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Possible Improvements in Meteorology for Aircraft Navigation

Published online by Cambridge University Press:  23 November 2009

M. Bisiaux ,
M. E. Cox ,
D. A. Forrester  and
J. T. Storey
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Extract

Based on a survey of its members in Europe and the Middle East, IATA expects that by 1985 almost half their aircraft will be equipped with Flight Management Systems (FMSs) incorporating 2-D, 3-D or 4-D navigational capabilities. The prime aim of this very significant investment is to increase airline operating efficiency, in particular through fuel saving. Flight Management Systems can perform a wide range of tasks, including flight planning and performance management, for which inputs of meteorological data are required. The more sophisticated systems can accept a number of wind and temperature inputs for the climb and descent profiles plus a wind input at each way-point of the cruise phase. Any estimate of flight progress and fuel requirements based on the use of the most economical aircraft speeds, whether made by the pilot or by an FMS, can only be as good as the knowledge of the wind-vector data pertinent to the flight. Whereas FMS-equipped aircraft in level cruise can often ‘update’ or correct the forecast data relating to the next flight leg, this is not feasible when major changes of altitude are necessary, e.g. during the descent phase. Accurate meteorological data are essential to ensure the optimum results from the FMS.

During the early 1970s, before the fuel crisis began, some thought was being given to the problem of handling the rapidly increasing number of aircraft movements in Europe.

Type
Research Article
Information
The Journal of Navigation , Volume 36 , Issue 1 , January 1983 , pp. 54 - 63
Copyright
Copyright © The Royal Institute of Navigation 1983

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References

IATA (1981) Advanced Navigational Equipment carried by Aircraft Operating to and within the EUR Region. Report published by IATA Regional Technical Office, Geneva.Google Scholar
Anon. (1982). ‘Airborne Management Systems Survey’, Interavia, March 1982.Google Scholar
Martin, R. and Benoit, A. (1972). ‘Accurate Aircraft trajectory predictions applied to future en-route ATC’. Presented at IATA 19th Technical Conference, Dublin, 1972, Eurocontrol Doc. 772031, Eurocontrol, Brussels.Google Scholar
Tucker, G. B.Upper Winds over the World, Part III’, Geophysical Memoirs No. 105, Meteorological Office, Bracknell.Google Scholar
Jesson, J. and Storey, J. (1977). ‘Measurement of the Longitudinal Progress of Aircraft on Air Routes’, Report No. 106, Eurocontrol Experimental Centre, Brétigny, 1977.Google Scholar
Forrester, D. A.Data Link Applicaton Study: the Exploitation of Aircraft-derived Meteorological Data’, Eurocontrol Doc. 972030.Google Scholar
Sparkman, J. (1977). ‘Data relay packages for commercial ships and aircraft’, Instruments and methods of observation, Proc. WMO Conference, 1977, Hamburg, pp. 226–30.Google Scholar
Stein, K. J. (1981). ‘Reporting system offers weather data cost savings’. Aviation Week and Space Technology.Google Scholar
Orlando, V. and Drouilhet, P. R.Discrete Address Beacon System Functional Description’. Report No. FAA–RD–80–41, Federal Aviation Administration, Washington D.C.Google Scholar