Wireless propagation modelling inside a business jet

IEEE EUROCON 2009 Pub Date : 2009-05-18 DOI:10.1109/EURCON.2009.5167863

K. Chetcuti, C. J. Debono, R. Farrugia, Serge Bruillot

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引用次数: 19

Abstract

Wireless communication on-board aircraft has recently received increased attention as passengers are demanding for seamless office-like communication environments during their flight. Aircraft manufacturers are also interested in this technology to reduce cable complexity and provide new in-flight services. Various technologies are being considered for this purpose, such as IEEE802.11a/b/g. A radio propagation map is necessary to determine the received signal strengths inside the environment and can be obtained either through accurate modelling or through a measurement campaign. A simulation model is more attractive as it can be used to identify ideal antenna locations that maximize coverage at the design stage. Since the business jet market necessitates customized cabin configurations for each customer this will avoid costly measurement campaigns. This work presents a novel simulation model which has been used to characterize propagation characteristics inside a Dassault Aviation business jet. The developed package is based on geometric optics (GO) and adopts ray tracing techniques. Simulation results were compared with actual measurements performed on-board the aircraft with a good correlation between the two. This study takes into account only a static channel whereby all passengers are seated.

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公务机内部的无线传播建模

最近，随着乘客们对飞行过程中像办公室一样的无缝通信环境的要求越来越高，机载无线通信受到了越来越多的关注。飞机制造商也对这项技术感兴趣，以降低电缆的复杂性并提供新的飞行服务。为此目的正在考虑各种技术，例如IEEE802.11a/b/g。无线电传播图对于确定环境内接收到的信号强度是必要的，可以通过精确的建模或通过测量活动获得。仿真模型更有吸引力，因为它可以在设计阶段用于确定理想的天线位置，使覆盖范围最大化。由于公务机市场需要为每个客户定制客舱配置，这将避免昂贵的测量活动。本文提出了一种新的仿真模型，用于表征达索航空公务机内部的传播特性。开发的封装基于几何光学(GO)并采用光线追踪技术。将仿真结果与飞机上的实际测量结果进行了比较，两者之间具有良好的相关性。这项研究只考虑了所有乘客都坐着的静态通道。

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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IEEE EUROCON 2009

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