[en] Finding relative satellite orbits that guarantee long-term bounded relative motion is important for cluster flight, wherein a group of satellites remain within bounded distances while applying very few formationkeeping maneuvers. However, most existing astrodynamical approaches utilize mean orbital elements for detecting bounded relative orbits, and therefore cannot guarantee long-term boundedness under realistic gravitational models. The main purpose of the present paper is to develop analytical methods for designing long-term bounded relative orbits under high-order gravitational perturbations. The key underlying observation is that in the presence of arbitrarily high-order even zonal harmonics perturbations, the dynamics are superintegrable for equatorial orbits. When only J [SUB]2[/SUB] is considered, the current paper offers a closed-form solution for the relative motion in the equatorial plane using elliptic integrals. Moreover, necessary and sufficient periodicity conditions for the relative motion are determined. The proposed methodology for the J2-perturbed relative motion is then extended to non-equatorial orbits and to the case of any high-order even zonal harmonics ( J2n, n ≥ 1). Numerical simulations show how the suggested methodology can be implemented for designing bounded relative quasiperiodic orbits in the presence of the complete zonal part of the gravitational potential.
Disciplines :
Aerospace & aeronautics engineering
Author, co-author :
Martinusi, Vladimir ; Technion -- Israel Institute of Technology > Faculty of Aerospace Engineering > Distributed Space Systems Lab
Gurfil, Pini; Faculty of Aerospace Engineering, Technion—Israel Institute of Technology)
Language :
English
Title :
Solutions and periodicity of satellite relative motion under even zonal harmonics perturbations
scite shows how a scientific paper has been cited by providing the context of the citation, a classification describing whether it supports, mentions, or contrasts the cited claim, and a label indicating in which section the citation was made.
Bibliography
Abramowitz M., Stegun I. A.: Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables. Dover, New York (1964).
Alfriend K. T., Vadali S. R., GurfilP. How J. P., Breger L.: Spacecraft Formation Flying: Dynamics, Control and Navigation, Chaps. I, IV, V, VI and VII. Elsevier, Oxford (2010).
Arnold V. I., Kozlov V., Neishtadt A. I.: Mathematical Aspects of Classical and Celestial Mechanics. 3rd edn. Springer, Berlin (2006).
Battin R. H.: An Introduction to the Mathematics and Methods of Astrodynamics. AIAA, Reston (1999).
Ben-Ya'acov, U.: Laplace-Runge-Lenz symmetry in general rotationally symmetric systems. ArXiv e-prints (2010).
Brouwer D.: Solution of the problem of artificial satellite theory without drag. Astron. J. 64, 378-397 (1959).
Brouwer D., Clemence G. M.: Methods of Celestial Mechanics. Academic Press, New York (1961).
Brown, O., Eremenko, P.: Fractionated space architectures: a vision for responsive space. In: 4th Responsive Space Conference, Los Angeles, CA, (2006).
Calkin M. G.: Lagrangian and Hamiltonian mechanics. World Scientific, Singapore (1996).
Celletti A., Negrini P.: Non-integrability of the problem of motion around an oblate planet. Celest Mech Dyn Astron 61, 253-260 (1995).
Condurache, D.: New symbolic procedures in the study of the dynamical systems. Ph. D. Thesis, Technical University "Gheorghe Asachi", Iasi, Romania (1995).
Condurache D., Martinuşi V.: Relative spacecraft motion in a central force field. J. Guid. Control Dyn. 30(3), 873-876 (2007).
Condurache, D., Martinuşi, V.: Exact solution to the relative orbital motion in a central force field. In: 2nd International Symposium on Systems and Control in Aerospace and Astronautics, Shenzen, China, pp. 1-6. IEEE, China (2008).
Condurache D., Martinuşi V.: Foucault pendulum-like problems: a tensorial approach. Int. J. Non-linear Mech. 43(8), 743-760 (2008).
Condurache, D., Martinuşi, V.: Super-integrability in the unperturbed relative orbital motion problem. In: AIAA Guidance, Navigation, and Control Conference, Toronto, Canada, paper AIAA 2010-7669 (2010).
