This study presents a bi-level framework designed
for the optimal control (OC) of aircraft.
Overall, the goal is to calculate trajectories for
the aircraft under external and internal uncertainties
that give a worst-case approximation of the
uncertainty interval.
The bi-level OC framework is set up as follows:
Within the lower level, standard deterministic
trajectory optimization problems by gradientbased
optimization are solved. The solved
problems only differ in their numerical values set
for the uncertain parameters. It should be noted
that this makes it easy to parallelize them, as they
are independent of each other. The calculation of
the uncertain response of the system is based on
the generalized polynomial chaos (gPC) method.
The upper level problem provides the numerical
values of the uncertain parameters and is
optimized using a differential evolution (DE)
strategy. Thus, the connection from the upper
to the lower level are the numerical values of
the uncertain parameters. Conversely, the lower
level provides the upper level with the optimized
trajectory at each of the uncertain parameter's
positions yielding the statistical moments.
We use case studies from a vertical take-off and
landing vehicle (VTOL) transition maneuvers to
show the viability of the approach.
«
This study presents a bi-level framework designed
for the optimal control (OC) of aircraft.
Overall, the goal is to calculate trajectories for
the aircraft under external and internal uncertainties
that give a worst-case approximation of the
uncertainty interval.
The bi-level OC framework is set up as follows:
Within the lower level, standard deterministic
trajectory optimization problems by gradientbased
optimization are solved. The solved
problems only differ in t...
»
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