Engineering Comprehensive Model of Complex Wind Fields for Flight Simulation

Chen, Jianwei; Wang, Liangming; Fu, Jian Qin; Yang, Zhiwei

doi:10.3390/aerospace8060145

Cited by 2 publications

(1 citation statement)

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“…The turbulence process is stochastic and is expressed by velocity spectra [31]. In this work, we apply the most frequently used model called the Dryden turbulence model [32]. Without loss of generality, we admit that the turbulence field is fixed in time and space.…”

Section: The Dryden Wind Turbulencementioning

confidence: 99%

Adaptive proportional integral derivative deep feedforward network for quadrotor trajectory-tracking flight control

Chater

Housny

Fadil

2022

IJECE

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<span>When the controlled system is subject to parameter variations and external disturbances, a fixed-parameter proportional integral derivative (PID) controller cannot ensure its stabilization. In this case, its control requires online parameter adjustment. Specifically, as the quadrotor is a multi-input multi-output, nonlinear, and underactuated system, robust control is necessary to ensure efficient trajectory tracking flights. In this paper, an adaptive proportional integral derivative (APID) controller is proposed to control the quadrotor systems. This APID-based control strategy uses a two hidden layer deep feedforward network (DFN), where the one-step secant algorithm is chosen for initializing the DFN parameters. All the design steps of the proposed adaptive controller are described. The multidimensional particle swarm optimization (PSO) algorithm is used for tuning the DFN parameters. Then, using two simulation efficiency tests, a comparison between the proposed PSO-based APID-DFN, the (non-optimized) APID-DFN, the feedforward network APID, and the fixed-parameter PID controllers proves much efficiency of the proposed adaptive controller. The results illustrate that the proposed PSO-based APID-DFN controller can ensure good quadrotor system stabilization and achieve minimum overshoot and faster convergence speed for all quadrotor motions. Thus, the proposed control strategy could be considered an additional intelligent method-based adaptive control for unmanned aerial vehicles.</span>

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Section: The Dryden Wind Turbulencementioning

confidence: 99%