Flight code convergence: fixedwing, rotorcraft, hybrid

D.C. van Wijngaarden; E.J.J. Smeur; B.D.W. Remes

Flight code convergence: fixedwing, rotorcraft, hybrid

D.C. van Wijngaarden^*, E.J.J. Smeur, B.D.W. Remes

^*Corresponding author for this work

Control & Simulation

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

58 Downloads (Pure)

Abstract

Rotorcraft, fixed wing and hybrid Unmanned Air Vehicles (UAV) each have applications in which they excel. Traditionally, dedicated autopilot control code is written to accommodate flight of each UAV type. This causes fragmentation of control code and may lead to performance differences or errors. In this paper, we propose to use the same INDI controller for rotorcraft, fixed wing and hybrid UAVs, with only parametric differences in control effective matrix definitions and roll, pitch and airspeed limits. The controller is based on earlier work, but relevant derivations are included in this paper. Successful test flights, performed with a Bebop2 quadrotor, a Disco fixed wing, and a Nederdrone tailsitter hybrid demonstrate the feasibility of this approach.

Original language	English
Title of host publication	12th International Micro Air Vehicle Conference
Place of Publication	Puebla, México
Pages	21-27
Number of pages	7
Publication status	Published - 2021
Event	12th International Micro Air Vehicle Conference - Puebla, Mexico Duration: 17 Nov 2021 → 19 Nov 2021 Conference number: 12

Conference

Conference	12th International Micro Air Vehicle Conference
Abbreviated title	IMAV 2021
Country/Territory	Mexico
City	Puebla
Period	17/11/21 → 19/11/21

Keywords

UAV
Hybrid MAVs
Flight Control
Incremental Nonlinear Dynamic Inversion

Access to Document

van wijngaarden - Flight Code Convergence Fixedwing, Rotorcraft, HybridFinal published version, 2.48 MB

https://www.imavs.org/tag/imav2021/

Cite this

@inproceedings{35c4b1cbfa7e4776a59740eba912776f,

title = "Flight code convergence: fixedwing, rotorcraft, hybrid",

abstract = "Rotorcraft, fixed wing and hybrid Unmanned Air Vehicles (UAV) each have applications in which they excel. Traditionally, dedicated autopilot control code is written to accommodate flight of each UAV type. This causes fragmentation of control code and may lead to performance differences or errors. In this paper, we propose to use the same INDI controller for rotorcraft, fixed wing and hybrid UAVs, with only parametric differences in control effective matrix definitions and roll, pitch and airspeed limits. The controller is based on earlier work, but relevant derivations are included in this paper. Successful test flights, performed with a Bebop2 quadrotor, a Disco fixed wing, and a Nederdrone tailsitter hybrid demonstrate the feasibility of this approach.",

keywords = "UAV, Hybrid MAVs, Flight Control, Incremental Nonlinear Dynamic Inversion",

author = "{van Wijngaarden}, D.C. and E.J.J. Smeur and B.D.W. Remes",

year = "2021",

language = "English",

pages = "21--27",

booktitle = "12th International Micro Air Vehicle Conference",

note = "12th International Micro Air Vehicle Conference, IMAV 2021 ; Conference date: 17-11-2021 Through 19-11-2021",

}

TY - GEN

T1 - Flight code convergence: fixedwing, rotorcraft, hybrid

AU - van Wijngaarden, D.C.

AU - Smeur, E.J.J.

AU - Remes, B.D.W.

N1 - Conference code: 12

PY - 2021

Y1 - 2021

N2 - Rotorcraft, fixed wing and hybrid Unmanned Air Vehicles (UAV) each have applications in which they excel. Traditionally, dedicated autopilot control code is written to accommodate flight of each UAV type. This causes fragmentation of control code and may lead to performance differences or errors. In this paper, we propose to use the same INDI controller for rotorcraft, fixed wing and hybrid UAVs, with only parametric differences in control effective matrix definitions and roll, pitch and airspeed limits. The controller is based on earlier work, but relevant derivations are included in this paper. Successful test flights, performed with a Bebop2 quadrotor, a Disco fixed wing, and a Nederdrone tailsitter hybrid demonstrate the feasibility of this approach.

AB - Rotorcraft, fixed wing and hybrid Unmanned Air Vehicles (UAV) each have applications in which they excel. Traditionally, dedicated autopilot control code is written to accommodate flight of each UAV type. This causes fragmentation of control code and may lead to performance differences or errors. In this paper, we propose to use the same INDI controller for rotorcraft, fixed wing and hybrid UAVs, with only parametric differences in control effective matrix definitions and roll, pitch and airspeed limits. The controller is based on earlier work, but relevant derivations are included in this paper. Successful test flights, performed with a Bebop2 quadrotor, a Disco fixed wing, and a Nederdrone tailsitter hybrid demonstrate the feasibility of this approach.

KW - UAV

KW - Hybrid MAVs

KW - Flight Control

KW - Incremental Nonlinear Dynamic Inversion

M3 - Conference contribution

SP - 21

EP - 27

BT - 12th International Micro Air Vehicle Conference

CY - Puebla, México

T2 - 12th International Micro Air Vehicle Conference

Y2 - 17 November 2021 through 19 November 2021

ER -

Flight code convergence: fixedwing, rotorcraft, hybrid

Abstract

Conference

Keywords

Access to Document

Fingerprint

Cite this