无线传感器网络故障节点恢复的改进算法

Darwish Im, E. Sm
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引用次数: 4

摘要

在无线传感器网络(WSN)中,传感环境与众多传感器节点的部署相结合,造成了严重的安全威胁,因此需要信任保证机制。对于大规模WSN,大量中间节点的存在负责将数据转发到汇聚节点。由于采用电池供电的传感器,充电和更换机制具有节能和最小网络寿命的优点。传输路径上故障节点的识别在节能方面起着重要的作用。随着传感器节点的密集部署,节点和链路故障高,导致整个通信中断。本文提出了一种适用于节点间通信的备选无故障路径预测模型。最初,传感器节点部署在WSN环境中。源节点和目的节点初始化完成后,通过哈密顿路径预测模型预测它们之间的路径。在故障场景中,分别估计接收信号强度指标(RSSI)、队列大小、响应时间和带宽等节点和链路参数,并将其分组为质量因子(QF)。在此基础上,提出了一种无故障链路的预测方法,减少了向故障节点的不必要传输,降低了能量消耗。将提出的基于哈密顿路径的超立方体(HPHC)网络与现有故障检测机制在包投递率(PDR)、故障节点检测率、吞吐量和端到端延迟等性能指标上进行比较,保证了HPHC在WSN通信中的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Enhanced Algorithms for Fault Nodes Recovery in Wireless Sensors Network
An integration of sensing environment with the numerous deployments of sensor nodes in Wireless Sensor Network (WSN) causes the severe security threats and hence the trust assurance mechanisms are required. For the large scale WSN, the existence of a number of intermediate nodes is responsible for the data forwarding to the sink node. Due to the battery operated sensors, the recharge and replace mechanisms suffer from the energy conservation and minimum network lifetime. The identification of fault nodes on the transmission path plays the major role in energy conservation. With the dense deployment of sensor nodes, the failures in node and link are high that disrupts the entire communication. This paper proposes the suitable alternative fault-free path prediction model to perform the communication among the nodes. Initially, the sensor nodes are deployed in the WSN environment. Once the initialization of source and destination nodes are over, the path between them is predicted through the Hamiltonian path prediction model. During the failure, scenario, this paper estimates the node and link parameters such as Received Signal Strength Indicator (RSSI), queue size, response time, and bandwidth are individually estimated and group them into the Quality Factor (QF). Based on the QF, the proposed work predicts the fault-free link to alleviate the unnecessary transmissions to the fault node and reduces the energy consumption. The comparison between the proposed Hamiltonian Path-based Hyper Cube (HPHC) network with the existing fault detection mechanisms regarding the performance measures such as Packet Delivery Ratio (PDR), fault node detection rate, throughput and end-to-end delay assures the effectiveness of HPHC in WSN communication.
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