多旋翼固定翼无人机多体动力学建模

Han Wu; Zhengping Wang; Zhou Zhou; Rui Wang

doi:10.1051/jnwpu/20193750928

多旋翼固定翼无人机多体动力学建模

Translated title of the contribution: Modeling and Simulation for Multi-Rotor Fixed-Wing UAV Based on Multibody Dynamics

Han Wu, Zhengping Wang, Zhou Zhou, Rui Wang

School of Aeronautics

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

Accurate dynamic modeling lays foundation for design and control of UAV. The dynamic model for the multi-rotor fixed-wing UAV was looked into and it was divided into fuselage, air-body, multi-rotors, vertical fin, vertical tail and control surfaces, based on the multibody dynamics. The force and moment model for each body was established and derived into the Lagrange equation of the second king by virtual work. By electing quaternion as generalized coordinate and introducing Lagrangian multiplier, the dynamic modeling was deduced and established. Finally, the comparison between the simulation results and the experimental can be found that the present dynamic model accurately describes the process of dynamic change of this UAV and lay foundation for the control of UAV.

Translated title of the contribution	Modeling and Simulation for Multi-Rotor Fixed-Wing UAV Based on Multibody Dynamics
Original language	Chinese (Traditional)
Pages (from-to)	928-934
Number of pages	7
Journal	Xibei Gongye Daxue Xuebao/Journal of Northwestern Polytechnical University
Volume	37
Issue number	5
DOIs	https://doi.org/10.1051/jnwpu/20193750928
State	Published - 1 Oct 2019

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title = "多旋翼固定翼无人机多体动力学建模",

abstract = "Accurate dynamic modeling lays foundation for design and control of UAV. The dynamic model for the multi-rotor fixed-wing UAV was looked into and it was divided into fuselage, air-body, multi-rotors, vertical fin, vertical tail and control surfaces, based on the multibody dynamics. The force and moment model for each body was established and derived into the Lagrange equation of the second king by virtual work. By electing quaternion as generalized coordinate and introducing Lagrangian multiplier, the dynamic modeling was deduced and established. Finally, the comparison between the simulation results and the experimental can be found that the present dynamic model accurately describes the process of dynamic change of this UAV and lay foundation for the control of UAV.",

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T1 - 多旋翼固定翼无人机多体动力学建模

AU - Wu, Han

AU - Wang, Zhengping

AU - Zhou, Zhou

AU - Wang, Rui

PY - 2019/10/1

Y1 - 2019/10/1

N2 - Accurate dynamic modeling lays foundation for design and control of UAV. The dynamic model for the multi-rotor fixed-wing UAV was looked into and it was divided into fuselage, air-body, multi-rotors, vertical fin, vertical tail and control surfaces, based on the multibody dynamics. The force and moment model for each body was established and derived into the Lagrange equation of the second king by virtual work. By electing quaternion as generalized coordinate and introducing Lagrangian multiplier, the dynamic modeling was deduced and established. Finally, the comparison between the simulation results and the experimental can be found that the present dynamic model accurately describes the process of dynamic change of this UAV and lay foundation for the control of UAV.

AB - Accurate dynamic modeling lays foundation for design and control of UAV. The dynamic model for the multi-rotor fixed-wing UAV was looked into and it was divided into fuselage, air-body, multi-rotors, vertical fin, vertical tail and control surfaces, based on the multibody dynamics. The force and moment model for each body was established and derived into the Lagrange equation of the second king by virtual work. By electing quaternion as generalized coordinate and introducing Lagrangian multiplier, the dynamic modeling was deduced and established. Finally, the comparison between the simulation results and the experimental can be found that the present dynamic model accurately describes the process of dynamic change of this UAV and lay foundation for the control of UAV.

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多旋翼固定翼无人机多体动力学建模

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