Adaptive cluster‐based heuristic approach in cognitive radio networks for<scp>5G</scp>applications

Devaraj, S. Allwin; Aruna, T.; Muthukumaran, N.; Roobert, A. Andrew

doi:10.1002/ett.4383

Cited by 26 publications

(8 citation statements)

References 27 publications

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“…HarborSync coordinates the creation and upkeep of stable clusters while simultaneously negotiating and tracking congestion in realtime. The system inducts adaptive actions, such as dynamic reconfiguration [19] and efficient routing, in reaction to congestion detection to relieve network strain [20]. Finally, among the most innovative WSN algorithms, HarborSync stands out in peculiarity because it can overturn WSNs in terms of congestion control, endurance, and stability.…”

Section: Proposed Methodologymentioning

confidence: 99%

HarborSync: An Advanced Energy-efficient Clustering-based Algorithm for Wireless Sensor Networks to Optimize Aggregation and Congestion Control

Aqeel

2024

IJACSA

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In the ever-evolving landscape of Wireless Sensor Networks (WSNs), the demand for cutting-edge algorithms has never been more critical. This paper proposes an algorithm, HarborSync, to improve stability, energy efficiency, durability, and congestion control in WSN. While selecting cluster heads and backup nodes, HarborSync applies the Optimised Stable Clustering Algorithm (OSCA) and the Weighted Clustering Algorithm (WCA). This fresh method puts the groundwork for better performance by acquainting techniques to intentionally postpone changes in cluster heads and computing priorities. Using the innovative Cluster-based Aggregation and Congestion Control (CACC) features, HarborSync provides enhanced routing, adaptive reconfiguration, efficient aggregation techniques, and dynamic congestion monitoring. Among HarborSync's strengths, stability bears out with a 90% rating, surpassing those of LEACH (78%), LEACH-C (82%), TEEN (88%), and PEGASIS (76%). When it comes to durability, HarborSync scores 88% better than LEACH (75%), LEACH-C (80%), TEEN (85%), and PEGASIS (72%). The HarborSync score is 3.85% for congestion control compared to LEACH and LEACH-C, managing 5.22%, TEEN accomplishing 4.98%, and PEGASIS with 7.32%. Regarding adaptability, HarborSync showcases its versatility, earning an 85% rating, surpassing LEACH (72%), competes with LEACH-C (78%), equals TEEN (90%), and outperforms PEGASIS (68%). In the critical realm of packet loss management, HarborSync demonstrates efficiency with a reduced rate of 6.179%. Therefore, it outperforms LEACH (7.811%), LEACH-C (6.897%), TEEN (4.953%), and PEGASIS (7.973%).

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Section: Proposed Methodologymentioning

confidence: 99%

HarborSync: An Advanced Energy-efficient Clustering-based Algorithm for Wireless Sensor Networks to Optimize Aggregation and Congestion Control

Aqeel

2024

IJACSA

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“…Cognitive radio networks can articulate multipurpose spectrum management [ 12 ] by enabling secondary users to provisionally use the licensed spectrum lacking a primary user. Each secondary user carries out spectrum sensing and transmits the collected data to the centralized controller in a backward induction approach.…”

Section: Methodsmentioning

confidence: 99%

Spectrum Sensing, Clustering Algorithms, and Energy-Harvesting Technology for Cognitive-Radio-Based Internet-of-Things Networks

Fernando,

Lăzăroiu

2023

Sensors

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The aim of this systematic review was to identify the correlations between spectrum sensing, clustering algorithms, and energy-harvesting technology for cognitive-radio-based internet of things (IoT) networks in terms of deep-learning-based, nonorthogonal, multiple-access techniques. The search results and screening procedures were configured with the use of a web-based Shiny app in the Preferred Reporting Items for Systematic Reviews and Meta-analysis (PRISMA) flow design. AMSTAR, DistillerSR, Eppi-Reviewer, PICO Portal, Rayyan, and ROBIS were the review software systems harnessed for screening and quality assessment, while bibliometric mapping (dimensions) and layout algorithms (VOSviewer) configured data visualization and analysis. Cognitive radio is pivotal in the utilization of an adequate radio spectrum source, with spectrum sensing optimizing cognitive radio network operations, opportunistic spectrum access and sensing able to boost the efficiency of cognitive radio networks, and cooperative spectrum sharing together with simultaneous wireless information and power transfer able increase spectrum and energy efficiency in 6G wireless communication networks and across IoT devices for efficient data exchange.

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“…Every CH transmits the timing information in the beacon slot before switching to receiving state to accept network packets. By analyzing beacons, the CMs acquire the channel and continue following the received timing lists, which tell it when or how to wake up for communication 33 . Figure 3 depicts the TDMA procedure, which does not need low latency across clusters.…”

Section: Proposed Methodsmentioning

confidence: 99%

“…By analyzing beacons, the CMs acquire the channel and continue following the received timing lists, which tell it when or how to wake up for communication. 33 does not need low latency across clusters. The cycle of CHs does not quite alter the intracluster routing concept, but that does equalize the energy usage within every cluster.…”

Section: Time Division Multiple Access Processmentioning

confidence: 99%

Congestion centric multi‐objective reptile search algorithm‐based clustering and routing in cognitive radio sensor network

Sunitha¹,

Balmuri

Prado

et al. 2022

Trans Emerging Tel Tech

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In recent trends, Cognitive Radio Sensor Networks (CRSNs) are investigated in‐depth and getting momentum in all types of applications. CRSN can make use of the underutilized frequency spectrum in a suitable manner. Due to the above‐mentioned advantage, the scholars have initiated to study of the domain of cognitive radio routing. Network congestion produces transmission delays and packet loss, as well as time and energy wasted on recovery. In order to fulfill the energy efficiency and network lifetime in CRSN, Congestion Centric Multi‐Objective Reptile Search Algorithm (CC‐MORSA)‐based Clustering and Routing are used. The main objective of proposed CC‐MORSA is to improve the lifetime by minimizing the distance among the designated Cluster Head nodes which creates the fitness function by multiple objectives like energy, distance, and load. This technique is appropriate for common sensor nodes in coordinated communications infrastructure and large networks. The simulation results are analyzed through MATALB in terms of remaining energy (999.5 J), average delay (0.36 s), Packet Delivery Ratio (99.8%), Energy Consumption (24.1 J), Throughput (0.98 Mbps), routing overhead (0.54), and Packet Loss Rate (0.2%). From the outcomes, it shows that the presented CC‐MORSA outperformed conventional Stability‐Aware Cluster‐based Routing and Drop Factor‐Based Energy Efficient Routing technique.

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Adaptive cluster‐based heuristic approach in cognitive radio networks for5Gapplications

Cited by 26 publications

References 27 publications

HarborSync: An Advanced Energy-efficient Clustering-based Algorithm for Wireless Sensor Networks to Optimize Aggregation and Congestion Control

HarborSync: An Advanced Energy-efficient Clustering-based Algorithm for Wireless Sensor Networks to Optimize Aggregation and Congestion Control

Spectrum Sensing, Clustering Algorithms, and Energy-Harvesting Technology for Cognitive-Radio-Based Internet-of-Things Networks

Congestion centric multi‐objective reptile search algorithm‐based clustering and routing in cognitive radio sensor network

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