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Active control technology

Published online by Cambridge University Press:  04 July 2016

A. Simpson  and
H. P. Y. Hitch
A. Simpson
Affiliation:
University of Bristol
H. P. Y. Hitch
Affiliation:
British Aircraft Corporation, Commercial Air Division, Weybridge, Surrey
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Extract

Active Control Technology (ACT) is not a new subject; it has been utilised in engineering circles for over a century in various guises, the first application of any significance being the steam engine governor. The history of the subject is accordingly long and is well referenced, and we shall depart from the time-honoured rigmarole of providing a detailed survey of early developments by directing our audience instead to Ref. 1 where such a survey may be found. In similar mildly unconventional vein, we note that this platform, and many others like it in this country and elsewhere, has been used many times by eminent individuals to expound their own idiosyncratic views as to how ACT should be defined in its constituent functions and how, in turn, these might possibly be applied without much in the way of reference to what has been done or to the many practical limitations. While our own views presented here will also be idiosyncratic, we shall attempt to relate what we say to that which has been achieved in actual applications and, based on these achievements, to what might follow in the foreseeable future.

Type
Research Article
Information
The Aeronautical Journal , Volume 81 , Issue 798 , June 1977 , pp. 231 - 246
Copyright
Copyright © Royal Aeronautical Society 1977 

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References

1. Mcruer, D. and Graham, D. A historical perspective for advances in flight control systems. AGARD Proc. No. 137 Advances in Control Systems.Google Scholar
2. Jones, J. G. Statistical discrete gust theory for aircraft loads—a progress report. RAE TR 73167, November 1973.Google Scholar
3. Simons, I. Advanced control systems for helicopters. 1976, Vertica, Vol I, pp 1729.Google Scholar
4. Attlfellner, S. BO 105 in-flight simulator for flight control and guidance systems. 1976. Paper 30. Symposium on Helicopters, Univ of Southampton.Google Scholar
5. Bangen, H.-J., Hoffman, W., Seelmann, H. and Leyendecker, H. Investigation of a helicopter manoeuvre demand system. 1976. Paper 28. Second European Rotor- craft and Powered Lift Aircraft Forum. Bückeburg, Federal Republic of Germany.Google Scholar
6. Hoffman, L. G. and Clement, W. F. Vehicle design considerations for active control application to subsonic transport aircraft. NASA CR-2408, August 1974.Google Scholar
7. Grosser, W. F., Hollenbeck, W. W. and Eckholdt, D. C. The C-5A active lift distribution control system. Paper 24. AGARD CP-157, October 1974.Google Scholar
8. Cohen, G. C. and Schoenman, R. L. Use of ACT to improve ride qualities of a large transport aircraft. Paper 23. AGARD CP-157, October 1974.Google Scholar
9. Kujawski, Maj. B. T. CCV’S B-52 programme results, Paper 14. AGARD CP-157. October 1974.Google Scholar
10. Frazzini, R. and Vaughn, D. Analysis and preliminary design of an advanced technology transport flying control system. NASA CR-2490, March 1975.Google Scholar
11. Stumpfl, S. C. and Whitmoyer, R. A. Horizontal can ards for two-axis CCV fighter control. Paper 6. AGARD CP-157. October 1974.Google Scholar
12. Krachmalnick, F. M., Berger, R. L., Hunter, J. E., Morris, J. W. and Ramage, J. K. Survivable flight control system active control development, flight test and application. Paper 12. AGARD CP-157. October 1974.Google Scholar
13. Smith, H. and Carleton, D. Weapon delivery impact on ACT. Paper 13. AGARD CP-157. October 1974.Google Scholar
14. Seacord, C L. and Vaughn, D. Preliminary system design study for a digital fly-by-wire flight control system for an F-8C aircraft. NASA CR-2609. January 1976.Google Scholar
15. Hartmann, G. L., Hauge, J. A. and Hendrick, R. C. F-8C digital CCV flight control laws. NASA CR-2629. February 1976.Google Scholar
16. Plumer, J. A., Fisher, F. A. and Walko, L. K. Light ning effects on a NASA F-8 digital fly-by-wire airplane. NASA CR-2524. March 1975.Google Scholar
17. Perisho, C H., Triplett, W. E. and Mykytow, W. J. Design considerations for an active suppression system for fighter wing/store flutter. AGARD CP-175. April 1975.Google Scholar
18. Thompson, G. O. and Sevart, F. D. Wind tunnel investigation of control configured vehicle systems. Paper 4. AGARD CP-175. April 1975.Google Scholar
19. Flannigan, J. B. and Elliott, T. R. Mechanization of active control systems. Paper 7. AGARD CP-175. April 1975.Google Scholar
20. Wiggins, D. A. Hydraulic controls for active flutter suppression and load alleviation. Paper 8. AGARD CP-175. April 1975.Google Scholar
21. Hutto, A. J. Flight test report on the heavy lift helicopter flight control system. American Helicopter Society. May 1975.Google Scholar
22. Liu, D. T. In flight stabilization of externally slung helicopter loads. USAA Contract No. DAAJO2-70-C-0067. Final Report, May 1975.Google Scholar
23. Chan, D., Flower, J. W. and Simpson, A. Aerodynamically induced motions of bluff bodies suspended beneath helicopters. USAA Contract No. DAJA 37-73-C-0477. Final Report, October 1975.Google Scholar
24. Kaufman, H., Alag, G., Berry, P. and Kotob, S. Digital adaptive flight controller development. NASA CR-2466. December 1974.Google Scholar
25. Kaufman, H. Research in digital adaptive flight controllers. NASA CR-2684. May 1976.Google Scholar
26. Roesch, P. and Harlan, R. B. A passive gust alleviation system for a light aircraft. NASA CR-2605. October 1975.Google Scholar
27. Anderson, N. R. Flying the YF-16. Aerospace, pp 1419. March 1976.Google Scholar
28. Cleveland, F. A. Challenge to advance technology transport aircraft systems. Journal of Aircraft, Vol 13 (10), pp 737744. October 1976.Google Scholar
29. Nissim, E. Flutter suppression using active controls based on the concept of aerodynamic energy. NASA TN D-6199. March 1971.Google Scholar
30. Turner, M. R. Active flutter suppression. Paper 2. AGARD CP-175. April 1975.Google Scholar
31. Dressler, W. Control of an elastic aircraft using optimal control laws. Paper 9. AGARD CP-157. October 1974.Google Scholar
32. Haidl, G., Lotze, A. and Sensburg, O. Active flutter suppression on wings with external stores. MBB Tech Note (unpublished).Google Scholar
33. Kaynes, I. W. Mathematical representation of turbulence for ACT. Institute of Meas. & Control Conf. on ACT, Queen Mary College, London. 20th July 1976.Google Scholar
34. Klug, H. G. Transport aircraft with relaxed/negative longitudinal stability—results of a design study. Paper 4. AGARD CP-157. October 1974.Google Scholar
35. Sensburg, O., Hönlinger, H. and Kühn, M. Active control of empennage flutter. Paper 3. AGARD CP-175. April 1975.Google Scholar