Inventions Utilizing Satellite Navigation Systems in the Railway Industry – An Analysis of Patenting Activity

Authors

  • Pekka Salmi Lappeenranta University of Technology
  • Marko T. Torkkeli Lappeenranta University of Technology

DOI:

https://doi.org/10.4067/S0718-27242009000300005

Keywords:

Railways, transport, satellite navigation, GNSS, GPS, inventions, patents, signaling, train control.

Abstract

Applications based on the Global Navigation Satellite System (GNSS), in combination with different communication systems, have significantly helped to increase safety, efficiency and system capacity of operations in different modes of transportation. Here railway transport is no exception, although the number of applications based on GNSS has been considerably behind the number of those used in road transport. Since incorporating e.g. GPS receivers into modern signaling, train control and other railway systems has become usual, it is interesting to examine GNSS/GPS-based inventions and patenting trends more closely in this context. This paper analyses GNSS/GPS-related patents in the railway industry in order to shed light on the patenting activity in different countries/regions and to identify (and to a certain extent make a classification of) the main application areas for this technology.

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Author Biographies

Pekka Salmi, Lappeenranta University of Technology

Researcher, Department of Industrial Management

Marko T. Torkkeli, Lappeenranta University of Technology

Prof. of Technology and Business Innovations, Dept. of Industrial Management, Kouvola Unit Visiting Researcher at INESC Porto (Portugal)

References

BEDRICH, S., Gu, X. (2004). GNSS-based sensor fusion for safety-critical applications in rail traffic, Galileo and EGNOS Information Catalogue. http://www.galileoservices.org/library/2.1-Bedrich.pdf (Accessed 1 April 2009)

DEREKENARIS, G. et al. (2001). Integrating GIS, GPS and GSM technologies for the effective management of ambulances. Computers, Environment and Urban Systems, 25(3), pp. 267-278.

EC-DGTREN (2008). The Directorate-General for Energy and Transport www page for Galileo applications. http://ec.europa.eu/dgs/energy_transport/galileo/applications/rail_en.htm (Accessed 1 April 2009)

EULER, H.-J., Hill, C.D., Miller, U. (1996). Real-time precise GPS for railroad mapping. IEEE Position Location and Navigation Symposium, 1996, pp. 437-443.

FIRMIN, P.E. (2006). Satellite navigation technology applications for Intelligent Transport Systems: A European perspective. European Navigation Conference, Manchester, UK, 8-10 May, 2000. http://eprints.whiterose.ac.uk/2495/ (Accessed 1 April 2009)

GU, X. (2005). Feasibility of GNSS/Galileo-based train location for safety relevant applications. Signal + Draht, No. 1+2 / 2005, pp. 29-33.

GUO, T., Iwamura, K., Koga, M. (2007). Towards high accuracy road maps generation from massive GPS Traces data. IEEE Geoscience and Remote Sensing Symposium, 2007, pp. 667-670.

HAUPT, R., Kloyer, M., Lange, M. (2007). Patent indicators for the technology life cycle development. Research Policy, 36(3), pp. 387-398.

HILMOLA, O.-P. (2007). European railway freight transportation and adaptation to demand decline: Efficiency and partial productivity analysis from period of 1980-2003. International Journal of Productivity and Performance Management, 56(3), pp. 205-225.

LOBO, A.X. (1998). A review of automatic vehicle location technology and its real-time applications. Transport Reviews, 18(2), pp. 165-191.

MAKI, Y. (2005). A new train position detection system using GPS. Railway Technology Avalanche, No. 9, August 1, 2005, p. 53.

MARAIS, J., Lefebvre, S., Berbineau, M. (2004). Satellite propagation path model along a railway track for GNSS applications. IEEE Vehicular Technology Conference, 2004, pp. 4066-4070.

MARWEDEL, P., Gebotys, C. (2004). Secure and safety-critical vs. insecure, non safety-critical embedded systems: Do they require completely different design approaches? Proceedings of the international conference on Hardware/Software Codesign and System Synthesis, pp. 72-73.

MINTSIS, G. et al. (2004). Applications of GPS technology in the land transportation. European Journal of Operational Research, 152(2), pp. 399-409.

NEJIKOVSKY, B., Keller, E. (2000). Wireless communications based system to monitor performance of rail vehicles. Proceedings of the ASME/IEEE Joint Railroad Conference, 2000, pp. 111-124.

PACE, S. et al. (1995). The Global Positioning System: Assessing National Policies. Rand Corporation, Santa Monica, CA.

SASAKI, K. (2005). Position detection system using GPS for carbody tilt control. Quarterly Report of RTRI, 46(2), pp. 73-77.

TAYLOR, M.A.P., Woolley, J.E., Zito, R. (2000). Integration of the global positioning system and geographical information systems for traffic congestion studies. Transportation Research Part C: Emerging Technologies, 8(1-6), pp. 257-285.

YUAN, B.J.C., Chen, J.K.C., Lin, L.W.C. (2007). Exploring the market development trend and technological Innovation of GPS. Proceedings of the International Conference on Business And Information. Tokyo, Japan, July 10-13, 2007. http://ibacnet.org/bai2007/proceedings/ Papers/2007bai7343.doc (Accessed 1 April 2009)

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Published

2009-10-02

How to Cite

Salmi, P., & Torkkeli, M. T. (2009). Inventions Utilizing Satellite Navigation Systems in the Railway Industry – An Analysis of Patenting Activity. Journal of Technology Management & Innovation, 4(3), 46–58. https://doi.org/10.4067/S0718-27242009000300005

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Research Articles

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