Identification and Modeling of the Airbrake of an Experimental Unmanned Aircraft

This paper presents the modeling, system identification, simulation and flight testing of the airbrake of an unmanned experimental aircraft in frame of the FLEXOP H2020 EU project. As the aircraft is equipped with a jet engine with slow response an airbrake is required to increase deceleration after...

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Bibliographic Details
Published in:Journal of intelligent & robotic systems 2020-10, Vol.100 (1), p.259-287
Main Authors: Bauer, Peter, Anastasopoulos, Lysandros, Sendner, Franz-Michael, Hornung, Mirko, Vanek, Balint
Format: Article
Language:English
Subjects:
Actuators
Aircraft
Aircraft control
Aircraft design
Airspace
Airspeed
Analysis
Angular velocity
Artificial Intelligence
Computer simulation
Control
Control equipment
Control surfaces
Deceleration
Drag
Drone aircraft
Dynamic loads
Dynamic models
Dynamic pressure
Electrical Engineering
Engineering
Flight tests
Flutter
Identification
Jet engines
Jet planes
Mechanical Engineering
Mechanical properties
Mechatronics
Nonlinearity
Robotics
Seats
Servomechanisms
Servomotors
Simulation
Simulation methods
Stiffness
System identification
Trajectory control
Transfer functions
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Summary:This paper presents the modeling, system identification, simulation and flight testing of the airbrake of an unmanned experimental aircraft in frame of the FLEXOP H2020 EU project. As the aircraft is equipped with a jet engine with slow response an airbrake is required to increase deceleration after speeding up the aircraft for flutter testing in order to remain inside the limited airspace granted by authorities for flight testing. The airbrake consists of a servo motor, an opening mechanism and the airbrake control surface itself. After briefly introducing the demonstrator aircraft, the airbrake design and the experimental test benches the article gives in depth description of the modeling and system identification referencing also previous work. System identification consists of the determination of the highly nonlinear (saturated and load dependent) servo actuator dynamics and the nonlinear aerodynamic and mechanical characteristics including stiffness and inertia effects. New contributions relative to the previous work are a unified servo angular velocity limit model considering opening against the load or closing with it, the detailed construction and evaluation of airbrake normal and drag force models considering the whole deflection and aircraft airspeed range, the presentation of a unified aerodynamic - mechanic nonlinearity model giving direct relation between airbrake angle, dynamic pressure and servo torque and the transfer function-based modeling of stiffness and inertial effects in the mechanism. The identified servo dynamical model includes system delay, inner saturation, the aforementioned load dependent angular velocity limit model and a transfer function model. The servo model was verified based-on test bench measurements considering the whole opening angle and dynamic load range of the airbrake. New, unpublished measurements with gradually increasing servo load as the servo moves are also considered to verify the model in more realistic circumstances. Then the full airbrake model is constructed and tested in simulation to check realistic behavior. In the next step the airbrake model integrated into the nonlinear simulation model of the FLEXOP aircraft is tested by flying simulated test trajectories with the baseline controller of the aircraft in software-in-the-loop (SIL) Matlab simulation. First, the standalone airbrake simulation is compared to the SIL results to verify flawless integration of airbrake model into the nonlinear aircraft
ISSN:0921-0296
1573-0409
DOI:10.1007/s10846-020-01204-1