Showing total 6 results

1. Sliding mode control for autonomous spacecraft rendezvous with collision avoidance.

Author

Li, Qi, Yuan, Jianping, and Wang, Huan

Subjects

*SPACE vehicles, *SPACE flight, *SPACE probes, *COMPUTER simulation, *LYAPUNOV stability, *LYAPUNOV functions

Abstract

Abstract This paper studies the relative position tracking and attitude synchronization problem of spacecraft rendezvous with the requirement of collision avoidance. To achieve the implementation of the rendezvous procedure, the docking port of the chaser is required to direct towards the counterpart of the target, while the relative distance between the two spacecraft should be larger than the radius of the danger zone during close proximity phase. In order to address the concerned problem, a novel sliding mode control strategy based on artificial potential function is developed, and more specifically, the sliding manifold of the close-loop system is chosen along the negative gradient of the artificial potential function. Within the Lyapunov framework, the proposed control laws are proved to guarantee the convergence of relative position and attitude errors while avoiding any accidental collision between the two spacecraft, even in the presence of external disturbance. Numerical simulations are carried out to demonstrate the effectiveness of the designed control laws. Highlights • Nonlinear relative pose control for spacecraft proximity operation with the requirement of collision avoidance is presented. • State feedback control laws are developed by employing artificial potential field and sliding mode technique. • A 6DOF simulation example is carried out to demonstrate the excellent performance of the proposed control laws. [ABSTRACT FROM AUTHOR]

Published

2018

2. Experiments study on attitude coupling control method for flexible spacecraft.

Author

Wang, Jie and Li, Dongxu

Subjects

*COUPLING agents (Chemistry), *SPACE vehicles, *SPACE exploration, *VIBRATION (Aeronautics), *COMPUTER simulation

Abstract

High pointing accuracy and stabilization are significant for spacecrafts to carry out Earth observing, laser communication and space exploration missions. However, when a spacecraft undergoes large angle maneuver, the excited elastic oscillation of flexible appendages, for instance, solar wing and onboard antenna, would downgrade the performance of the spacecraft platform. This paper proposes a coupling control method, which synthesizes the adaptive sliding mode controller and the positive position feedback (PPF) controller, to control the attitude and suppress the elastic vibration simultaneously. Because of its prominent performance for attitude tracking and stabilization, the proposed method is capable of slewing the flexible spacecraft with a large angle. Also, the method is robust to parametric uncertainties of the spacecraft model. Numerical simulations are carried out with a hub-plate system which undergoes a single-axis attitude maneuver. An attitude control testbed for the flexible spacecraft is established and experiments are conducted to validate the coupling control method. Both numerical and experimental results demonstrate that the method discussed above can effectively decrease the stabilization time and improve the attitude accuracy of the flexible spacecraft. [ABSTRACT FROM AUTHOR]

Published

2018

3. Robust coordinated control of a dual-arm space robot.

Author

Shi, Lingling, Kayastha, Sharmila, and Katupitiya, Jay

Subjects

*SPACE robotics, *ROBOTS, *SPACE vehicles, *NONLINEAR statistical models, *COMPUTER simulation

Abstract

Dual-arm space robots are more capable of implementing complex space tasks compared with single arm space robots. However, the dynamic coupling between the arms and the base will have a serious impact on the spacecraft attitude and the hand motion of each arm. Instead of considering one arm as the mission arm and the other as the balance arm, in this work two arms of the space robot perform as mission arms aimed at accomplishing secure capture of a floating target. The paper investigates coordinated control of the base's attitude and the arms' motion in the task space in the presence of system uncertainties. Two types of controllers, i.e. a Sliding Mode Controller (SMC) and a nonlinear Model Predictive Controller (MPC) are verified and compared with a conventional Computed-Torque Controller (CTC) through numerical simulations in terms of control accuracy and system robustness. Both controllers eliminate the need to linearly parameterize the dynamic equations. The MPC has been shown to achieve performance with higher accuracy than CTC and SMC in the absence of system uncertainties under the condition that they consume comparable energy. When the system uncertainties are included, SMC and CTC present advantageous robustness than MPC. Specifically, in a case where system inertia increases, SMC delivers higher accuracy than CTC and costs the least amount of energy. [ABSTRACT FROM AUTHOR]

