dc.description.abstract | Multirotor Unmanned Aerial Vehicles (UAVs) high maneuverability and their capability
to hover, makes them an extensively used platform in many fields of applications.
However, their limitations in flight time challenge the ambition of using multirotor
UAVs in fully autonomous operations. By introducing ground or maritime vehicles for
deployment and recovery of the UAVs, or even serve as a service platform performing
automatic battery replacement, it is possible to perform autonomous operations with
multirotor UAVs beyond todays limitations in regards range and duration. To achieve a
seamless synergy between the UAVs and the vehicle including a landing pad, requires
the UAV to be able to perform autonomous landing on the landing pad wile it is in
motion.
This thesis addresses autonomous landing of a multirotor UAV on a vehicle in
motion by using traditional navigation sensors in combination with a camera based
measurement system. The camera based measurements and the traditional navigation
measurements are processed in a Kalman filter developed in this assignment which
performs sensor fusion, estimates navigation states as well as calculating the sensor
biases. Moreover, two different guidance methods are compared, and a state machine
generating flight paths and adjusting controller gains are developed.
The camera based measurement system, the state estimator and the controller
are all implemented on the UAV and physical tests have been conducted in real time.
Results from the test show that the UAV is, in a robust manner, able to locate, track and
precisely land on a static landing pad. Unfortunately, there was no time to conduct final tests on landing pad in motion. However, results from simulations and the state
estimator indicates that the system is able to carry out autonomous landing on a
landing pads in motion. | |