The theory of the longitudinal static stability of the hang-glider

M. V. Cook

doi:10.1017/S0001924000026798

Abstract

This paper describes the development of a simple theory of the longitudinal static stability of the hang-glider. The classical theory, as developed for the conventional aeroplane, is modified to accommodate the particular features of the hang-glider. When the appropriate assumptions are made, the theory provides simple insight into the controls fixed and controls free stability and control characteristics of the hang-glider. The validity of the theoretical models is successfully demonstrated by application to a typical fifth generation hang-glider wing for which good quality aerodynamic data were available.

Information

References

1 Kilkenny, E.A. An experimental study of the longitudinal aerodynamic and static stability characteristics of hang-gliders. College of Aeronautics PhD thesis, Cranfield Institute of Technology, September 1986.Google Scholar

2 Cook, M.V. and Kilkenny, E.A. An experimental investigation of the aerodynamics of the hang-glider. In: Proceedings of an International Conference on Aerodynamics at low Reynolds numbers. Royal Aeronautical Society, London, October 1986.Google Scholar

3 Kilkenny, E.A. An evaluation of a mobile aerodynamic test facility for hang-glider wings. College of Aeronautics report No: 8330, Cranfield Institute of Technology, November 1983.Google Scholar

4 Kilkenny, E.A. Full scale wind tunnel tests on hang-glider pilots. College of Aeronautics report No: 8416, Cranfield Institute of Technology, April 1984.Google Scholar

5 Duncan, W.J. The Principles of the Control and Stability of Aircraft. Cambridge University Press, 1959. pp 137–142.Google Scholar

6 Blake, D.M. Modelling the aerodynamics, stability and control of the hang-glider. College of Aeronautics MSc thesis, Cranfield Institute of Technology, September 1991.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Gratton, G B 2001. The weightshift-controlled microlight aeroplane. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, Vol. 215, Issue. 3, p. 147.

D’Angelo, S. Fantetti, M. and Minisci, E. 2004. IUTAM Symposium on Evolutionary Methods in Mechanics. Vol. 117, Issue. , p. 47.

Cook, M. V. and Spottiswoode, M. 2005. Modelling the flight dynamics of the hang glider. The Aeronautical Journal, Vol. 109, Issue. 1102, p. I.

Cook, M. V. and Spottiswoode, M. 2006. Modelling the flight dynamics of the hang glider. The Aeronautical Journal, Vol. 110, Issue. 1103, p. 1.

Carrera, E. and Cosatto, C. 2010. Flight Mechanics Analysis of a Motorized Trike with Composite Wing. Journal of Aerospace Engineering, Vol. 23, Issue. 4, p. 251.

Metzger, S. Junkermann, W. Butterbach-Bahl, K. Schmid, H. P. and Foken, T. 2011. Measuring the 3-D wind vector with a weight-shift microlight aircraft. Atmospheric Measurement Techniques, Vol. 4, Issue. 7, p. 1421.

Cook, Michael V. 2013. Flight Dynamics Principles. p. 33.

Ochi, Yoshimasa 2015. Modeling of the Longitudinal Dynamics of a Hang Glider.

Abouheaf, Mohammed Gueaieb, Wail and Lewis, Frank 2018. Model-Free Gradient-Based Adaptive Learning Controller for an Unmanned Flexible Wing Aircraft. Robotics, Vol. 7, Issue. 4, p. 66.

Abouheaf, Mohammed Mailhot, Nathaniel and Gueaieb, Wail 2019. An Online Reinforcement Learning Wing-Tracking Mechanism for Flexible Wing Aircraft. p. 1.

Abouheaf, Mohammed and Gueaieb, Wail 2019. Model-Free Adaptive Control Approach Using Integral Reinforcement Learning. p. 1.

Abouheaf, Mohammed Gueaieb, Wail and Lewis, Frank 2020. Online model‐free reinforcement learning for the automatic control of a flexible wing aircraft. IET Control Theory & Applications, Vol. 14, Issue. 1, p. 73.

Abouheaf, Mohammed and Gueaieb, Wail 2020. Online model-free controller for flexible wing aircraft: a policy iteration-based reinforcement learning approach. International Journal of Intelligent Robotics and Applications, Vol. 4, Issue. 1, p. 21.

Abouheaf, Mohammed Mailhot, Nathaniel Q. Gueaieb, Wail and Spinello, Davide 2020. Guidance Mechanism for Flexible-Wing Aircraft Using Measurement-Interfaced Machine-Learning Platform. IEEE Transactions on Instrumentation and Measurement, Vol. 69, Issue. 7, p. 4637.

Chinvorarat, Sinchai Watjatrakul, Boonchai Nimdum, Pongsak Sangpet, Teerawat Soontornpasatch, Tosaporn and Vallikul, Pumyos 2020. Six-Degree of Freedom Mathematical Dynamic Model of a Light-Sport Aircraft. IOP Conference Series: Materials Science and Engineering, Vol. 886, Issue. 1, p. 012011.

Chinvorarat, Sinchai Watjatrakul, Boonchai Nimdum, Pongsak Sangpet, Teerawat and Vallikul, Pumyos 2021. Takeoff Performance Analysis of a Light Amphibious Airplane. IOP Conference Series: Materials Science and Engineering, Vol. 1137, Issue. 1, p. 012010.

Mailhot, Nathaniel de Jesus Krings, Teresa Navajas, Gilmar Tuta Zhou, Boyan and Spinello, Davide 2023. uWSC Aircraft Simulator: A Gazebo-based model for uncrewed weight-shift control aircraft flight simulation. p. 1.

Mailhot, Nathaniel Abouheaf, Mohammed and Spinello, Davide 2024. Model-Free Force Control of Cable-Driven Parallel Manipulators for Weight-Shift Aircraft Actuation. IEEE Transactions on Instrumentation and Measurement, Vol. 73, Issue. , p. 1.

Article contents

The theory of the longitudinal static stability of the hang-glider

Abstract

Information

Access options

Article purchase

Temporarily unavailable

References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

The theory of the longitudinal static stability of the hang-glider

Abstract

Information

Access options

Article purchase

Temporarily unavailable

References

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests