Libration point orbit
Today, we want to dedicate a space to talk about Libration point orbit, a topic that has gained relevance in recent times. Libration point orbit is an issue that concerns us all, since it has a direct impact on our lives. Throughout this article, we will explore different aspects and perspectives related to Libration point orbit, with the aim of providing a comprehensive and complete vision on this topic. We will address its importance, its evolution over time, its implications in current society and its future projection. Without a doubt, Libration point orbit is a fascinating topic that invites us to reflect and analyze its influence on our personal and collective contexts.
In orbital mechanics, a libration point orbit (LPO) is a quasiperiodic orbit around a Lagrange point. Libration is a form of orbital motion exhibited, for example, in the Earth–Moon system. Trojan bodies also exhibit libration dynamics.
Two varieties of libration point orbits amenable to Lyapunov stability[clarification needed] are halo orbits and Lissajous orbits[1]
The James Webb Space Telescope (JWST) is in a libration point orbit around the L2 Lagrange point of the Sun, and Earth-Moon barycenters.[2][3] Because libration point orbits are quasiperiodic, the telescope must make frequent small burns to maintain proximity to the L2 point, as part of orbital station keeping, limiting the lifespan of the telescope due to depletion of fuel reserves.
Early simulations of the JWST obtained a high confidence in achieving a ten-year operational lifespan before station keeping becomes untenable.[3] However thanks to a highly accurate launch, it is now thought the telescope could keep its station for up to twenty or even twenty-five years. Some years of intermittent service after that might also be tenable, because of the slow drift rate out of, or in to, the Lagrange point.
References
- ^ Pergola, P. (21 October 2012). "Libration point orbit characterization in the Earth-Moon system". Monthly Notices of the Royal Astronomical Society. 426 (2): 1212–1222. Bibcode:2012MNRAS.426.1212P. doi:10.1111/j.1365-2966.2012.21585.x. S2CID 122979904.
- ^ Greenhouse, Matthew (October 2011). "The James Webb Space Telescope: Mission overview and status". 2011 2nd International Conference on Space Technology. pp. 1–4. doi:10.1109/ICSpT.2011.6064655. hdl:2060/20090026783. ISBN 978-1-4577-1874-8. S2CID 1957332. Retrieved 20 September 2022.
- ^ a b Dichmann, Donald J. (5 May 2014). "Stationkeeping Monte Carlo Simulation for the James Webb Space Telescope". International Symposium on Space Flight Dynamics Conference Proceeding. S2CID 51732847.
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