Sedighe Hedayati, Payam Mahmoudi-Nasr, Sekine Asadi Amiri
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引用次数: 0
摘要
计算机技术和无线通信的发展为世界带来了无线体域网(WBAN)。在 WBAN 中,病人的生命体征由嵌入体内的小型传感器监测。传感器节点的工作能源有限,因此能耗是这些网络的一个主要问题。数据传输引起的温度升高会对人体组织造成严重损害。本文提出了一种能量-温度感知路由协议(ETAR)来解决这个问题。在 ETAR 中,路由是通过中继节点直接和多跳完成的。多跳数据转发在降低能耗方面发挥着重要作用。在所提出的方法中,中继节点是通过模糊推理系统来选择的。能量、温度和距离参数被定义为模糊系统的输入。因此,在每一轮中,都会选择剩余能量较多、温度较低、与邻居距离较远的节点作为中继节点。所提出的协议通过为传感器设定温度限制,减少了温度对人体的不利影响。在同质和异质网络中对 ETAR 的性能进行了评估。在同质网络中,与 THE 和 EEMR 相比,该协议的能耗分别降低了 44% 和 55%。与 THE 和 EEMR 相比,网络寿命分别提高了 46% 和 55%。吞吐量分别比 THE 和 EEMR 提高了 40% 和 34%。在异构网络中,与 THE 和 EEMR 相比,该协议的能耗分别提高了 47% 和 52%。与 THE 和 EEMR 相比,网络寿命分别提高了 62% 和 65%。吞吐量比 THE 提高了 100%,比 EEMR 提高了 97%。
An energy-temperature aware routing protocol in wireless body area network: a fuzzy-based approach
The development of computer technology and wireless communication has introduced the wireless body area network (WBAN) to the world. In WBAN, the patient’s vital signs are monitored by small sensors embedded in the body. Sensor nodes work with a limited energy source, so energy consumption is a major issue in these networks. The increase in temperature caused by data transmissions can cause serious damage to body tissue. This paper proposes an Energy-Temperature Aware Routing (ETAR) protocol to solve this problem. In ETAR, routing is done directly and multi-hop using relay nodes. Multi-hop data forwarding plays a significant role in reducing energy consumption. In the proposed method, relay nodes are selected using a fuzzy inference system. Energy, temperature, and distance parameters are defined as the inputs of the fuzzy system. Therefore, in each round, a node with more remaining energy, lower temperature, and less distance from its neighbors is selected as the relay node. The proposed protocol reduces the adverse effects of temperature on the body by setting temperature limits for sensors. The performance of ETAR was evaluated for homogeneous and heterogeneous networks. In homogenous network, this protocol improves energy consumption by 44% and 55% compared to THE and EEMR. Network lifetime is enhanced by 46% and 55% compared to THE and EEMR. The throughput is improved by 40% compared to THE and 34% compared to EEMR, respectively. In a heterogeneous network, this protocol improves energy consumption by 47% and 52% compared to THE and EEMR. Network lifetime is enhanced by 62% and 65% compared to THE and EEMR, respectively. The throughput is improved by 100% compared to THE and 97% compared to EEMR.
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