• DocumentCode
    728446
  • Title

    Fast, safe and precise landing of a quadrotor on an oscillating platform

  • Author

    Botao Hu ; Lu Lu ; Mishra, Sandipan

  • Author_Institution
    Dept. of Mech., Aerosp. & Nucl. Eng., Rensselaer Polytech. Inst., Troy, NY, USA
  • fYear
    2015
  • fDate
    1-3 July 2015
  • Firstpage
    3836
  • Lastpage
    3841
  • Abstract
    In this paper, we propose a novel control structure that can achieve fast, safe and precise landing of a VTOL (vertical takeoff and landing) UAV onto a vertically oscillating landing pad. The control structure consists of three modules to achieve these goals: a motion estimation module, a trajectory generation module and a tracking control module. In the tracking control module, an ARC (Adaptive Robust Controller) is designed to robustly adapt the nonlinear ground effect to enable a quadrotor accurately track a given reference trajectory. In the trajectory generation module, a time-optimal reference trajectory for the quadrotor is generated such that it converges from the initial height precisely to the platform height with zero relative velocity (for smooth landing). The landing time duration is as short as possible, and physical safety constraints (position, velocity, acceleration bounds etc.) are satisfied during the entire landing process. The above two modules use the motion information of the quadrotor and the platform in absolute coordinate system (inertial frame). In the motion estimation module, we estimate the UAV and platform positions online from only the measurement of the relative distance between the UAV and the platform, as well as the inertia measurement of the UAV. An UKF (unscented Kalman Filter) is constructed and the estimated parameters are fed to the other two modules in real time. Comparative simulation and experimental results are presented to validate the performances of the proposed control structure.
  • Keywords
    Kalman filters; adaptive control; aircraft control; autonomous aerial vehicles; control system synthesis; helicopters; mobile robots; motion control; nonlinear control systems; nonlinear filters; oscillations; parameter estimation; robust control; trajectory control; ARC design; UAV; UKF; VTOL; adaptive robust controller design; motion estimation module; nonlinear ground effect; parameter estimation; platform oscillation; platform position; quadrotor landing; time-optimal reference trajectory tracking; tracking control module; unmanned aerial vehicle; unscented Kalman filter; vertical takeoff and landing; Acceleration; Estimation; Motion estimation; Robustness; Tracking; Trajectory;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    American Control Conference (ACC), 2015
  • Conference_Location
    Chicago, IL
  • Print_ISBN
    978-1-4799-8685-9
  • Type

    conf

  • DOI
    10.1109/ACC.2015.7171928
  • Filename
    7171928