Published

2017

4. Robust stationkeeping and reconfiguration of underactuated spacecraft formations.

Author

Godard, null, Dev Kumar, Krishna, and Zou, Anmin

Subjects

*SPACE vehicles, *AUTOMATIC control systems, *LINEAR dynamical systems, *EIGENVALUES, *COMPUTER simulation, *NONLINEAR theories

Abstract

Feasibility of achieving reliable control for spacecraft formation keeping and reconfiguration without the need for thrust in either the radial or along-track direction is explored in this paper. Analysis of the linearized dynamics without along-track input indicates the presence of an uncontrollable eigenvalue at the origin. A nonlinear controller is designed to indirectly stabilize the uncontrollable modes to a stable manifold around the equilibrium. Conditions for robustness against unmatched uncertainties and disturbances are derived to establish the regions of asymptotic stabilization. The benefits of the proposed control method are also validated via numerical simulations to show that precise formation maintenance can be achieved by dealing with the issues of system nonlinearities, variations in initial conditions, and external disturbances, concurrently. [ABSTRACT FROM AUTHOR]

Published

2014

5. Distributed attitude synchronization of formation flying via consensus-based virtual structure

Author

Cong, Bing-Long, Liu, Xiang-Dong, and Chen, Zhen

Subjects

*ARTIFICIAL satellite attitude control systems, *SPACE vehicles, *COMPUTER simulation, *REDUNDANCY in engineering, *SYNCHRONIZATION, *ROBUST control, *ALGORITHMS, *SLIDING mode control, *UNCERTAINTY (Information theory)

Abstract

Abstract: This paper presents a general framework for synchronized multiple spacecraft rotations via consensus-based virtual structure. In this framework, attitude control systems for formation spacecrafts and virtual structure are designed separately. Both parametric uncertainty and external disturbance are taken into account. A time-varying sliding mode control (TVSMC) algorithm is designed to improve the robustness of the actual attitude control system. As for the virtual attitude control system, a behavioral consensus algorithm is presented to accomplish the attitude maneuver of the entire formation and guarantee a consistent attitude among the local virtual structure counterparts during the attitude maneuver. A multiple virtual sub-structures (MVSSs) system is introduced to enhance current virtual structure scheme when large amounts of spacecrafts are involved in the formation. The attitude of spacecraft is represented by modified Rodrigues parameter (MRP) for its non-redundancy. Finally, a numerical simulation with three synchronization situations is employed to illustrate the effectiveness of the proposed strategy. [Copyright &y& Elsevier]

Published

2011

6. Sliding mode attitude control with L2-gain performance and vibration reduction of flexible spacecraft with actuator dynamics

Author

Hu, Qinglei

Subjects

*ARTIFICIAL satellite attitude control systems, *SLIDING mode control, *SPACE vehicles, *VIBRATION (Aeronautics), *PIEZOELECTRIC materials, *UNCERTAINTY (Information theory), *COMPUTER simulation

Abstract

Abstract: This paper presents a dual-stage control system design method for the rotational maneuver control and vibration stabilization of a flexible spacecraft. In this design approach, the sub-systems of attitude control and vibration suppression are designed separately using the low order model. Based on the sliding mode control (SMC) theory, a discontinuous attitude control law in the form of the input voltage of the reaction wheel is derived to control the orientation of the spacecraft, incorporating the L2-gain performance criterion constraint. The resulting closed-loop system is proven to be uniformly ultimately bounded stability and the effect of the external disturbance on both attitude quaternion and angular velocity can be attenuated to the prescribed level as well. In addition, an adaptive version of the control law is designed for adapting the unknown upper bounds of the lumped disturbance such that the limitation of knowing the bound of the disturbance in advance is released. For actively suppressing the induced vibration, strain rate feedback control method is also investigated by using piezoelectric materials as additional sensors and actuators bonded on the surface of the flexible appendages. Numerical simulations are performed to show that rotational maneuver and vibration suppression are accomplished in spite of the presence of disturbance and uncertainty. [Copyright &y& Elsevier]

Published

2010