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fbtwitterlinkedinvimeoflicker grey 14rssslideshare1
Hopper, DJF
Languages: English
Types: Doctoral thesis
Subjects: other
Vertical/Short Take-Off arid Landing (V/STOL) fighter aircraft are\ud characterised by increased control complexity caused by the extra degree\ud ol freedom. This can result in a high pilot workload which may be\ud alleviated with the careful application of active flight control.\ud However, the advent of control configured vehicles demands that the\ud controller design must be part of a fully integrated and iterative\ud aircraft design; hence it must allow the two-way flow of design\ud information.\ud In this thesis a suitable controller (leSign method is developed to solve\ud this two-fold problem.\ud The method is based upon a singular perturbation analysis which is used\ud to expose the underlying dynamics of a closed-loop state-space system.\ud developments are described which allow high-order, dynamically\ud complex parasitics, such as actuators, to be included in the design.\ud }urtherrnore, the method gives the designer insight into the problem\ud allowing tuning and engineering trade-offs to be performed intelligently\ud with a two-way flow of design information. The end result is a robust\ud high-gain multivariable controller.\ud In order fully to develop arid analyse the method it has been applied to\ud a representative non-linear time-varying aircraft simulation model. This\ud LS supplied by the Royal Aerospace Establishment, Bedford. The necessary slate-space matrices are otitairted by lirLearisirig the model at several\ud differertt flight cases. This occurs over a wide flight envelope, from\ud hover to 300 Kts, and consequently the multivariable control laws are\ud implemented using gain scheduling.\ud Finally, task tailored control and handling qualities requirements are\ud derived for a V/STOL aircraft in the form of a design brief. This design\ud brief is then fulfilled by designing a controller which alleviates pilot\ud workload during transitions from jet-borne to fully wing-borne flight\ud (and vice versa).
  • The results below are discovered through our pilot algorithms. Let us know how we are doing!

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