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Linearised identification of the longitududinal flight dynamics of the solar powered airship Lotte

Published online by Cambridge University Press:  04 July 2016

C. F. Eckersley
Affiliation:
Flight Test and Dynamics Group, College of Aeronautics, Cranfield University, Bedfordshire, UK
M. V. Cook
Affiliation:
Flight Test and Dynamics Group, College of Aeronautics, Cranfield University, Bedfordshire, UK

Abstract

This paper relates to a recent project in which the aim was to devise a procedure that could be used to identify the linearised transfer functions of the longitudinal motion of the solar powered airship Lotte from flight test data.

Using a non-linear mathematical model of the Airship, a linearised state space model was derived numerically and this was used to derive the response transfer functions, which formed the theoretical results. A test procedure was then developed to identify the transfer functions experimentally from frequency response data obtained in simulated flight tests. Initially, the linearised model was used and the test procedure was refined until a suitable level of coherence between the experimental and theoretical results was observed. The test procedure was then applied to simulated flight test data from the non-linear model, and finally sensor noise was added in order to represent actual flight test conditions as closely as possible. Unfortunately, the results were inaccurate and in some cases, they were unacceptable. When the test procedure was applied to the non-linear model, significant errors were seen in all the results. The addition of sensor noise led to heavily distorted results and a further degradation of the resulting transfer function estimates.

It was concluded that meaningful results could not be achieved unless frequency response data with a higher resolution could be obtained and the effects of sensor noise could be reduced. Presently, no test procedure has been developed that would be of any use in a practical situation. However, a number of ways of possibly improving the test procedure or otherwise improving the quality of the results were conceived near the end of the project. It is therefore the purpose of this paper to account for the shortcomings that were encountered in the project and to introduce briefly the unexplored remedies, in the hope that these may be of some benefit to future identification studies.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 2002 

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References

1. Eckersley, C.F. Linearised Modelling and Identification of the Longitudinal Flight Dynamics of the Solar Powered Airship Lotte, 1999, College of Aeronautics MSc thesis, Cranfield University.Google Scholar
2. Kindler, J.T. Lineare Identifizierung der Längsbewegung eines Luftschiffs (‘Linear identification of the longitudinal motion of an airship’), Studienarbeit, (‘Flight Mechanics and Control Institute under graduate project’), 1998, University of Stuttgart. (In German).Google Scholar
3. Jex, H.R., Hogue, J.R., Magdaleno, R.E., Gelhausen, P.A. and Tucker, G.E. Dynamic flight-tests of the Skyship-500 blimp, STI Technical Report TR-1151-4, preliminary, Systems Technology, Hawthrone, CA, 1984.Google Scholar
4. Unbehauen, H. Regelungstechnik HI (‘Control Engineering III’), 5th edition, 1995, Friedr. Vieweg & Sohn Verlagsgesellschaft mbH, Braunschweig/Wiesbaden, (In German).Google Scholar
5. Randall, R.B. Frequency Analysis, 3rd edition, 1987, Briiel & Kjasr, Nasrum, Denmark.Google Scholar
6. Adcock, J.L. Curve fitter for pole-zero analysis, Hewlett Packard J, January 1987, 38, (1), pp 3336.Google Scholar
7. Bendat, J.S. and Piersol, A.G. Engineering Applications of Correlation and Spectral Analysis, 1980, John Wiley & Sons, New York.Google Scholar