The use of wheeled mobile robots (MRs) with symmetrical structure in engineering is rapidly increasing, with applications in various fields, such as industry, agriculture, forestry, healthcare, mining, rehabilitation, search and rescue, household tasks, remote locations, and entertainment. As MRs become more common, researchers are focusing on developing better ways to model and control these robots to improve their performance and adaptability. The main challenges in this area include uncertain dynamics, non-holonomic constraints, and various perturbations, which complicate the design of the control system. This paper presents a new predictive control scheme for MRs that is independent of the dynamics and the robot’s working environment. A Type-3 fuzzy logic system is developed to identify the MR dynamics online. The designed predictive scheme improves accuracy and speeds up convergence, while also addressing uncertainties and considering constraints on control input. Additionally, a chaotic-based system is proposed for secure path planning, generating a complex and unpredictable reference trajectory that is useful for patrol MR applications. The effectiveness of the suggested controller is demonstrated through simulations and experiments.
A constrained Fuzzy control for robotic systems / Xue, Wenkui; Zhou, Baozhi; Chen, Fenghua; Taghavifar, Hamid; Mohammadzadeh, Ardashir; Ghaderpour, Ebrahim. - In: IEEE ACCESS. - ISSN 2169-3536. - 12:(2024), pp. 7298-7309. [10.1109/ACCESS.2024.3352129]
A constrained Fuzzy control for robotic systems
Ebrahim Ghaderpour
Ultimo
Writing – Review & Editing
2024
Abstract
The use of wheeled mobile robots (MRs) with symmetrical structure in engineering is rapidly increasing, with applications in various fields, such as industry, agriculture, forestry, healthcare, mining, rehabilitation, search and rescue, household tasks, remote locations, and entertainment. As MRs become more common, researchers are focusing on developing better ways to model and control these robots to improve their performance and adaptability. The main challenges in this area include uncertain dynamics, non-holonomic constraints, and various perturbations, which complicate the design of the control system. This paper presents a new predictive control scheme for MRs that is independent of the dynamics and the robot’s working environment. A Type-3 fuzzy logic system is developed to identify the MR dynamics online. The designed predictive scheme improves accuracy and speeds up convergence, while also addressing uncertainties and considering constraints on control input. Additionally, a chaotic-based system is proposed for secure path planning, generating a complex and unpredictable reference trajectory that is useful for patrol MR applications. The effectiveness of the suggested controller is demonstrated through simulations and experiments.| File | Dimensione | Formato | |
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Xue_ Constrained_2024.pdf
accesso aperto
Note: Received 25 December 2023, accepted 7 January 2024, date of publication 10 January 2024, date of current version 18 January 2024. Digital Object Identifier 10.1109/ACCESS.2024.3352129 A Constrained Fuzzy Control for Robotic Systems
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3.56 MB | Adobe PDF |
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