Modeling of an airborne wind energy system with a flexible tether model for the optimization of landing trajectories * *Support by the EU via ERC-HIGHWIND (259 166), ITN-TEMPO (607 957), and ITN-AWESCO (642 682) and by DFG in context of the Research Unit FOR 2401.

Jonas Koenemann,Moritz Diehl,Paul Williams,Soeren Sieberling

doi:10.1016/j.ifacol.2017.08.1037

Modeling of an airborne wind energy system with a flexible tether model for the optimization of landing trajectories * *Support by the EU via ERC-HIGHWIND (259 166), ITN-TEMPO (607 957), and ITN-AWESCO (642 682) and by DFG in context of the Research Unit FOR 2401.

Jonas Koenemann, Moritz Diehl + Show 2 more

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https://doi.org/10.1016/j.ifacol.2017.08.1037

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Journal: IFAC-PapersOnLine	Publication Date: Jul 1, 2017
Citations: 11

Affiliation: University of Freiburg

#Airborne Wind Energy #Autonomous Takeoff + Show 8 more

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Abstract

Abstract Autonomous takeoff and landing is a big challenge in the field of airborne wind energy. We propose numerical methods in order to optimize flight trajectories of a tethered aircraft. These flight trajectories yield a baseline for analyzing takeoff or landing performance. In this paper, we optimize for a landing strategy that uses the winch to decelerate the aircraft after touchdown. A complete optimal control formulation with differential algebraic equations for the system dynamics is derived. For avoiding tether collision with the ground, we employ a quasi-static tether model that treats both the tether sag and elasticity. It is a novelty in airborne wind energy trajectory optimization to solve for the tether shape as part of the optimization problem.

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