热带植被环境中叶片对LoRaWAN路径丢失的影响

IF 1.5 Q3 TELECOMMUNICATIONS

IET Wireless Sensor Systems Pub Date : 2020-04-14 DOI:10.1049/IET-WSS.2019.0201

M. Ansah, R. Sowah, J. Melià-Seguí, F. Katsriku, Xavier Vilajosana, W. Owusu-Banahene

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引用次数: 10

摘要

:无处不在的远程监控计算使物联网应用于不同领域。无线传感器网络在偏远栖息地和农业监测方面的潜在影响怎么强调都不为过。LoRa(远程)特别适合需要低运营成本、远程无线通信技术、低数据速率和低功耗的应用。对于这种有前途的技术的工业和大规模部署，必须在经验和理论上进行评估和证明。为了网络设计的目的和设备的优化定位，作者评估了远程无线局域网(LoRaWAN)在热带植被环境中的传播。将传统的植被繁殖模型与实测数据进行了比较。自由空间模型最适合他们的数据，除了树冠区域的损失约为56 dB。研究结果可作为制定LoRaWAN部署规划的精确模型和仿真工具的经验依据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Characterising foliage influence on LoRaWAN pathloss in a tropical vegetative environment

: Ubiquitous computing for remote monitoring is enabling the Internet of Things applications in diverse areas. The potential impact of wireless sensor networks in remote habitat and agricultural monitoring cannot be overemphasised. LoRa (long range) is particularly well suited to applications requiring low operational costs, long-range wireless communication technology, low data rates and low power consumption. For industrial and large-scale deployment of this promising technology, it must be both empirically and theoretically evaluated and proven. For network design purposes and optimised positioning of devices, the authors evaluated long range wireless area network (LoRaWAN) propagation in a tropical vegetative environment. Traditional vegetation propagation models have been compared with the measured data. The free space model best fits their data except for the tree canopy area where the loss was about 56 dB. The result can be used as empirical bases to develop an accurate model and simulation tool for LoRaWAN deployment planning.

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来源期刊

IET Wireless Sensor Systems TELECOMMUNICATIONS-

CiteScore

4.90

自引率

5.30%

发文量

审稿时长

33 weeks

期刊介绍： IET Wireless Sensor Systems is aimed at the growing field of wireless sensor networks and distributed systems, which has been expanding rapidly in recent years and is evolving into a multi-billion dollar industry. The Journal has been launched to give a platform to researchers and academics in the field and is intended to cover the research, engineering, technological developments, innovative deployment of distributed sensor and actuator systems. Topics covered include, but are not limited to theoretical developments of: Innovative Architectures for Smart Sensors;Nano Sensors and Actuators Unstructured Networking; Cooperative and Clustering Distributed Sensors; Data Fusion for Distributed Sensors; Distributed Intelligence in Distributed Sensors; Energy Harvesting for and Lifetime of Smart Sensors and Actuators; Cross-Layer Design and Layer Optimisation in Distributed Sensors; Security, Trust and Dependability of Distributed Sensors. The Journal also covers; Innovative Services and Applications for: Monitoring: Health, Traffic, Weather and Toxins; Surveillance: Target Tracking and Localization; Observation: Global Resources and Geological Activities (Earth, Forest, Mines, Underwater); Industrial Applications of Distributed Sensors in Green and Agile Manufacturing; Sensor and RFID Applications of the Internet-of-Things ("IoT"); Smart Metering; Machine-to-Machine Communications.