failure. To overcome the problem of failure of such nodes, this article proposes a fault-tolerant strategy that allows a routing protocol to tolerate the failure of a critical node. The proposed strategy is carried out in two phases. In the first phase, a hybrid genetic algorithm with a local search heuristic called genetic algorithm-critical node problem (GA-CNP) is used to select the critical nodes and in the second phase, an algorithm called Aug-CNP is involved to deal with the augmentation problem by deploying additional wireless edges to preserve network connectivity in case of critical node failure. Our proposal has been developed using the OMNET++ simulator, evaluated, and compared to the AODV protocol. The simulation results showed that the GA-CNP algorithm selects the critical nodes whose failure can degrade the network lifetime with a rate of 40%. Moreover, the Aug-CNP algorithm applied to the AODV protocol brings improvements in terms of network lifetime which reaches 22% compared to the traditional AODV protocol.

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Section: Cut Vertexmentioning

confidence: 99%

Section: Cut Vertexmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

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Fault‐tolerance based on augmenting approach in wireless sensor networks

Belkadi

Lehsaini

Tahraoui

2022

Concurrency and Computation

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“…When compared to static WSNs, MWSNs find a wider variety of applications, since the mobility of entities results in many advantages, such as reliability, cost, improved coverage, connectivity, energy efficiency, dynamic topology, increased channel capacity, etc. [ 26 , 27 , 28 ]. Moreover, MWSNs can easily monitor also moving targets (e.g., animals, people, chemical clouds, etc.)…”

Section: Introductionmentioning

confidence: 99%

Average Consensus over Mobile Wireless Sensor Networks: Weight Matrix Guaranteeing Convergence without Reconfiguration of Edge Weights

Kenyeres

Kenyeres²

2020

Sensors

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Efficient data aggregation is crucial for mobile wireless sensor networks, as their resources are significantly constrained. Over recent years, the average consensus algorithm has found a wide application in this technology. In this paper, we present a weight matrix simplifying the average consensus algorithm over mobile wireless sensor networks, thereby prolonging the network lifetime as well as ensuring the proper operation of the algorithm. Our contribution results from the theorem stating how the Laplacian spectrum of an undirected simple finite graph changes in the case of adding an arbitrary edge into this graph. We identify that the mixing parameter of Best Constant weights of a complete finite graph with an arbitrary order ensures the convergence in time-varying topologies without any reconfiguration of the edge weights. The presented theorems and lemmas are verified over evolving graphs with various parameters, whereby it is demonstrated that our approach ensures the convergence of the average consensus algorithm over mobile wireless sensor networks in spite of no edge reconfiguration.

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“…Therefore, appropriate routing decisions should be determined for optimizing network connectivity and stability. The main aim of the optimal decision is to choose the best and most maintainable path among the others with efficient utilization of node resources and reliable data delivery to application users [4][5][6][7][8]. Also, due to the lower cost and robust features of sensor networks, most researchers have integrated it with IoT for better network performance in terms of cost-effectiveness, better network coverage, and scalability [9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

A Lightweight Secure and Energy-Efficient Fog-Based Routing Protocol for Constraint Sensors Network

et al. 2020

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The Wireless Sensor Network (WSN) has seen rapid growth in the development of real-time applications due to its ease of management and cost-effective attributes. However, the balance between optimization of network lifetime and load distribution between sensor nodes is a critical matter for the development of energy-efficient routing solutions. Recently, many solutions have been proposed for constraint-based networks using the cloud paradigm. However, they achieve network scalability with the additional cost of routing overheads and network latency. Moreover, the sensors’ data is transmitted towards application users over the uncertain medium, which leads to compromised data security and its integrity. Therefore, this work proposes a light-weight secure and energy-efficient fog-based routing (SEFR) protocol to minimize data latency and increase energy management. It exploits the Quality of Service (QoS) factors and facilitates time-sensitive applications with network edges. Moreover, the proposed protocol protects real-time data based on two levels of cryptographic security primitives. In the first level, a lightweight data confidentiality scheme is proposed between the cluster heads and fog nodes, and in the second level, a high-performance asymmetric encryption scheme is proposed among fog and cloud layers. The analysis of simulation-based experiments has proven the significant outcomes of the proposed protocol compared to existing solutions in terms of routing, security, and network management.

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A GRASP Meta-Heuristic for Evaluating the Latency and Lifetime Impact of Critical Nodes in Large Wireless Sensor Networks

Cited by 4 publications

References 14 publications

Fault‐tolerance based on augmenting approach in wireless sensor networks

Fault‐tolerance based on augmenting approach in wireless sensor networks

Average Consensus over Mobile Wireless Sensor Networks: Weight Matrix Guaranteeing Convergence without Reconfiguration of Edge Weights

A Lightweight Secure and Energy-Efficient Fog-Based Routing Protocol for Constraint Sensors Network

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