DocumentCode
2437924
Title
Fully automatic taxiing, takeoff and landing of a UAV using a single-antenna GPS receiver only
Author
Cho, Am ; Kim, Jihoon ; Lee, Sanghyo ; Choi, Sujin ; Lee, Boram ; Kim, Bosung ; Park, Noha ; Kim, Dongkeon ; Kee, Changdon
Author_Institution
Seoul Nat. Univ., Seoul
fYear
2007
fDate
17-20 Oct. 2007
Firstpage
821
Lastpage
825
Abstract
This paper presents automatic taxiing, takeoff and landing of a UAV based on a single-antenna GPS receiver. In this paper, inertial sensors such as gyros and accelerometers are not used at all to show the full potential of a single-antenna GPS receiver based attitude determination system. DGPS is implemented to give high accuracy position information for automatic taxiing, landing and takeoff on the runway. For a fixed wing aircraft, under the assumption of coordinated flight, the attitude information called as pseudo-attitudes can be estimated from the measurements of a single-antenna GPS receiver. So full state variables for the automatic control can be obtained from single-antenna GPS receiver. In addition to GPS receiver, only an airspeed sensor is added because the velocity relative to the air is very important during landing and takeoff. The forward velocity is replaced with the airspeed obtained from Pitot tube. From linearized equations of motions around the steady state, LQR controllers for takeoff and landing are built, m particular, the flare controller that controls the pitch, altitude and airspeed of a UAV is designed. During flight tests, the aircraft taxies and takes off the runway, follows the predefined waypoint path, and then lands on the runway along the curved approach path, all fully automatically. Based on flight test results, a single-antenna GPS receiver can be used as a main sensor for a backup or a low-cost control system of UAVs.
Keywords
Global Positioning System; aircraft landing guidance; attitude control; motion control; receiving antennas; remotely operated vehicles; aircraft taxies; airspeed sensor; attitude determination system; linearized motion equation; single-antenna differential GPS receiver; unmanned aerial vehicle landing; unmanned aerial vehicle takeoff; Accelerometers; Aircraft; Automatic control; Coordinate measuring machines; Equations; Global Positioning System; Motion control; Position measurement; Sensor systems; Unmanned aerial vehicles; Single-antenna GPS receiver; UAV; automatic landing; automatic takeoff; automatic taxiing;
fLanguage
English
Publisher
ieee
Conference_Titel
Control, Automation and Systems, 2007. ICCAS '07. International Conference on
Conference_Location
Seoul
Print_ISBN
978-89-950038-6-2
Electronic_ISBN
978-89-950038-6-2
Type
conf
DOI
10.1109/ICCAS.2007.4407014
Filename
4407014
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