Your search keyword '"Jia, Yinghong"' showing total 4 results

1. Dynamics of flexible multibody systems with variable-speed control moment gyroscopes.

Author

Feng, Xiao, Jia, Yinghong, and Xu, Shijie

Subjects

*GYROSCOPES, *MULTIBODY systems, *EULER equations, *INERTIA (Mechanics), *AXIAL flow

Abstract

This paper presents a generic global matrix formulation for the dynamics of flexible multibody systems with variable-speed control moment gyroscopes (VSCMGs). The flexible bodies are assumed to exhibit only small deformation, and they are connected in a tree topology by hinges permitting large rotation and translation. A cluster of VSCMGs is mounted on each body for actuation; it is assumed that the VSCMGs are statically and dynamically balanced, and their rotors are axisymmetric. A minimum set of dynamic equations are derived systematically via a mixed use of Kane's method and Newton–Euler equations. The parameters of each flexible body are augmented to take into account the inertias of the attached VSCMGs. Moreover, a skew-symmetric gyroscopic matrix and three control-input-mapping matrices are defined to represent the passive and the active gyroscopic torques of the VSCMGs in a global matrix manner. Three examples are given to show the usefulness, versatility, and correctness of the proposed formulation. As an additional contribution, also presented are linear dynamic equations for a spacecraft with flexible appendages and embedded VSCMGs. [ABSTRACT FROM AUTHOR]

Published

2018

2. Maneuver and Active Vibration Suppression of Free-Flying Space Robot.

Author

Jia, Shiyuan, Jia, Yinghong, Xu, Shijie, and Hu, Quan

Subjects

*AERODYNAMICS, *ACTUATORS, *COMPUTER simulation, *SINGULAR perturbation stability, *GYROSCOPES

Abstract

This work studies the maneuver control and vibration suppression of a flexible free-flying space robot using variable-speed control moment gyros as actuators. A novel flexible space manipulator is designed. The dynamics of the flexible multibody system is derived by using Kane method. Based on the singular perturbation approach, the dynamics of the flexible manipulator is decoupled into a slow subsystem and a fast subsystem. The slow subsystem is associated with the rigid motion dynamics, and the fast subsystem is related to the link flexible dynamics. A composite control strategy is proposed as a combination of two controllers for these subsystems. An adaptive sliding mode controller is designed for the slow subsystem, and an adaptive controller is designed for the fast subsystem. Uncertainty estimation can be achieved by the adaptive terms of the composite controller. A weighted robust pseudo-inverse steering law is proposed for the variable-speed control moment gyros. Numerical results demonstrate that the proposed composite controller is robust to parameter uncertainties and external disturbances. [ABSTRACT FROM AUTHOR]

Published

2018

3. Robust trajectory tracking control of a dual-arm space robot actuated by control moment gyroscopes.

Author

Jia, Yinghong and Misra, Arun K.

Subjects

*SPACE robotics, *GYROSCOPES, *TRACKING control systems, *LYAPUNOV stability, *ANGULAR momentum (Mechanics)

Abstract

It is a new design concept to employ control moment gyroscopes (CMGs) as reactionless actuators for space robots. Such actuation has several noticeable advantages such as weak dynamical coupling and low power consumption over traditional joint motor actuation. This paper presents a robust control law for a CMG-actuated space robot in presence of system uncertainties and closed-chain constraints. The control objective is to make the manipulation variables to track the desired trajectories, and reduce the possibility of CMG saturation simultaneously. A reduced-order dynamical equation in terms of independent motion variables is derived using Kane's equations. Desired trajectories of the independent motion variables are derived by minimum-norm trajectory planning algorithm, and an adaptive sliding mode controller with improved adaptation laws is proposed to drive the independent motion variables tracking the desired trajectories. Uniformly ultimate boundedness of the closed loop system is proven using Lyapunov method. The redundancy of the full-order actual control torques is utilized to generate a null torque vector which reduces the possibility of CMG angular momentum saturation while producing no effect on the reduced-order control input. Simulation results demonstrate the effectiveness of the proposed algorithms and the advantage of weak dynamical coupling of the CMG-actuated system. [ABSTRACT FROM AUTHOR]

Published

2017

4. Dynamics and vibration suppression of space structures with control moment gyroscopes.

Author

Hu, Quan, Jia, Yinghong, and Xu, Shijie

Subjects

*GYROSCOPES, *DYNAMICS, *VIBRATION (Aeronautics), *SPACE frame structures, *CONTROL theory (Engineering), *EQUATIONS of motion

Abstract

Abstract: This paper presents a new and effective approach for vibration suppression of large space structures. Collocated pairs of control moment gyroscope (CMG) and angular rate sensor are adopted as actuators/sensors. The equations of motion of a flexible structure with a set of arbitrarily distributed CMGs are developed. The detailed dynamics of the CMGs and their interactions between the flexibilities of the structure are incorporated in the formulation. Then, the equations of motion are linearized to describe the small-scale motion of the system. The optimal placement problem of the actuators/sensors on the flexible structures is solved from the perspective of system controllability and observability. The controller for the vibration suppression is synthesized using the angular rates of the locations where the CMGs are mounted and the gimbal angles of the CMGs. The stability of the controller is proved by the Lyapunov theorem. Numerical examples of a beam structure and a plate structure validate the efficacy of the proposed method. [Copyright &y& Elsevier]

Published

2014