Title :
Magnetic control of tethered cube-satellite stabilized by rotating
Author :
Keshtkar, Sajjad ; Poznyak, Alexander ; Keshtkar, Najmeh
Author_Institution :
Dept. of Autom. Control, CINVESTAV - IPN, Mexico City, Mexico
fDate :
Sept. 29 2014-Oct. 3 2014
Abstract :
Active magnetic control have been used to develop the rotating stabilization of tethered nano-satellites. It uses magnetic control to stabilize the orbit position by controlling angular velocity of rotating TCS. The system uses Earth´s magnetic field as energy source to interact with a long conductive tether and consecutively reach the rotational stability on Low Earth Orbit (LEO). The mathematical model and control design describing orbiting system for two connected cube-satellites with a 1-km-length tether have been studied. The adaptive version of sliding mode control was used to control the system in presence of unmodelled dynamics and perturbations. The performance of this system has been investigated via simulation.
Keywords :
Earth; angular velocity control; artificial satellites; control system synthesis; magnetic variables control; perturbation techniques; position control; space tethers; stability; variable structure systems; Earth magnetic field; LEO; Low Earth Orbit; active magnetic control; angular velocity control; conductive tether; control design; energy source; mathematical model; orbit position stabilization; rotational stability; sliding mode control; tethered cube-satellite magnetic control; tethered nanosatellite rotating stabilization; unmodelled dynamics; Aerospace electronics; Angular velocity; Earth; Mathematical model; Orbits; Satellites; Space vehicles; Cube Satellite; Sliding mode; Space Tether;
Conference_Titel :
Electrical Engineering, Computing Science and Automatic Control (CCE), 2014 11th International Conference on
Conference_Location :
Campeche
Print_ISBN :
978-1-4799-6228-0
DOI :
10.1109/ICEEE.2014.6978291
