Radio altimeter interference mitigation in wireless avionics intra-communication networks

2017 15th International Symposium on Modeling and Optimization in Mobile, Ad Hoc, and Wireless Networks (WiOpt) Pub Date : 2017-05-15 DOI:10.23919/WIOPT.2017.7959893

L. Hanschke, Leo Krüger, T. Meyerhoff, C. Renner, A. Timm‐Giel

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引用次数: 13

Abstract

On-board commercial passenger aircraft Wireless Sensor Networks (WSNs) are anticipated to be used for implementing machine-to-machine communication also referred to as Wireless Avionics Intra-Communications (WAIC). These systems enable safety-related wireless avionics and aim to reduce electrical wiring harness contributing by 5% of the total weight of an aircraft. The globally harmonized frequency band designated for WAIC usage is shared with aeronautical Radio Altimeters (RAs). Literature lacks consideration of the impact of on-board RAs on WAIC systems; thus, we close this gap by performing a detailed study and propose two mitigation techniques based on channel hopping. Our simulations show that harmful RA signals infer doubled to tripled delays as well as packet error rates up to 90% when WAIC systems use the frequency band without applying appropriate techniques for increasing communication robustness. With the developed mitigation techniques, we show delays can be kept at levels comparable to non-interfered performance while increasing the usable spectrum by 50% simultaneously. Our evaluations show that the presented mitigation techniques enable reliable usage of WAIC systems in commercial aircraft allowing increased spectrum usage.

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无线航空电子内部通信网络中无线电高度计干扰的缓解

商用客机机载无线传感器网络(wsn)预计将用于实现机器对机器通信，也称为无线航空电子内部通信(WAIC)。这些系统可以实现与安全相关的无线航空电子设备，并旨在减少占飞机总重量5%的电气线束。指定用于WAIC使用的全球协调频带与航空无线电高度表(RAs)共享。文献缺乏考虑机载RAs对WAIC系统的影响;因此，我们通过进行详细的研究来缩小这一差距，并提出了两种基于信道跳变的缓解技术。我们的模拟表明，当WAIC系统使用频带而没有应用适当的技术来增加通信鲁棒性时，有害的RA信号推断出两倍到三倍的延迟以及高达90%的数据包错误率。通过开发的缓解技术，我们可以将延迟保持在与无干扰性能相当的水平，同时将可用频谱增加50%。我们的评估表明，所提出的缓解技术能够在商用飞机上可靠地使用WAIC系统，从而增加频谱使用量。

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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2017 15th International Symposium on Modeling and Optimization in Mobile, Ad Hoc, and Wireless Networks (WiOpt)

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