Cross-layer cluster-based energy-efficient protocol for wireless sensor networks

Recent developments in electronics and wireless communications have enabled the improvement of low-power and low-cost wireless sensors networks (WSNs). One of the most important challenges in WSNs is to increase the network lifetime due to the limited energy capacity of the network nodes. Another ma...

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Published in:Sensors (Basel, Switzerland) Switzerland), 2015-04, Vol.15 (4), p.8314-8336
Main Authors: Mammu, Aboobeker Sidhik Koyamparambil, Hernandez-Jayo, Unai, Sainz, Nekane, de la Iglesia, Idoia
Format: Article
Language:English
Subjects:
Aggregation
Algorithms
cluster
Clustering
Clusters
Computer Communication Networks
energy
Energy consumption
Energy resources
Load
MAC
Networks
Optimization
Protocol
Remote sensors
Residual energy
routing
sensor
Sensors
Wireless networks
Wireless Technology
WSN
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cited_by cdi_FETCH-LOGICAL-c575t-d5e70e572c582f269395710bdcb864377c741044abbbca699bcd2852ac9f59823
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container_title Sensors (Basel, Switzerland)
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creator Mammu, Aboobeker Sidhik Koyamparambil
Hernandez-Jayo, Unai
Sainz, Nekane
de la Iglesia, Idoia
description Recent developments in electronics and wireless communications have enabled the improvement of low-power and low-cost wireless sensors networks (WSNs). One of the most important challenges in WSNs is to increase the network lifetime due to the limited energy capacity of the network nodes. Another major challenge in WSNs is the hot spots that emerge as locations under heavy traffic load. Nodes in such areas quickly drain energy resources, leading to disconnection in network services. In such an environment, cross-layer cluster-based energy-efficient algorithms (CCBE) can prolong the network lifetime and energy efficiency. CCBE is based on clustering the nodes to different hexagonal structures. A hexagonal cluster consists of cluster members (CMs) and a cluster head (CH). The CHs are selected from the CMs based on nodes near the optimal CH distance and the residual energy of the nodes. Additionally, the optimal CH distance that links to optimal energy consumption is derived. To balance the energy consumption and the traffic load in the network, the CHs are rotated among all CMs. In WSNs, energy is mostly consumed during transmission and reception. Transmission collisions can further decrease the energy efficiency. These collisions can be avoided by using a contention-free protocol during the transmission period. Additionally, the CH allocates slots to the CMs based on their residual energy to increase sleep time. Furthermore, the energy consumption of CH can be further reduced by data aggregation. In this paper, we propose a data aggregation level based on the residual energy of CH and a cost-aware decision scheme for the fusion of data. Performance results show that the CCBE scheme performs better in terms of network lifetime, energy consumption and throughput compared to low-energy adaptive clustering hierarchy (LEACH) and hybrid energy-efficient distributed clustering (HEED).
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source Publicly Available Content Database; PubMed Central
subjects Aggregation
Algorithms
cluster
Clustering
Clusters
Computer Communication Networks
energy
Energy consumption
Energy resources
Load
MAC
Networks
Optimization
Protocol
Remote sensors
Residual energy
routing
sensor
Sensors
Wireless networks
Wireless Technology
WSN
title Cross-layer cluster-based energy-efficient protocol for wireless sensor networks
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