Modelling and Attitude Control of an Agile Fixed Wing UAV based on Nonlinear Dynamic Inversion

Kimathi, Stephen; Lantos, Béla

doi:10.3311/ppee.20287

Cited by 4 publications

(2 citation statements)

References 9 publications

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“…The physical properties of a Yak-54 scaled unmanned aircraft are given in Table 1. Equations ( 13), ( 14) were used to carry out numerical simulations in Matlab using the model and structure adapted from [30]. The simulation was designed using an appropriate maneuver such that the control deflections were not too large to yield impractical data nor too small to not excite the dynamic modes.…”

Section: Simulation Flight Datamentioning

confidence: 99%

Robust Aerodynamic Parameter Estimation of Unmanned Aircraft Based on Two-step Identification

Kimathi

Lantos

2023

Period. Polytech. Elec. Eng. Comp. Sci.

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This paper presents the estimation of stability and control derivatives of an unmanned aircraft. The aerodynamics are described using regressors composed of velocity, angular rates, flow angles and control surface deflections. The flight data is generated from numerical simulation of postulated equations of motion describing the aerodynamics model. Least squares based on the equation error method is used to estimate the parameters representing the different force and moment aerodynamic coefficients. Statistical analysis is done on the estimates to determine the accuracy and adequacy of the estimates to describe the aerodynamic model. A dynamic simulation based on the identified aerodynamic model is used to improve the parameter estimates through regression of the errors between the flight data and the model response. The aircraft under consideration is a scaled Yak-54 fixed wing unmanned aerial vehicle.

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Section: Simulation Flight Datamentioning

confidence: 99%

Robust Aerodynamic Parameter Estimation of Unmanned Aircraft Based on Two-step Identification

Kimathi

Lantos

2023

Period. Polytech. Elec. Eng. Comp. Sci.

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“…Dynamic inversion is one of the feedback linearization methods which can effectively realize global linearization and decoupling of nonlinear systems [1][2][3] . However, it heavily depends on a precise mathematical model.…”

Section: Introductionmentioning

confidence: 99%

Gliding Vehicle Controller Based on Neural Network Compensating Dynamic Inversion Error

Liu

2023

J. Phys.: Conf. Ser.

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Aiming at the attitude control problem of the gliding vehicle with uncertainty and strong coupling, a dynamic inversion control method based on RBF neural network compensated inversion error is discussed. Firstly, based on the double time scale separation hypothesis, the controlled aircraft model is divided into a fast and slow state subsystem. Then the dynamic inversion control laws are designed for each of the two subsystems. The weight update rule of the RBF neural network is derived online based on the Lyapunov stability principle to compensate for the inversion error caused by the modeling error and uncertainty. The simulation verifies the effectiveness of the control law. The robustness of the control system after neural network compensation is significantly improved.

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Integrated Path Tracking, and Control of a Fixed Wing UAV based on Dual Quaternion Parameterized Dynamics

Kimathi,

Lantos

2024

2024 47th MIPRO ICT and Electronics Convention (MIPRO)

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Modelling and Attitude Control of an Agile Fixed Wing UAV based on Nonlinear Dynamic Inversion

Cited by 4 publications

References 9 publications

Robust Aerodynamic Parameter Estimation of Unmanned Aircraft Based on Two-step Identification

Robust Aerodynamic Parameter Estimation of Unmanned Aircraft Based on Two-step Identification

Gliding Vehicle Controller Based on Neural Network Compensating Dynamic Inversion Error

Integrated Path Tracking, and Control of a Fixed Wing UAV based on Dual Quaternion Parameterized Dynamics

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