论文信息 - Feasibility for Orbital Life Extension of a CubeSat in the Lower Thermosphere

Feasibility for Orbital Life Extension of a CubeSat in the Lower Thermosphere

Orbital flight of CubeSats at altitudes between 150 and 250 km has the potential to enable a new class of scientific, commercial, and defense-related missions. A study is presented to demonstrate the feasibility of extending the orbital lifetime of a CubeSat in a 210 km orbit. Propulsion consists of an electrospray thruster operating at a 2 W, 0.175 mN thrust, and an specific impulse (Isp) of 500 s. The mission consists of two phases. In phase 1, the CubeSat is deployed from a 414 km orbit and uses the thruster to deorbit to the target altitude of 210 km. In phase 2, the propulsion system is used to extend the mission lifetime until propellant is fully expended. A control algorithm based on maintaining a target orbital energy is presented that uses an extended Kalman filter to generate estimates of the orbital dynamic state, which are periodically updated by Global Positioning System measurements. For phase 1, the spacecraft requires 25.21 days to descend from 414 to 210 km, corresponding to a ΔV=96.25 m...

[1] John Conklin,et al. Three-Axis Drag-Free Control and Drag Force Recovery of a Single-Thruster Small Satellite , 2015 .

[2] Rune Floberghagen,et al. VII: CLOSING SESSION: GOCE: ESA's First Earth Explorer Core Mission , 2003 .

[3] John Conklin,et al. Measurement of drag and its cancellation , 2011 .

[4] D. Vallado. Fundamentals of Astrodynamics and Applications , 1997 .

[5] John L. Crassidis,et al. Fundamentals of Spacecraft Attitude Determination and Control , 2014 .

[6] A. Hedin. Extension of the MSIS Thermosphere Model into the middle and lower atmosphere , 1991 .

[7] Michael A. Demetriou,et al. Electric Propulsion and Controller Design for Drag-Free Spacecraft Operation , 2008 .

[8] John L. Crassidis,et al. Static Attitude Determination Methods , 2014 .

[9] Kenneth Moe,et al. Gas-surface interactions and satellite drag coefficients , 2005 .

[10] John Ziemer,et al. Colloid micro-Newton thruster development for the ST7-DRS and LISA missions , 2005 .

[11] Ryan W. Conversano,et al. Mission Capability Assessment of CubeSats Using a Miniature Ion Thruster , 2013 .

[12] J. Schofield,et al. Observing Earth's atmosphere with radio occultation measurements using the Global Positioning System , 1997 .