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

Chater, El Ayachi; Housny, Halima; Fadil, H. El

doi:10.11591/ijece.v12i4.pp3607-3619

Cited by 3 publications

(3 citation statements)

References 34 publications

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“…For each dynamic, setting conditions that ensure the system's stability is possible. For the dynamics of Z, shown in (7), the stability is determined by Theorem1 and is tested with Lyapunov's sense analysis. Theorem 1.…”

Section: Stability Testmentioning

confidence: 99%

Optimisation of nonlinear controllers for a quadrotor using metaheuristic algorithm

Samantha Zuñiga-Peña,

Hernandez-Romero,

Carlos Seck-Tuoh Mora

et al. 2024

IJEECS

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Unmanned aerial vehicles (UAVs) facilitate complex activities and are widely used for aerial transport. Quadrotor UAVs (QUAV), the most popular UAV containing four motors, are characterised by higher control properties since they have fewer actuators than degrees of freedom, implying a nonlinear underactuated system. In addition, the coupling of dynamics, flaws while modelling and parameter uncertainty are the factors that hinder the design and implementation of a controller. Here, we present the modelling, optimisation, simulation, and implementation methodology for controllers, proportional-integralderivative (PID), and super-twisting-sliding mode control (ST-SMC). We carry out the parameterisation problem of controllers using the hunger game search (HGS) metaheuristic algorithm. This process was developed offline, and the values obtained were successfully implemented in simulation and experimental form. The testing platform comprises a motion capture system, Vicon® Bonita cameras, linked by ROS, that allows the known position and the attitude of a Parrot® QUAV bebop1. The whole six dynamics of the QUAV are included in the implementation, translational trajectories X-Y are trapezoidal, and the altitude trajectory is a ramp. The results enabled the comparison of the statistics calculation of each controller. Successful tracking trajectories were obtained even with disturbance when the ST-SMC algorithm was implemented with root mean square error (RMSE)=0.0176.

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Section: Stability Testmentioning

confidence: 99%

Optimisation of nonlinear controllers for a quadrotor using metaheuristic algorithm

Samantha Zuñiga-Peña,

Hernandez-Romero,

Carlos Seck-Tuoh Mora

et al. 2024

IJEECS

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“…(35) which is described mathematically in the form of the following inputs/outputs: 𝐸(𝑦, 𝑦, … , 𝑦 (𝑎) , 𝑢, 𝑢̇, … , 𝑢 (𝑏) , 𝑑) = 0 (35) d represents disturbances that are generally caused by external sources. The objective is to ensure the proper tracking [20] of trajectories even if the precise dynamics of the system are not required. For this approach.…”

Section: Control Strategymentioning

confidence: 99%

Intelligent Control of Inter Distance in Convoy of Vehicles Using Model-Free Control and Algebraic Filter

Bouras,

Bekaik

2024

IJTDI

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Road accidents are the leading cause of death; this increase is usually due to speeding. For road safety, intelligent systems have been designed to keep a constant speed and a safe distance between vehicles in a convoy. This article focuses on the synthesis of an interdistance control system using intelligent methods and algorithms. The main idea presented in this article is to implement a model-free control for physical model "spring-damper" known as intelligent control based on an algebraic filter. Our comparative analysis extends beyond comparing the use of a simple derivative and an algebraic filter for intelligent control. We also take into account the effect of noise directly affecting the model's behaviour to demonstrate the robustness of our approach. Through MATLAB simulations, we highlight that our approach exhibits better robustness and stable tracking in the interdistance control system.

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“…To establish an effective control system for the UGV robot, the design process necessitates the utilization of a suitable methodology. Numerous approaches for robot control systems can be employed encompassing PID (Proportional Integral Derivative) controllers, Fuzzy Logic, genetic algorithms, artificial neural networks, and more [6]. Among these options, PID controllers are widely applied in control system applications, owing to their proven effectiveness [7].…”

Section: Introductionmentioning

confidence: 99%

433Mhz based Robot using PID (Proportional Integral Derivative) for Precise Facing Direction

Hariyadi,

Fadila,

Sifaulloh

2023

JOIV : Int. J. Inform. Visualization

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This research endeavor aims to evaluate the effectiveness of the robot's direction control system by employing PID (Proportional Integral Derivative) output and utilizing wireless communication LoRa E32 433MHz. The experimental robot used in this study was a tank model robot equipped with 4 channels of control. LoRa was implemented in the robot control system, in conjunction with an Android control application, through serial data communication. The LoRa E32 module system was selected based on its established reliability in long-range communication applications. However, encountered challenges included the sluggishness of data transmission when using LoRa for transferring control data and the decreased performance of the robot under Non-Line of Sight conditions. To overcome these challenges, the PID method was employed to generate control data for the robot, thereby minimizing the error associated with controlling its movements. The PID system utilized feedback from a compass sensor (HMC5883L) to evaluate the setpoint data transmitted by the user, employing Kp, Ki, and Kd in calculations to enable smooth movements toward the setpoint. The findings of this study regarding the direct control of the robot using wireless LoRa E32 communication demonstrated an error range of 0.6% to 13.34%. A trial-and-error approach for control variables determined the optimal values for Kp, Ki, and Kd as 10, 0.1, and 1.5, respectively. Future investigations can integrate additional methodologies to precisely and accurately determine the PID constants (Kp, Ki, and Kd) mathematically.

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

Cited by 3 publications

References 34 publications

Optimisation of nonlinear controllers for a quadrotor using metaheuristic algorithm

Optimisation of nonlinear controllers for a quadrotor using metaheuristic algorithm

Intelligent Control of Inter Distance in Convoy of Vehicles Using Model-Free Control and Algebraic Filter

433Mhz based Robot using PID (Proportional Integral Derivative) for Precise Facing Direction

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