基于三维胞元空间的无线传感器网络路由算法

针对无线传感器网络路由算法中的3维空洞问题,该文提出3维胞元空间路由(3D Cell Space Routing,3D-CSR)算法.该算法针对贪婪算法中空洞区域无法路由的情况,利用3维胞元空间模型将这些空洞区域的边界加以确定,进一步运用胞元路由机制完成路由过程.同时,单个胞元内部采用了自适应选举机制,使其中的胞父节点保持活跃并参与路由而其余胞子节点保持休眠状态,以平衡网络能量消耗.仿真结果验证了3维胞元空间模型与3D-CSR 算法的正确性和有效性,与3D-GPR(3D Grid Position-based Routing)和3D-CFace (3D Coordinate Face)算法比较,3D-CSR 的消息发送率与节点存活率更高.     

一种基于信号机制的能量感知地理路由算法

在实际的无线传感器网络中,由于路由空洞的存在,采用边缘转发机制的地理路由算法容易使空洞边缘的节点由于负载较重,能量快速消耗从而过早的死亡,导致空洞进一步的扩大．为了使网络负载更加均衡,延长网络生命周期,提出了一种基于能量信号机制的地理路由算法SIENGR ．SIENGR将节点的初始能量划分3个能量区间,并用能量信号来标识节点的剩余能量所处的能量区间．SIENGR算法的边缘转发机制结合节点的能量信号,利用空洞边界节点的所有平面邻居节点来轮流承担边缘转发的数据量,使产生的路由能够根据节点能耗的情况,自适应地避开空洞边缘能量较少的热区节点,均衡热区附近节点的能量消耗,防止空洞扩大．仿真结果验证了SIENGR算法在网络生命周期、网络能耗均衡、数据包到达率等指标上的性能．     

动态分层的水下传感器网络分簇路由算法

针对平面路由难以适应较大规模水下传感器网络的局限,该文提出一种能更好地适用于较大规模网络的分簇路由算法DLCR(Dynamic Layered Clustering Routing)。该算法将网络自上向下划分为多层,并选择层内与sink节点距离较近、剩余能量较高的节点作为簇头节点,从而降低簇头节点的通信能耗。为了避免同一节点连续被选举为簇头节点,提出一种动态分层机制,每一轮数据采集周期都将网络重新划分为多层。实验证明DLCR不仅具有良好的稳定性,还降低了网络的能耗,延长了网络的寿命。     

基于跨层设计的无线传感器网络节能双向梯度路由算法

针对现有无线传感器网络梯度路由算法在下行路由创建过程和能量更新机制中存在冗余控制开销的问题,该文提出一种采用跨层和功率控制机制,具有节能功能的双向梯度路由算法(Cross-layer Energy-efficient Bidirectional Routing,CEBR):无需使用专门的控制分组,采用源路由方式以较小开销建立从Sink节点通往传感器节点的下行路由;通过跨层信息共享,定期采集节点剩余能量信息并按需发布;设计使用含跳数和节点剩余能量的合成路由度量标准,减少节点能量和网络带宽消耗的同时均衡节点能耗;结合RSSI(Received Signal Strength Indication)测距实现节点发射功率控制从而在数据及查询分组发送过程中节约节点能量。理论分析表明了CEBR的有效性;仿真结果显示:与现有的典型相关算法相比,CEBR能够在建立双向梯度路由的前提下,至少降低34.5%的归一化控制开销和27.12%的数据分组平均能耗,并使网络生存期延长18.98%以上。     

k跳受限泛洪的能量平衡组播路由算法

组播路由算法(Energy-Balanced Multicast Routing,EBMR)把无线传感器网络节点的剩余能量作为建立组播路由的重要因子,在不引入过长路径的同时优先选择剩余能量高的节点作为组播数据转发节点,构建组播能量平衡树(EB-Tree),从网络能量均衡消耗的角度来延长了无线传感器网络的生存时间.针对EBMR算法路由开销较大的问题,提出了k跳受限泛洪的能量平衡组播路由算法k-EBMR,控制组播路由报文在k跳范围内传播,并且研究了影响算法性能的关键因子的选取.仿真实验表明,与EBMR算法相比,k-EBMR算法较大程度上降低了路由控制报文的传输,提高了节点能量有效使用性,进一步延长了网络生存时间.     

一种基于节点能量的机会网络概率路由算法

在机会网络中,节点之间可能不存在端到端的路径.为了节省网络中节点消耗的能量,在概率路由算法的基础上提出了一种基于节点能量的概率路由算法(Energy-based Probabilistic Routing Protocol using History of Encounters and Transitivity,EBPROPHET).首先,计算两个节点相遇时节点的通信开销,然后相遇节点的剩余能量作为一个参量引入算法,选择节点剩余能量多的节点作为转发节点,最后,进行消息的转发.仿真表明,EB-PROPHET算法具有良好的路由性能,降低了整个网络的能量消耗,延长了网络的生存周期.     

