Ziting Chen scite author profile

To perform power augmentation tasks of a robotic exoskeleton, this paper utilizes fuzzy approximation and designed disturbance observers for compensating the disturbance torques caused by unknown input saturation, fuzzy approximation errors, viscous friction, gravity and payloads. The proposed adaptive fuzzy control with updated parameters mechanism and additional torque inputs by using the disturbance observers are exerted into the robotic exoskeleton via feed-forward loops to counteract to the disturbances. Through such an approach, the system does not need any requirement of built-in torque sensing units. In order to validate the proposed framework, the extensive experiments are conducted on the upper limb exoskeleton using the state feedback and output feedback control to illustrate the performance the proposed approaches.

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Adaptive Neural Control of Uncertain MIMO Nonlinear Systems With State and Input Constraints

Chen

2017

IEEE Trans. Neural Netw. Learning Syst.

185

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An adaptive neural control strategy for multiple input multiple output nonlinear systems with various constraints is presented in this paper. To deal with the nonsymmetric input nonlinearity and the constrained states, the proposed adaptive neural control is combined with the backstepping method, radial basis function neural network, barrier Lyapunov function (BLF), and disturbance observer. By ensuring the boundedness of the BLF of the closed-loop system, it is demonstrated that the output tracking is achieved with all states remaining in the constraint sets and the general assumption on nonsingularity of unknown control coefficient matrices has been eliminated. The constructed adaptive neural control has been rigorously proved that it can guarantee the semiglobally uniformly ultimate boundedness of all signals in the closed-loop system. Finally, the simulation studies on a 2-DOF robotic manipulator system indicate that the designed adaptive control is effective.

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Disturbance Observer-Based Fuzzy Control of Uncertain MIMO Mechanical Systems With Input Nonlinearities and its Application to Robotic Exoskeleton

Chen

2017

IEEE Trans. Cybern.

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We develop a novel disturbance observer-based adaptive fuzzy control approach in this paper for a class of uncertain multi-input-multi-output mechanical systems possessing unknown input nonlinearities, i.e., deadzone and saturation and time-varying external disturbance. It is shown that the input nonlinearities can be represented by a nominal part and a nonlinear disturbance term. High-dimensional integral-type Lyapunov function is used to construct the controller. Fuzzy logic system is employed to cancel model uncertainties, and disturbance observer is also integrated into control design to compensate the fuzzy approximation error, external disturbance, and nonlinear disturbance caused by the unknown input nonlinearities. Semiglobally uniformly ultimately boundness of the closed-loop control system is guaranteed with tracking errors keeping bounded. Experimental studies on a robotic exoskeleton using the proposed control demonstrate the effectiveness of the approach.

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Direct adaptive controller for uncertain MIMO dynamic systems with time-varying delay and dead-zone inputs

Chen

et al. 2016

Automatica

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This paper presents an adaptive tracking control method for a class of nonlinearly parameterized MIMO dynamic systems with time-varying delay and unknown nonlinear dead-zone inputs. A new high dimensional integral Lyapunov-Krasovskii functional is introduced for the adaptive controller to guarantee global stability of the considered systems and also ensure convergence of the tracking errors to the origin. The proposed method provides an alternative to existing methods used for MIMO time-delay systems with dead-zone nonlinearities.

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Efficient production of a narrow-line erbium magneto-optical trap with two-stage slowing

Seo

Chen

et al. 2020

Phys. Rev. A

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Ziting Chen

Nonlinear Disturbance Observer-Based Control Design for a Robotic Exoskeleton Incorporating Fuzzy Approximation

Adaptive Neural Control of Uncertain MIMO Nonlinear Systems With State and Input Constraints

Disturbance Observer-Based Fuzzy Control of Uncertain MIMO Mechanical Systems With Input Nonlinearities and its Application to Robotic Exoskeleton

Direct adaptive controller for uncertain MIMO dynamic systems with time-varying delay and dead-zone inputs

Efficient production of a narrow-line erbium magneto-optical trap with two-stage slowing

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