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Maximum survival capability of an aircraft in a severe windshear (1987)

Miele, A. ; Wang, T. ; Melvin, W. W. ; [et al.]

Springer

Journal of optimization theory and applications 53 (1987), S. 181-217

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ISSN: 1573-2878

Keywords: Flight mechanics ; take-off ; windshear problems ; optimal trajectories ; guidance strategies ; piloting techniques ; feedback control ; gamma guidance ; simplified gamma guidance ; quick transition to horizontal flight

Source: Springer Online Journal Archives 1860-2000

Topics: Mathematics

Notes: Abstract This paper is concerned with guidance strategies and piloting techniques which ensure near-optimum performance and maximum survival capability in a severe windshear. The take-off problem is considered with reference to flight in a vertical plane. In addition to the horizontal shear, the presence of a downdraft is assumed. First, six particular guidance schemes are considered, namely: constant alpha guidance; maximum alpha guidance; constant velocity guidance; constant absolute path inclination guidance; constant rate of climb guidance; and constant pitch guidance. Among these, it is concluded that the best one is the constant pitch guidance. Next, in an effort to improve over the constant pitch guidance, three additional trajectories are considered: the optimal trajectory, which minimizes the maximum deviation of the absolute path inclination from a reference value, while employing global information on the wind flow field; the gamma guidance trajectory, which is based on the absolute path inclination and which approximates the behavior of the optimal trajectory, while employing local information on the windshear and the downdraft; and the simplified gamma guidance trajectory, which is the limiting case of the gamma guidance trajectory in a severe windshear and which does not require precise information on the windshear and the downdraft. The essence of the simplified gamma guidance trajectory is that it yields a quick transition to horizontal flight. Comparative numerical experiments show that the survival capability of the simplified gamma guidance trajectory is superior to that of the constant pitch trajectory and is close to that of the optimal trajectory. Next, with reference to the simplified gamma guidance trajectory, the effect of the feedback gain coefficient is studied. It is shown that larger values of the gain coefficient improve the survival capability in a severe windshear; however, excessive values of the gain coefficient are undesirable, because they result in larger altitude oscillations and lower average altitude. Finally, with reference to the simplified gamma guidance trajectory, the effect of time delays is studied, more specifically, the time delay τ1 in reacting to windshear onset and the time delay τ2 in reacting to windshear termination. While time delay τ2 has little effect on survival capability, time delay τ1 appears to be critical in the following sense: smaller values of τ1 correspond to better survival capability in a severe windshear, while larger values of τ1 are associated with a worsening of the survival capability in a severe windshear.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00939214

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Quasi-steady flight to quasi-steady flight transition in a windshear: Trajectory optimization and guidance (1987)

Miele, A. ; Wang, T. ; Melvin, W. W.

Springer

Journal of optimization theory and applications 54 (1987), S. 203-240

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ISSN: 1573-2878

Keywords: Flight mechanics ; take-off ; quasi-steady flight to quasisteady flight transition ; optimal trajectories ; optimal control ; guidance strategies ; feedback control ; windshear problems ; sequential gradient-restoration algorithm ; dual sequential gradient-restoration algorithm

Source: Springer Online Journal Archives 1860-2000

Topics: Mathematics

Notes: Abstract This paper is concerned with the near-optimum guidance of an aircraft from quasi-steady flight to quasi-steady flight in a windshear. The take-off problem is considered with reference to flight in a vertical plane. In addition to the horizontal shear, the presence of a downdraft is considered. It is assumed that the power setting is held at the maximum value and that the aircraft is controlled through the angle of attack. Inequality constraints are imposed on both the angle of attack and its time derivative. First, trajectory optimization is considered. The optimal transition problem is formulated as a Chebyshev problem of optimal control: the performance index being minimized is the peak value of the modulus of the difference between the absolute path inclination and a reference value, assumed constant. Two types of optimal trajectories are studied: type 1 is concerned with gamma recovery (recovery of the initial value of the relative path inclination); and type 2 is concerned with quasisteady flight recovery (recovery of the initial values of the relative velocity, the relative path inclination, and the relative angle of attack). The numerical results show that the type 1 trajectory and the type 2 trajectory are nearly the same in the shear portion, while they diverge to a considerable degree in the aftershear portion of the optimal trajectory. Next, trajectory guidance is considered. A guidance scheme is developed so as to achieve near-optimum quasi-steady flight recovery in a windshear. The guidance scheme for quasi-steady flight recovery includes three parts in sequence. The first part refers to the shear portion of the trajectory and is based on the result that this portion of the trajectory depends only mildly on the boundary conditions; therefore, any of the guidance schemes already developed for type 1 trajectories can be employed (for instance, variable gamma guidance). The second part (constant gamma guidance) refers to the initial aftershear portion of the trajectory and is designed to achieve almost velocity recovery. The third part (constant rate of climb guidance) refers to the final aftershear portion of the trajectory and is designed to achieve almost complete restoration of the initial quasi-steady state. While the shear guidance and the initial aftershear guidance employ constant gain coefficients, the final aftershear guidance employs a variable gain coefficient. This is done in order to obtain accuracy and prompt response, while avoiding oscillations and overshoots. The numerical results show that the guidance scheme for quasi-steady flight recovery yields a transition from quasi-steady flight to quasi-steady flight which is close to that of the optimal trajectory, ensures the restoration of the initial quasi-steady state, and has good stability properties.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00939432

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