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Wireless in-cabin communication for aircraft infrastructure

A holistic approach for on-board high data-rate UWB network

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Abstract

Wireless communication networks have recently gained appeal among aircraft manufacturers as a cost-effective manner to provide services to crew and passengers. A preliminary survey study has indicated Ultra Wideband (UWB) technology and in particular a solution implementing ECMA-368 protocol as one of the most promising means to develop high-data rate networks within the airplane. Some interesting products have already reached mass market, although most of them comply with the Wireless-USB specification and are therefore conceived to offer wireless connectivity to external peripherals or small networks with a “host-device” architecture.

In this paper we analyse the issues which emerge when the ECMA-368 Physical and Medium Access Control (MAC) protocols are used as underlying layer for the realization of complex IP networks and point out the specific challenges related to the aeronautical use case. Solutions for optimal node placement, quality of service mechanisms and loss-free mobility support are presented in theoretical and practical approaches. The work supports the aircraft manufacturing and operation with a fundamental protocol analysis, assisting methods during the design phase and algorithms for the operation of the aircraft.

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References

  1. Niebla, C. (2003). Coverage and capacity planning for aircraft in-cabin wireless heterogeneous networks. In IEEE vehicular technology conference.

    Google Scholar 

  2. Jones, W., & de La Chapelle, M. (2001). Connexion by Boeing/sup SM/-broadband satellite communication system for mobile platforms. In IEEE military communications conference.

    Google Scholar 

  3. Tsuboi, T., Yamada, J., & Yamauchi, N. (2007). UWB radio propagation inside vehicle environments. In ITST telecommunications.

    Google Scholar 

  4. Chuang, J., Xin, N., Huang, H., Chiu, S., & Michelson, D. (2007). UWB radiowave propagation within the passenger cabin of a Boeing 737-200 aircraft. In VTC spring. New York: IEEE Press.

    Google Scholar 

  5. Schmidt, I., Enders, A., Schwark, M., Schuur, J., Geise, R., Schirrmacher, M., & Stoefen, H. (2008). UWB aircraft transfer function measurements in the frequency range from 2 to 8 GHz. In 2008 international symposium on electromagnetic compatibility—EMC Europe.

    Google Scholar 

  6. Jacob, M., Chee, K. L., Schmidt, I., Schuur, J., Fischer, W., Schirrmacher, M., & Kurner, T. (2009). Influence of passengers on the uwb propagation channel within a large wide-bodied aircraft. In 3rd European conference on antennas and propagation, EuCAP 2009.

    Google Scholar 

  7. Barrett, T. W. (2000). History of UltraWideBand (UWB) radar & communications: pioneers and innovators. In Progress in electromagnetics symposium, July 2000.

    Google Scholar 

  8. ECMA International. ECMA-368: high rate ultra wideband PHY and MAC standard (3rd ed.), December 2008.

  9. Harary, F. (1974). Graphentheorie. Munich: Oldenbourg.

    Google Scholar 

  10. Vishnevsky, V., Lyakhov, A., Safonov, A., Mo, S., & Gelman, A. (2006). Beaconing in distributed control wireless PAN: problems and solutions. In Consumer communications and networking conference. New York: IEEE Press.

    Google Scholar 

  11. Ceria, S., Nobili, P., & Sassano, A. (1997). Set covering problem. In M. Dell’Amico, F. Maffioli, & S. Martello (Eds.), Annotated bibliographies in combinatorial optimization. New York: Wiley.

    Google Scholar 

  12. Tutschku, K. (1998). Demand-based radio network planning of cellular mobile communication systems. In Proceedings of the IEEE infocom 98 (pp. 1054–1061). New York: IEEE Press.

    Google Scholar 

  13. So, A., & Liang, B. (2005). An efficient algorithm for the optimal placement of wireless extension points in rectilineal wireless local area networks. In Second international conference on quality of service in heterogeneous wired/wireless networks (pp. 9–25), August 2005.

    Google Scholar 

  14. Prommak, C., Kabara, J., Tipper, D., & Charnsripinyo, C. (2002). Next generation wireless LAN system design. In MILCOM 2002. Proceedings (Vol. 1, pp. 473–477), Oct. 2002.

