Title :
Robust Take-Off for a Quadrotor Vehicle
Author :
Cabecinhas, David ; Naldi, R. ; Marconi, L. ; Silvestre, Carlos ; Cunha, Rita
Author_Institution :
Lab. of Robot. & Syst. in Eng. & Sci. (LARSyS), Univ. Tec. de Lisboa, Lisbon, Portugal
fDate :
6/1/2012 12:00:00 AM
Abstract :
This paper addresses the problem of robust take-off of a quadrotor unmanned aerial vehicle (UAV) in critical scenarios, such as in the presence of sloped terrains and surrounding obstacles. Throughout the maneuver, the vehicle is modeled as a hybrid automaton whose states reflect the different dynamic behaviors exhibited by the UAV. The original take-off problem is then addressed as the problem of tracking suitable reference signals in order to achieve the desired transitions between different hybrid states of the automaton. Reference trajectories and feedback control laws are derived to explicitly account for uncertainties in both the environment and the vehicle dynamics. Simulation results demonstrate the effectiveness of the proposed solution and highlight the advantages with respect to more standard open-loop strategies, especially for cases in which the slope of the terrain renders the take-off maneuver more critical to achieve.
Keywords :
aircraft control; autonomous aerial vehicles; feedback; helicopters; mobile robots; open loop systems; robot dynamics; trajectory control; vehicle dynamics; UAV; autonomous unmanned aerial vehicles; dynamic behaviors; feedback control laws; flight control; hybrid automaton; open-loop strategies; quadrotor unmanned aerial vehicle; reference trajectories; robust take-off problem; sloped terrains; surrounding obstacles; take-off maneuver; vehicle dynamics; Automata; Force; Friction; Robustness; Trajectory; Vehicle dynamics; Vehicles; Aerial robotics; hybrid automaton; optimization; underactuated robots;
Journal_Title :
Robotics, IEEE Transactions on
DOI :
10.1109/TRO.2012.2187095