基于灰色关联的ZigBee网络混合路由算法研究

ZigBee网络混合路由算法(ZigBee Routing,ZBR)中将源目的节点之间的最小跳数作为唯一的路由度量因素。但随着节点能量消耗以及节点的频繁移动,ZBR算法的这一特性会造成网络间歇性连接,从而导致网络性能下降。本文提出一种选择最优分组转发路径的ZigBee网络混合路由算法—GRA-ZBR算法。GRA-ZBR算法在目的节点选择路径时引入灰色关联算法,综合考虑节点剩余能量、链路质量、节点剩余队列长度、以及路径长度等因素。仿真结果表明：GRA-ZBR算法可以有效提高网络分组投递率,降低平均端到端时延。     

无线传感网络移动分簇路由策略

无线传感网络(WSN)路由协议中,分簇路由具有拓扑管理方便、能量高效和数据融合简单等优点,成为当前重点研究的路由技术。通过研究各种环境下的移动传感器网络,有效地降低能耗则是研究移动无线传感器网络的重要目的之一。针对无线传感网络中移动性问题,基于LEACH协议,利用移动传感器网络中节点距离、速度和剩余能量等因素提出了能量高效的移动分簇路由算法。实验结果表明此算法能够较好地支持节点移动,从而降低网络能耗,延长网络生存时间。     

基于灰色关联的ZigBee网络混合路由算法

ZigBee网络混合路由算法(ZigBee Routing,ZBR)中将源节点和目的节点之间的最小跳数作为唯一的路由度量因素.但随着节点能量消耗以及节点的频繁移动,ZBR算法的这一特性会造成网络间歇性连接,从而导致网络性能下降.提出一种选择最优分组转发路径的ZigBee网络混合路由算法(Grey Relational Algorithm based ZBR,GRA-ZBR).GRA-ZBR算法在目的节点选择路径时引入灰色关联算法,综合考虑节点剩余能量、链路质量、节点剩余队列长度以及路径长度等因素.仿真结果表明,GRA-ZBR算法可以有效提高网络分组投递率,降低平均端到端时延.     

MANET中一种具有能量意识的无信标地理路由算法

 地理路由具有有效的传输性能和良好的可扩展能力,是当前移动Ad Hoc网络路由算法中的一个研究热点. 在许多实际场合下,网络中的节点能量有限并且难以补充,所以合理调整节点之间的能量消耗成为提高网络寿命的一种重要手段. 本文针对贪婪转发和空洞解决方案中存在的节点能量消耗不平衡的问题,提出了一种具有能量意识的无信标地理路由算法EBGR (Energy-Aware and Beaconless Geographic Routing). 该算法包括两个模式：贪婪竞争策略和空洞解决策略. 在贪婪竞争策略中,源节点或中继节点（即上游节点）广播数据包,位于数据包转发域内具有最小动态转发延迟的节点（即下游节点）转发数据包,其余候选节点侦听到该广播包后,自动放弃转发该数据包. 当遇到节点空洞时,将角度和能量信息同时加入到转发节点的动态延迟计算中,从而在数据包转发过程中有效地避绕空洞和平衡节点间的能量消耗. 仿真结果表明,与已有的BLR和GEAR等典型地理路由算法相比,平均投递率提高2%到4%;平均网络寿命提高了10%到20%.     

无线自组传感器网络中基于能量的超宽带多路径路由算法

The Energy based Ultra-Wideband Multipath Routing (EUMR) algorithm for Ad hoc sensor network is proposed. It utilizes the function of UWB positioning to reduce the network communication delay and route overhead. Furthermore, the algorithm considers energy consumption, the residual energy and node hops of communication paths to make energy consumption more balanced and extend the network lifetime. Then routing which is stable, energy-saving and low-delay is realized. Simulation results show that the algorithm has better performance on saving energy, route overhead, stability and extending network lifetime.     

Load‐balanced data gathering in Internet of Things using an energy‐aware cuckoo‐search algorithm

This paper deals with the lifetime problem in the Internet of Things. We first propose an efficient cluster‐based scheme named “Cuckoo‐search Clustering with Two‐hop Routing Tree (CC‐TRT)” to develop a two‐hop load‐balanced data aggregation routing tree in the network. CC‐TRT uses a modified energy‐aware cuckoo‐search algorithm to fairly select the best cluster head (CH) for each cluster. The applied cuckoo‐search algorithm makes the CH role to rotate between different sensors round by round. Subsequently, we extend the CC‐TRT scheme to present two methods for constructing multi‐hop data aggregation routing trees, named “Cuckoo‐search Clustering with Multi‐Hop Routing Tree (CC‐MRT)” and “Cuckoo‐search Clustering with Weighted Multi‐hop Routing Tree (CC‐WMRT).” Both CC‐MRT and CC‐WMRT rely on a two‐level structure; they not only use an energy‐aware cuckoo‐search algorithm to fairly select the best CHs but also adopt a load‐balanced high‐level routing tree to route the aggregated data of CHs to the sink node. However, CC‐WMRT slightly has a better performance thanks to its low‐level routing strategy. As an advantage, the proposed schemes balance the energy consumption among different sensors. Numerical results show the efficiency of the CC‐TRT, CC‐MRT, and CC‐WMRT algorithms in terms of the number of transmissions, remaining energy, energy consumption variance, and network lifetime.     

