Aiming at a more efficient and accurate performance of parallel manipulators in the existence of complex kinematics and dynamics, a robust generalizable methodology is proposed here for an integrated 6-DOF Stewart platform with rotary time-delayed actuators torque control. The suggested method employs a time-delay linear–quadratic integral regulator with online artificial neural network gain adjustment. The unknown time-delay is estimated through a novel robust adaptive estimator. The global asymptotic stability of the estimator is proved via a Lyapunov function. The controller is developed in MATLAB software and implemented on the robot designed in ADAMS software to ensure that the real-time tracking error of a nonlinear system with an unk...
In this manuscript, we formulate and experimentally verify four state-of-the-art controlstrategies o...
Controller gain is often limited by time delay in the control loop and therefore actuation is constr...
This brief proposes a new adaptive-robust formulation for time-delay control (TDC) under a less-rest...
In the presence of complicated kinematic and dynamic, we present a generalizable robust control tech...
Aiming at operating optimally minimizing error of tracking and designing control effort, this study ...
This paper presents a practical adaptive time-delay control scheme (ATDC) and then applies it to rob...
This article proposes an enhanced adaptive time delay controller (ATDC) for robot manipulators subje...
The robot manipulators are used in network-based industrial units, and even homes, by expending a si...
Aiming at operating optimally minimizing error of tracking and designing control effort, this study ...
To improve the trajectory tracking performance of a complex nonlinear robotic system, a velocity-fre...
A time delay estimation based general framework for trajectory tracking control of robot manipulator...
Thanks to its simplicity and robustness, time delay control (TDC) has been recognized as a simple an...
This study proposes an innovative reinforcement learning-based time-delay control (RL-TDC) scheme to...
In this article, we propose an innovative model-free control (MFC) algorithm using an adaptive model...
In this paper, a novel adaptive robust controller is presented for high-accuracy tracking control of...
In this manuscript, we formulate and experimentally verify four state-of-the-art controlstrategies o...
Controller gain is often limited by time delay in the control loop and therefore actuation is constr...
This brief proposes a new adaptive-robust formulation for time-delay control (TDC) under a less-rest...
In the presence of complicated kinematic and dynamic, we present a generalizable robust control tech...
Aiming at operating optimally minimizing error of tracking and designing control effort, this study ...
This paper presents a practical adaptive time-delay control scheme (ATDC) and then applies it to rob...
This article proposes an enhanced adaptive time delay controller (ATDC) for robot manipulators subje...
The robot manipulators are used in network-based industrial units, and even homes, by expending a si...
Aiming at operating optimally minimizing error of tracking and designing control effort, this study ...
To improve the trajectory tracking performance of a complex nonlinear robotic system, a velocity-fre...
A time delay estimation based general framework for trajectory tracking control of robot manipulator...
Thanks to its simplicity and robustness, time delay control (TDC) has been recognized as a simple an...
This study proposes an innovative reinforcement learning-based time-delay control (RL-TDC) scheme to...
In this article, we propose an innovative model-free control (MFC) algorithm using an adaptive model...
In this paper, a novel adaptive robust controller is presented for high-accuracy tracking control of...
In this manuscript, we formulate and experimentally verify four state-of-the-art controlstrategies o...
Controller gain is often limited by time delay in the control loop and therefore actuation is constr...
This brief proposes a new adaptive-robust formulation for time-delay control (TDC) under a less-rest...