Receding Horizon Control on Steering of Control Moment Gyro for Fast Attitude Maneuver

The problem of steering pyramid control moment gyro (CMG) cluster for fast spacecraft attitude maneuver along eigenaxis is investigated. A novel steering law is proposed to continuously attempt to reduce the difference between the current gimbal angle and the desired one corresponding to the angular momentum envelop of the CMG cluster. The proposed steering law can be decomposed into two parts: the first one is a singularity robust term to keep maneuverability and produce control torque, and the other is a null motion term to rearrange the gimbal angles toward momentum envelope. By involving this steering law, it is expected to possess both rapid angular momentum exchange and singularity avoidance ability. In addition, by introducing a new limit vector on attitude error, classical cascade-saturation control algorithm is revised to guarantee spacecraft eigenaxis rotation. Both open-loop steering law test and closed-loop attitude maneuver simulations are performed to evaluate the efficacy of the proposed methods.

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3221 Receding Horizon Control on Steering of Control Momentum Gyro for Fast Attitude Maneuver

The Proceedings of the Symposium on the Motion and Vibration Control ◽

10.1299/jsmemovic.2007.10.383 ◽

2007 ◽

Vol 2007.10 (0) ◽

pp. 383-387

Author(s):

Kohei TAKADA ◽

Hirohisa KOJIMA

Keyword(s):

Receding Horizon Control ◽

Receding Horizon ◽

Attitude Maneuver

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Comparing fluid ring and CMG servomechanisms for active control of rigid satellites

Aircraft Engineering and Aerospace Technology ◽

10.1108/aeat-01-2017-0039 ◽

2018 ◽

Vol 90 (6) ◽

pp. 896-905 ◽

Cited By ~ 2

Author(s):

Saleh Akbaritabar ◽

Reza Esmaelzadeh ◽

Reza Zardashti

Keyword(s):

Attitude Control ◽

Design Methodology ◽

Torque Control ◽

Performance Parameters ◽

Attitude Control System ◽

Content Type ◽

Control Moment ◽

Attitude Maneuver ◽

Control Moment Gyro ◽

Practical Implications

Purpose This paper aims to describe a novel type of attitude control system (ACS) in different configurations. This servomechanism is compared with control moment gyro (CMG) in significant parameters of performance for ACS of rigid satellite. Design/methodology/approach This new actuator is the fluid containing one or more rings and fluid flow is supplied by pump. The required torque control is obtained by managing fluid angular velocity. The cube-shaped satellite with three rings of fluid in the principle axes is considered for modeling. The satellite is considered rigid and nonlinear dynamics equation is used for it. In addition, the failure of the pyramid-shaped satellite with an additional ring fluid is discussed. Findings The controller model for four fluid rings has more complexity than for three fluid rings. The simulation results illustrated that four fluid rings need less energy for stabilization than three fluid rings. The performance of this type of actuator is compared with CMG. At last, it is demonstrated that performance parameters are improved with fluid ring actuator. Research limitations/implications Fluid ring actuator can be affected by environmental pressure and temperature. Therefore, freezing and boiling temperature of the fluid should be considered in system designation. Practical implications Fluid ring servomechanism can be used as ACS in rigid satellites. This actuator is compared by CMG, the prevalent actuator. It has less displacement attitude maneuver. Originality/value The results provide the feasibility and advantages of using fluid rings as satellite ACS. The quaternion error controller is used for this model to enhance its performance.

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