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The Anti-Symmetric Vibrations of Aircraft

Published online by Cambridge University Press:  07 June 2016

R. W. Traill-Nash
R. W. Traill-Nash*
Affiliation:
Department of Supply and Development, Aeronautical Research Laboratories, Melbourne
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Summary

It is assumed that pure anti-symmetric vibrations of an aircraft can exist, involving fuselage torsion but excluding fuselage bending. With this assumption, which in most cases is a reasonable approximation, the eigenvalue equations for anti-symmetric vibrations of a complete aircraft are derived in a very general form. The “lumped mass” approximation to the continuous mass distribution is used and sub-matrices are associated with properties of relatively simple branches of the system. The final eigenvalue equations are expressed in terms of these sub-matrices so that in a numerical application the physical system as such is considered only in relation to properties of the simple branches. It is assumed initially that the aircraft wing and tail have flexural axes of the conventional type, but the treatment is generalised to cover swept and cranked wing aircraft.

Type
Research Article
Information
Aeronautical Quarterly , Volume 3 , Issue 2 , September 1951 , pp. 145 - 160
Copyright
Copyright © Royal Aeronautical Society. 1951

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References

1. Traill-Nash, R. W. (1951). The Symmetric Vibrations of Aircraft. The Aeronautical Quarterly, Vol. III, May 1951.Google Scholar
2. Frazer, R. A., Duncan, W. J. and Collar, A. R. (1946). Elementary Matrices, Cambridge University Press, 1946.Google Scholar
3. Morris, J. and Morrison, D. (1945). The Rolling Vibrations of an Aircraft, R.A.E. Report No. Vib. 8, August 1945.Google Scholar
4. Duncan, W. J. and Collar, A. R.(1934). A Method for the Solution of Oscillation Problems by Matrices. Phil. Mag. S7, Vol. 17, No. 115, May 1934, p. 865.Google Scholar
5. Morris, J. and Head, J. W. (1944). The “Escalator” Process for the Solution of Lagrangian Frequency Equations. Phil. Mag. S7, Vol. 35, No. 350, Nov., 1944, p. 735.Google Scholar