Real-Time Interval Type-2 Fuzzy Control of an Unmanned Aerial Vehicle with Flexible Cable-Connected Payload

Candan, Fethi; Dik, Omer Faruk; Kumbasar, Tufan; Mahfouf, Mahdi; Mihaylova, Lyudmila

doi:10.3390/a16060273

Cited by 2 publications

References 46 publications

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Automatic control of UAVs: new adaptive rules and type-3 fuzzy stabilizer

Cai,

Zhang,

Khadakar

et al. 2024

Complex Intell. Syst.

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Unmanned Aerial Vehicles (UAVs) have become important in an extensive range of fields such as surveillance, environmental monitoring, agriculture, infrastructure inspection, commercial applications, and many others. Ensuring stable flight and precise control of UAVs, especially in adverse weather conditions or turbulent environments, presents significant challenges. Developing control systems that can adapt to these environmental factors while ensuring safe and reliable operation is a main motivation. Considering the challenges, first, an adaptive model is identified using the input/output data sets. New adaptation laws are obtained for dynamic parameters. Then, a Type-3 (T3) Fuzzy Logic System (FLS) is used to compensate for the error of dynamic identification. T3-FLS is tuned by a sliding mode control (SMC) strategy. The robustness is analyzed considering the adaptation error using the SMC approach. The main idea is that the basic dynamics of UAVs are taken into account, and adaptation laws are designed to enhance the modeling accuracy. On the other hand, an optimized T3-FLS with SMC is introduced to eliminate the adaption errors and ensure robustness. Several simulations show that known parameters converge under uncertainty, and the stability is kept, well. Also, output signals follow the desired trajectories under dynamic perturbations, identification errors, and uncertainties.

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Automatic control of UAVs: new adaptive rules and type-3 fuzzy stabilizer

Cai,

Zhang,

Khadakar

et al. 2024

Complex Intell. Syst.

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An Interacting Multiple Model Approach Based on Maximum Correntropy Student's T Filter

Candan,

Beke,

Mihaylova

2023

2023 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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This paper presents a novel approach called the Interacting Multiple Model (IMM)-based Maximum Correntropy Student's T Filter (MCStF), which addresses the challenges posed by non-Gaussian measurement noises. The MCStF demonstrates superior performance compared to the IMM algorithm based on Kalman Filters (KFs) in both simulation environments and real-time systems. The Crazyflie 2.0 nano Unmanned Air Vehicle (UAV) model is used in the simulation validation, and results from 3000 independent Monte Carlo runs are shown. After getting the simulation results under monotonously changed non-Gaussian distribution, their performance results have been compared to each other. The same scenario has been applied in the real-time system using Crazyflie 2.0. Next, results from real-time tests are presented in which the position of Crazyflie 2.0 is estimated online.

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Real-Time Interval Type-2 Fuzzy Control of an Unmanned Aerial Vehicle with Flexible Cable-Connected Payload

Cited by 2 publications

References 46 publications

Automatic control of UAVs: new adaptive rules and type-3 fuzzy stabilizer

Automatic control of UAVs: new adaptive rules and type-3 fuzzy stabilizer

An Interacting Multiple Model Approach Based on Maximum Correntropy Student's T Filter

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