Gim D.-W., Alfriend K. T.: State transition matrix of relative motion for the perturbed noncircular reference orbit. J. Guid. Control Dyn. 26(6), 956-971 (2003).
Gim D.-W., Alfriend K. T.: Satellite relative motion using differential equinoctial elements. Celest. Mech. Dyn. Astron. 92(4), 295-336 (2005).
Gurfil P.: Relative motion between elliptic orbits: generalized boundedness conditions and optimal formationkeeping. J. Guid. Control Dyn. 28(4), 761-767 (2005).
Gurfil P., Kholshevnikov K. V.: Manifolds and metrics in the relative spacecraft motion problem. J. Guid. Control Dyn. 29(4), 1004-1010 (2006).
Hamel J. F., de Lafontaine J.: Linearized dynamics of formation flying spacecraft on a J2-perturbed elliptical orbit. J. Guid. Control Dyn. 30(6), 1649-1658 (2007).
Irigoyen M., Simo C.: Nonintegrability of the J2 problem. Celest. Mech. Dyn. Astron. 55, 281-287 (1993).
Jezewski D. J.: An analytic solution for the J2 perturbed equatorial orbit. Celest. Mech. 30, 363-371 (1983).
Kasdin N. J., Gurfil P., Kolemen E.: Canonical modelling of relative spacecraft motion via epicyclic orbital elements. Celest. Mech. Dyn. Astron. 92(4), 337-370 (2005).
Leach P. G. L., Flessas G. P.: Generalisations of the Laplace-Runge-Lenz vector. J. Nonlinear Math. Phys. 10(3), 340-423 (2003).
Ross I. M.: Linearized dynamic equations for spacecraft subject to J2 perturbations. J. Guid. Control Dyn. 26(4), 657-659 (2003).
Schaub H., Alfriend K. T.: J2 invariant relative orbits for spacecraft formations. Celest. Mech. Dyn. Astron. 79(2), 77-95 (2001).
Schaub H., Junkins J. L.: Analytical Mechanics of Space Systems. 2nd edn. AIAA Education Series, Reston (2009).
Schweighart S. A., Sedwick R. J.: High-fidelity linearized J2 model for satellite formation flight. J. Guid. Control Dyn. 25(6), 1073-1080 (2002).
Sengupta P., Vadali S. R., Alfriend K. T.: Second-order state transition for relative motion near perturbed, elliptic orbits. Celest. Mech. Dyn. Astron. 97(2), 101-129 (2007).
Uldall Kristiansen K., Palmer P. L., Roberts M.: Relative motion of satellites exploiting the super-integrability of Kepler's problem. Celest. Mech. Dyn. Astron. 106(4), 371-390 (2009).
Vadali, S. R.: An analytical solution for relative motion of satellites. In: 5th Dynamics and Control of Systems and Structures in Space Conference, Cranfield, UK, Cranfield University (2002).
Vallado D. A.: Fundamentals of Astrodynamics and Applications. 2nd edn. Microcosm, USA (2001).
Wiesel W. E.: Relative satellite motion about an oblate planet. J. Guid. Control Dyn. 25(4), 776-785 (2002).
Similar publications
Sorry the service is unavailable at the moment. Please try again later.
This website uses cookies to improve user experience. Read more
Save & Close
Accept all
Decline all
Show detailsHide details
Cookie declaration
About cookies
Strictly necessary
Performance
Strictly necessary cookies allow core website functionality such as user login and account management. The website cannot be used properly without strictly necessary cookies.
This cookie is used by Cookie-Script.com service to remember visitor cookie consent preferences. It is necessary for Cookie-Script.com cookie banner to work properly.
Performance cookies are used to see how visitors use the website, eg. analytics cookies. Those cookies cannot be used to directly identify a certain visitor.
Used to store the attribution information, the referrer initially used to visit the website
Cookies are small text files that are placed on your computer by websites that you visit. Websites use cookies to help users navigate efficiently and perform certain functions. Cookies that are required for the website to operate properly are allowed to be set without your permission. All other cookies need to be approved before they can be set in the browser.
You can change your consent to cookie usage at any time on our Privacy Policy page.
