A Comparative Study Between Convolution and Optimal Backstepping Controller for Single Arm Pneumatic Artificial Muscles

Ahmed, Amna S.; Kadhim, Saleem Khalefa

doi:10.18196/jrc.v3i6.16064

Cited by 5 publications

(5 citation statements)

References 39 publications

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“…Further advancements can be explored by suggesting other control techniques, such as adaptive control schemes, observe-based control, backstepping-based control, and active disturbance rejection control for the sake of comparison [45][46][47][48][49][50][51]. Also, an improvement of the proposed controller can be presented by suggesting modern optimization techniques to optimize the design parameters of the controller [52][53][54][55]. Another extension of this study could be to implement the proposed control in a real-time environment, either using a FPGA (field programming gate array) hardware tool, Raspberry-Pi single board computer, or LabVIEW-based data acquisition system [56][57][58][59][60].…”

Section: Discussionmentioning

confidence: 99%

Design of a Robust Controller Based on Barrier Function for Vehicle Steer-by-Wire Systems

Husain,

Al-Dujaili,

Jaber

et al. 2024

WEVJ

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In this research paper, a recent robust control scheme was proposed and designed for a VSbW (vehicle steer-by-wire) system. Using an integral sliding mode control (ISMC) design based on barrier function (ISMCbf) could improve the robustness of ISMCs. This control scheme, due to the characteristics of the barrier function, can improve the robustness of the proposed controller better than that based on the conventional SMC or integral SMC (ISMC). The ISMCbf scheme exhibits all the benefits of the conventional ISMC with the addition of two main advantages: it does not require prior knowledge of perturbation bounds or their derivatives, and it can effectively eliminate the chattering phenomenon associated with the classical ISMC due to the smooth characteristics of the barrier function. On the other hand, in terms of the design implementation, the ISMCbf is simpler than the ISMC. In this study, the mathematical dynamical model of the VSbW plant was first presented. Then, the control design of the ISMCbf scheme was developed. The numerical results showed that the proposed scheme is superior to the conventional ISMC. The superiority of the proposed ISMCbf controller versus the classical ISM has been evaluated under three different uncertain conditions, and three scenarios can be deduced: a slalom path, quick steering, and shock disturbance rejection. Furthermore, a comparative analysis with other controllers from the literature has further been established to show the effectiveness of the proposed ISMCbf.

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Section: Discussionmentioning

confidence: 99%

Design of a Robust Controller Based on Barrier Function for Vehicle Steer-by-Wire Systems

Husain,

Al-Dujaili,

Jaber

et al. 2024

WEVJ

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“…This section meticulously examines the performance of three control strategies for regulating airway pressure in respirators, focusing primarily on the data showcased in Figure 6. It is important to note that introducing nonlinear elements may escalate the controller's complexity [35][36][37].…”

Section: Comparative Analysis Of Pid Npid and Smc For Respirator Airw...mentioning

confidence: 99%

Comparative Analysis of Airflow Regulation in Ventilator Systems Using Various Control Strategies

Shanan,

Kadhim

2023

JESA

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Ventilator designs, pivotal in providing respiratory support to patients, often grapple with performance optimization challenges due to variable patient conditions and intricate mechanical components. This research strives to identify the optimal control strategy that can assure maximal patient safety and efficient ventilator operation. We compared three control strategies: the conventional Proportional-Integral-Derivative (PID) control, the Nonlinear PID control, and the sliding mode control (SMC) equipped with signum function triggers. Our studies underscored the preeminence of SMC in controlling airway pressure, exhibiting a rapid and disturbance-free response. However, while SMC ensured smooth patient airflow in flow rate control, it exhibited a slightly delayed response. The research thus posits SMC as a promising contender, particularly in light of the sophisticated design requirements of contemporary ventilators. Through this investigation, we aim to offer a robust control solution capable of enhancing current ventilator operations to ensure superior patient safety and efficiency.

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“…Due to their highly time-varying, nonlinear, ambiguous parameter structure, the PAM systems' operating ranges are highly constrained by factors that affect them, such as viscosity, temperature, and supply pressure. PAMs are unable to be controlled, which is another significant problem [9]. This is because the system mechanics contains many non-deterministic parameters and non-linear and nondeterministic elements that hinder the design of a reasonable and accurate actuator tracking controller [10].…”

Section: Introductionmentioning

confidence: 99%

“…The amount of pneumatic muscle extension xt and muscle contraction xb can be expressed respectively by researches [26,27]:…”

Section: Introductionmentioning

confidence: 99%

“…where m denotes mass in (kg), g represents gravitational acceleration (m/s 2 ), r is the pulley radius (m), xt represents pneumatic muscle extension (m), and xb is the muscle contraction (m). The PMs are attached to the elbow at point A, which is a rotational axis away from the joint.L is distance between joint and the load's center of mass.The amount of pneumatic muscle extension xt and muscle contraction xb can be expressed respectively by researches[26,27]:…”

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confidence: 99%

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Non-Leaner Control on the Pneumatic Artificial Muscles: A Comparative Study Between Adaptive Backstepping and Conventional Backstepping Algorithms

Ahmed¹,

Kadhim²

2023

MMEP

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This paper focuses on the control of Pneumatic Artificial Muscles (PAMs) used in arm manipulator modeling and the dynamic model of the Pneumatic Artificial Muscles. PAMs have become popular in robotics due to their fast work capabilities, direct action mechanisms, and safety implementation. However, these systems often suffer from uncertainty, nonlinearity, and time-varying features, which negatively impact tracking control performance and cause instability in motion outcomes. To address these issues, this study presents a comparison of two controllers: an adaptive backstepping controller and a backstepping convolution controller. Computer simulations were used to evaluate the performance of both controllers. The results demonstrate that the adaptive backstepping controller effectively eliminates chattering, reduces error, and maintains stability in the controlled system, leading to smoother signal curves and improved overall response in the arm model. In conclusion, the study provides evidence that the adaptive backstepping controller is a more effective control solution for PAM-led arm manipulator systems, offering improved control of uncertainties and better motiontracking performance. These findings have important implications for the development of advanced robotic systems using PAMs.

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A Comparative Study Between Convolution and Optimal Backstepping Controller for Single Arm Pneumatic Artificial Muscles

Cited by 5 publications

References 39 publications

Design of a Robust Controller Based on Barrier Function for Vehicle Steer-by-Wire Systems

Design of a Robust Controller Based on Barrier Function for Vehicle Steer-by-Wire Systems

Comparative Analysis of Airflow Regulation in Ventilator Systems Using Various Control Strategies

Non-Leaner Control on the Pneumatic Artificial Muscles: A Comparative Study Between Adaptive Backstepping and Conventional Backstepping Algorithms

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