Modeling the unstable DelftaCopter vertical take-off and landing tailsitter unmanned air vehicle in hover and forward flight from flight test data

The DelftaCopter is a tilt-body tailsitter unmanned air vehicle which combines a large swashplate controlled helicopter rotor with a biplane delta-wing. Previous research has shown that the large moment of inertia of the wing and fuselage significantly interacts with the dynamics of the rotor. While this rigid rotor cylinder dynamics model has allowed initial flight testing, part of the dynamics remains unexplained. In particular, higher frequency dynamics and the forward flight dynamics were not modeled. In this work, the cylinder dynamics model is compared with the tip-path plane model, which includes the steady-state flapping dynamics of the blades. The model is then extended to include the wing and elevon dynamics during forward flight. Flight test data consisting of excitations with a large frequency content are used to identify the model parameters using grey-box modeling. Since the DelftaCopter is unstable, flight tests can only be performed while at least a rate feedback controller is active. To reduce the influence of this active controller on the identification of the dynamics, one axis is identified at a time while white noise is introduced on all other axes. The tip-path plane model is shown to be much more accurate in reproducing the high-frequency attitude dynamics of the DelftaCopter. The significant rotor–wing interaction is shown to differ greatly from what is seen in traditional helicopter models. Finally, an Linear-Quadratic Regulator (LQR) controller based on the tip-path plane model is derived and tested to validate its applicability. Modeling the attitude dynamics of the unstable DelftaCopter from flight test data has been shown to be possible even in the presence of the unavoidable baseline controller.

[1]  Kimon P. Valavanis,et al.  Advances in Unmanned Aerial Vehicles: State of the Art and the Road to Autonomy , 2007 .

[2]  Jean-Marc Moschetta,et al.  Development of a VTOL mini UAV for multi-tasking missions , 2009 .

[3]  Jean-Marc Moschetta,et al.  Development of the flight model of a tilt-body MAV , 2014 .

[4]  Christophe De Wagter,et al.  Control of a hybrid helicopter with wings , 2017 .

[5]  Mirko Hornung,et al.  Conceptual design studies of vertical takeoff and landing remotely piloted aircraft systems for hybrid missions , 2016 .

[6]  Kevin van Hecke,et al.  Design, Control and Visual Navigation of the DelftaCopter , 2017, ArXiv.

[7]  Atsushi Konno,et al.  Development of a quad rotor tail-sitter VTOL UAV without control surfaces and experimental verification , 2013, 2013 IEEE International Conference on Robotics and Automation.

[8]  Shai A. Arogeti,et al.  Flight transition control of a multipurpose UAV , 2017, 2017 13th IEEE International Conference on Control & Automation (ICCA).

[9]  Mark B. Tischler,et al.  Aircraft and Rotorcraft System Identification: Engineering Methods with Flight-Test Examples , 2006 .

[10]  Austin Murch,et al.  System Identification for Small, Low-Cost, Fixed-Wing Unmanned Aircraft , 2013 .

[11]  A.R.S. Bramwell,et al.  Bramwell's Helicopter Dynamics , 2001 .

[12]  Murat Bronz,et al.  Using the Paparazzi UAV System for Scientific Research , 2014 .

[13]  Joris De Schutter,et al.  Design and Control of an Unmanned Aerial Vehicle for Autonomous Parcel Delivery with Transition from Vertical Take-off to Forward Flight – VertiKUL, a Quadcopter Tailsitter , 2015 .

[14]  Eric N. Johnson,et al.  Practical System Identification for Small VTOL Unmanned Aerial Vehicle , 2019 .

[15]  Manuel Béjar,et al.  A Survey on Methods for Elaborated Modeling of the Mechanics of a Small-Size Helicopter. Analysis and Comparison , 2013, J. Intell. Robotic Syst..

[16]  Ahmad Bani Younes,et al.  A survey of hybrid Unmanned Aerial Vehicles , 2018 .

[17]  Bernard Mettler,et al.  Identification Modeling and Characteristics of Miniature Rotorcraft , 2002 .

[18]  Joseph F. Horn,et al.  Aircraft and Rotorcraft System Identification: Engineering Methods with Flight Test Examples, Second Edition [Bookshelf] , 2016, IEEE Control Systems.

[19]  Brendan Williams,et al.  How the Outback Challenge Was Won: The Motivation for the UAV Challenge Outback Rescue, the Competition Mission, and a Summary of the Six Events , 2016, IEEE Robotics & Automation Magazine.

[20]  Konstantin Kondak,et al.  Autonomously Flying VTOL-Robots: Modeling and Control , 2007, Proceedings 2007 IEEE International Conference on Robotics and Automation.

[21]  G. C. H. E. de Croon,et al.  Modelling of a Hybrid UAV Using Test Flight Data , 2014 .

[22]  Hector Garcia de Marina,et al.  Development of A Fixed-Wing mini UAV with Transitioning Flight Capability , 2017 .

[23]  Eric Feron,et al.  Scaling effects and dynamic characteristics of miniature rotorcraft , 2004 .

[24]  Subodh Bhandari,et al.  Six-DoF Dynamic Modeling and Flight Testing of a UAV Helicopter , 2005 .

[25]  Rogelio Lozano,et al.  Attitude stabilization in hover flight of a mini tail-sitter UAV with variable pitch propeller , 2007, 2007 IEEE/RSJ International Conference on Intelligent Robots and Systems.