    Chapter  Google Scholar 

  15. Mateus, G., Loureiro, A., & Rodrigues, R. (2001). Optimal network design for wireless local area network. Annals of Operations Research, 106(15), 331–345.

    Article  Google Scholar 

  16. Hills, A. (2001). Large-scale wireless LAN design. IEEE Communications Magazine, 39, 98–107.

    Article  Google Scholar 

  17. Kamenetsky, M., & Unbehaun, M. (2002). Coverage planning for outdoor wireless LAN systems. In International Zurich seminar on broadband communications, 2002. Access, transmission, networking (pp. 49–1–49–6).

    Google Scholar 

  18. Bosio, S., Capone, A., & Cesana, M. (2007). Radio planning of wireless local area networks. IEEE/ACM Transactions on Networking, 15(6), 1414–1427.

    Article  Google Scholar 

  19. Eisenblatter, A., Geerdes, H.-F., & Siomina, I. (2007). Integrated access point placement and channel assignment for wireless LANs in an indoor office environment. In IEEE international symposium on a world of wireless, mobile and multimedia networks (WoWMoM 2007) (pp. 1–10), June 2007.

    Chapter  Google Scholar 

  20. Gondran, A., Baala, O., Caminada, A., & Mabed, H. (2007). Joint optimization of access point placement and frequency assignment in WLAN. In 3rd IEEE/IFIP international conference in Central Asia on Internet (ICI 2007) (pp. 1–5), Sept. 2007.

    Chapter  Google Scholar 

  21. RTCA, Inc. (1992). Do-178b: Software considerations in airborne systems and equipment certification.

  22. Ramos, N., Panigrahi, S., & Dey, D. (2005). Quality of service provisioning in 802.11e networks: challenges, approaches and future directions. In IEEE Network, July/August 2005.

    Google Scholar 

  23. Grilo, A., Macedo, M., & Nunes, M. (2003). A scheduling algorithm for QoS support in IEEE 802.11e networks. In IEEE wireless communications, June 2003.

    Google Scholar 

  24. Larcheri, P., & Lo Cigno, R. (2006). Scheduling in 802.11e: open-loop or closed-loop. In IEEE/IFIP conference on wireless on demand network systems and services. New York: IEEE Press.

    Google Scholar 

  25. WiMedia Logical Link Control Protocol, approved draft 1.0 (2007).

  26. Skyrianoglou, D., Passas, N., & Salkintzis, A. (2006). ARROW: an efficient traffic scheduling algorithm for IEEE 802.11e HCCA. IEEE Transactions on Wireless Communications, 5(12).

  27. P, A., Ni, Q., & Turletti, T. (2006). FHCF: a simple and efficient scheduling scheme for IEEE 802.11e wireless LAN. Mobile Networks and Applications, 11(3), 391–403. Special Issue Modeling Opt..

    Article  Google Scholar 

  28. IEEE std 802.11-2007 wireless LAN medium access control (mac) and physical layer (phy) specifications (2007).

  29. Perkins, C. (2002). IP mobility support for IPv4, August 2002. RFC3344.

  30. Johnson, D., Perkins, C., & Arkko, J. (2004). Mobility support in IPv6, June 2004, RFC3775.

  31. Koodli, E. R. (2005). Fast handovers for mobile IPv6, July 2005. RFC4068.

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Authors and Affiliations

  1. Institute of Communication Networks, Technical University of Munich, 80290, Munich, Germany

    Frank Leipold

  2. Sensors, Electronics & Systems Integration, EADS Innovation Works, 81663, Munich, Germany

    Dimitri Tassetto & Sergio Bovelli

Authors
  1. Frank Leipold
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  2. Dimitri Tassetto
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  3. Sergio Bovelli
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Correspondence to Sergio Bovelli.

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Leipold, F., Tassetto, D. & Bovelli, S. Wireless in-cabin communication for aircraft infrastructure. Telecommun Syst 52, 1211–1232 (2013). https://doi.org/10.1007/s11235-011-9636-8

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  • DOI: https://doi.org/10.1007/s11235-011-9636-8

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