A Novel Adaptive Sliding Mode Controller for a 2-DOF Elastic Robotic Arm

Tuan, Hua Minh; Sanfilippo, Filippo; Hao, Nguyen Vinh

doi:10.3390/robotics11020047

Cited by 6 publications

(3 citation statements)

References 43 publications

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“…Hence, they are not reasonable solutions for commercialization. Adaptive sliding mode [63] is a complex method to handle models with two degrees of freedom, with the ability to be adapted online. It is an appropriate method for managing uncertainties, but it is not a reliable solution to grasp different objects without training.…”

Section: Discussionmentioning

confidence: 99%

Improving robotic hand control via adaptive Fuzzy-PI controller using classification of EMG signals

Barfi¹,

Karami²,

Faridi³

et al. 2022

Heliyon

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Section: Discussionmentioning

confidence: 99%

Improving robotic hand control via adaptive Fuzzy-PI controller using classification of EMG signals

Barfi¹,

Karami²,

Faridi³

et al. 2022

Heliyon

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“…Besides softening the interaction force by designing soft joints from a mechanical perspective, imposing desired behaviour on the robot can also be done from the software Fig. 2: A soft robotic arm is in a compressed state due to the collision with the environment [9] side [13]. To achieve this, in [14], Hogan presented two concepts, i.e.…”

Section: B Admittance and Impedancementioning

confidence: 99%

From Rigid to Hybrid/Soft Robots: Exploration of Ethical and Philosophical Aspects in Shifting from Caged Robots to Human-Robot Teaming

Hua,

Langås,

Zafar

et al. 2023

2023 IEEE Symposium Series on Computational Intelligence (SSCI)

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This paper delves into the ethical, philosophical, and practical dimensions associated with the transition from caged robots to human-robot teaming (HRT). By exploring the evolving dynamics between humans and robots, this paper examines the ethical challenges, philosophical implications, and practical considerations that arise as collaboration and integration between humans and robots deepen. It emphasises the need for responsible design, implementation, and ethical frameworks to guide the development and deployment of human-robot teams. Particular focus is put into the ethical ramifications of choosing between rigid and soft actuators. The study underscores the significance of employing admittance and impedance control techniques to regulate interaction forces and compliance between humans and robots. By analysing the ethical implications of utilising soft actuators, the paper emphasises the potential advantages, such as enhanced safety and reduced risk of harm during close humanrobot collaboration.

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“…To overcome the limitations of a single control method, combining the SMC method with various intelligent control methods has emerged as an important research direction. For example, combining impedance control [3] , high-order super distortion control [4] , fuzzy control [5] , adaptive control [6,7], etc., can effectively reduce the generation of chattering. However, compared to integer order control, research has found that introducing fractional calculus theory into sliding mode control theory can greatly improve the degree of freedom of controller design, making the design more flexible [8] .…”

Section: Introductionmentioning

confidence: 99%

Fractional order adaptive sliding mode control method of manipulator

Zhang,

Ma,

Zhuang

et al. 2024

J. Phys.: Conf. Ser.

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A new controller (NAFOFTSMC) is designed and successfully applied to the manipulator system. Compared with traditional integer-order sliding mode control methods (IOSMC), the fractional order sliding mode control method (FOSMC) adopted additional degrees of freedom and, to some extent, weakens the drawback of sliding mode control chattering problem. Fractional-order adaptive rate compensation is utilized to compensate for the total disturbance set of the system. The new sliding surface reduces the derivative signals that are difficult to obtain due to external interference and other factors in the robotic arm system. It also reduces the unknown parameters for adjustment, increases the proportion term, and thus enables the system to have higher control accuracy and shorter adjustment time. While designing the controller, the stability is proved at the end of the fourth section. At the same time, this control method was compared and analyzed with IOSMC, simple FOSMC, and a Pre-improved controller (AFOFTSMC).

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A Novel Adaptive Sliding Mode Controller for a 2-DOF Elastic Robotic Arm

Cited by 6 publications

References 43 publications

Improving robotic hand control via adaptive Fuzzy-PI controller using classification of EMG signals

Improving robotic hand control via adaptive Fuzzy-PI controller using classification of EMG signals

From Rigid to Hybrid/Soft Robots: Exploration of Ethical and Philosophical Aspects in Shifting from Caged Robots to Human-Robot Teaming

Fractional order adaptive sliding mode control method of manipulator

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