Q-MOHRA: QoS Assured Multi-objective Hybrid Routing Algorithm for Heterogeneous WSN

Quality of Service (QoS) assurance in Wireless Sensor Network (WSN) is a tough task, and it is more exciting due to the scarcity of resources. The requirement of different WSN applications running over has different constraints. In QoS, routing protocol the network has to balance the traffic. This paper presents a novel heuristic routing algorithm known as QoS assured Multi-objective Hybrid Routing Algorithm (Q-MOHRA) for Heterogeneous WSN. Q-MOHRA takes into account the link (energy, hop count, link quality indicator etc.) and path (jitter) metrics for optimal path selection. The performance of Q-MOHRA is evaluated through intensive simulation and equated with Simple Hybrid Routing Protocol (SHRP) and Dynamic Multi-objective Routing Algorithm (DyMORA). The metrics such as average energy consumption, residual energy, packet delivery ratio, jitter, and normalized routing load are used for comparison. The performance of Q-MOHRA has been observed to outclass SHRP and DyMORA. It improves the packet delivery ratio by 24.31% as compared to SHRP and 11.86% as compared to DyMORA. Q-MOHRA outperforms DyMORA in terms of average energy consumption by a factor of 8.27%.     

基于地理位置的无线传感器网络路由协议

基于地理位置的路由协议是无线传感器网络路由协议研究的一个重要方向。利用位置信息指导路由的发现、维护和数据转发,能够优化路径选择,减少路由能耗,实现网络的全局优化。从限制洪泛机制、虚拟分区机制、最优路由确认机制3个方面,可以看出地理位置信息在路由协议中的重要性。     

光无线混合接入网中风险感知节能路由算法

研究了光无线混合接入网中具有抗毁能力的节能路由问题,结合光网络单元(ONU)休眠控制和风险备用路由表维护机制,提出一种有效的可靠绿色路由算法。该算法为每个无线路由器维护一个风险表,以记录网络中路径是否可用以及ONU活跃与否的状态信息,通过鼓励选择ONU活跃的可用路径来传输数据,可降低全网丢包率和能耗。仿真结果表明:该算法能够在稳定丢包率的同时更好地节省能量。     

MintRouteEE:一种无线传感器网络能量有效的路由协议

路由是无线传感器网络的关键问题之一。通过分析TinyOS系统中MintRoute路由协议的主要结构和路由策略。提出一种能量有效的路由协议MintRouteEE。模拟结果表明，MintRouteEE能够较大地降低网络的能耗，从而达到延长网络生存时间的目的。     

Optimized mobile sink based grid coverage-aware sensor deployment and link quality based routing in wireless sensor networks

Mobile sink (MS) has been used in wireless sensor networks (WSN) to increase the network lifetime by changing the location over time. The major quality of service given by WSN is coverage energy consumption (EC) and network lifetime. There are many methods implemented for enhance the coverage hole restoration and reduce the EC. We propose a novel MSCOLER (MS based Coverage Optimization and Link-stability Estimation Routing) protocol for Optimal Coverage restoration and Link stability Estimation. An optimization algorithm is used to optimize the coverage hole and move the redundant node besides the hole. During the routing process, link quality based routing is used to discover the relay nodes with the estimation of link stability to enhance the entire network lifetime and practically make the perfect transmission distance for energy saving. Experimental results demonstrate that proposed protocol can solve the coverage restoration problem, decrease the EC and reduce the network lifetime. The performance is evaluated regarding Average of residual energy (ARE), Receiving packets ratio (RPR), Moving energy consumption (MEC), Network lifetime (NL), Percentage of coverage (%C) and Average Energy Consumption (AEC).     

A Centralized Balance Clustering Routing Protocol for Wireless Sensor Network

Routing protocol plays a role of great importance in the performance of wireless sensor networks (WSNs). A centralized balance clustering routing protocol based on location is proposed for WSN with random distribution in this paper. In order to keep clustering balanced through the whole lifetime of the network and adapt to the non-uniform distribution of sensor nodes, we design a systemic algorithm for clustering. First, the algorithm determines the cluster number according to condition of the network, and adjusts the hexagonal clustering results to balance the number of nodes of each cluster. Second, it selects cluster heads in each cluster base on the energy and distribution of nodes, and optimizes the clustering results to minimize energy consumption. Finally, it allocates suitable time slots for transmission to avoid collision. Simulation results demonstrate that the proposed protocol can balance the energy consumption and improve the network throughput and lifetime significantly.