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Artificial frozen orbit control scheme based on J_2 perturbation 被引量:4

Artificial frozen orbit control scheme based on J_2 perturbation
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摘要 Since the inclination of frozen orbit with non-rotation of the perigee that occurs due to J2 perturbation must be equal to the critical inclination, this regulation has restricted the application of frozen orbit a lot. In this paper, we propose two control strategies to eliminate the secular growth of the argument of the perigee for orbits that are not at the critical inclination. One control strategy is using transverse continuous low-thrust, and the other is using both the transverse and the radial continuous low-thrusts. Fuel optimization in the second control strategy is addressed to make sure that the fuel consumption is the minimum. Both strategies have no effect on other orbital parameters’ secular motion. It is proved that the strategy with transverse control could save more energy than the one with radial control. Simulations show that the second control strategy could save 54.6% and 86% of energy, respectively, compared with the two methods presented in the references. Since the inclination of frozen orbit with non-rotation of the perigee that occurs due to J2 perturbation must be equal to the critical inclination, this regulation has restricted the application of frozen orbit a lot. In this paper, we propose two control strategies to eliminate the secular growth of the argument of the perigee for orbits that are not at the critical inclination. One control strategy is using transverse continuous low-thrust, and the other is using both the transverse and the radial continuous low-thrusts. Fuel optimization in the second control strategy is addressed to make sure that the fuel consumption is the minimum. Both strategies have no effect on other orbital parameters’ secular motion. It is proved that the strategy with transverse control could save more energy than the one with radial control. Simulations show that the second control strategy could save 54.6% and 86% of energy, respectively, compared with the two methods presented in the references.
出处 《Science China(Technological Sciences)》 SCIE EI CAS 2010年第11期3138-3144,共7页 中国科学(技术科学英文版)
基金 supported by the National Natural Science Foundation of China (Grant No 10702078) the Research Foundation of National University of Defense Technology (Grant No JC08-01-05)
关键词 continuous low-thrust artificial frozen orbit Gauss’variation of parameters equations mean element method continuous low-thrust artificial frozen orbit Gauss’ variation of parameters equations mean element method
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  • 1边炳秀.卫星推进系统的历史、现状和未来[J].控制工程(北京),2001(5):28-39. 被引量:5
  • 2杨维廉.临界倾角与冻结轨道[J].宇航学报,1993,14(3):1-9. 被引量:3
  • 3吴汉基.脉冲等离子体电火箭在卫星控制方面的应用[J].电工电能新技术,1986,(3):27-33.
  • 4[3]R M Myers,S R Oleson,Melissa Mcguire,et al.Pulsed plasma thruster technology for small satellite missions[C].In:Proc.of the 9th annual AIAA/USU Conf.of small satellite,1995.
  • 5[4]Gregory G,Spanjers,Daron R,Bromaghim,et al.AFRL MicroPPT development for small spacecraft propulsion[R].AIAA 2002-3974.
  • 6Cook G E. Peturbations of Near- Circular Orbit by Earth's Gravitational Potential, Planet. Space Sci. , 1966(14) :433 -444.
  • 7Cutting E, Born G H, Frautnick J C. Orbit analysis for SEASAT-A [J]. Journal of the Astronautical Sciences, 1978, 26(4) : 315 - 342.
  • 8Janson S W. The on-orbit role of electric propulsion[C]. AIAA 1993 - 2220.
  • 9Yan Q, Kapila V. Analysis and control of satellite orbits around oblate earth using perturbation method [ C ]. Proceedings of the 40th IEEE Conference on Decision and Control, IEEE, Orlando, FL, 2001,2: 1517- 1522.
  • 10Christopher C, Wilkins and Vikram Kapila. Eliminating perigee rotation in J2 perturbed orbits with a constant radial acceleration [ C ]. AIAA 2007 - 6844.

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