Earth–Moon transfer via the L1 Lagrangian point using the theory of functional connections

1. Witze, A. Lift off! Artemis Moon rocket launch kicks off new era of human exploration. Nature, 2022, 611(7937): 643–644.

   Article  Google Scholar 

2. Takan, A. H., Yue, B. Z. Seizing the opportunity: Partnering with China’s international lunar research station (ILRS) and deep space exploration projects for mutual collaboration and scientific advancement. In: Proceedings of the 2nd International Conference on Mechanical System Dynamics. Lecture Notes in Mechanical Engineering. Rui, X. T., et al. Eds. Springer Singapore, 2024: 3933–3942.

   Chapter  Google Scholar 

3. Wu, W. R., Li, C. L., Zuo, W., Zhang, H. B., Liu, J. J., Wen, W. B., Su, Y., Ren, X., Yan, J., Yu, D. Y., et al. Lunar farside to be explored by Chang’e-4. Nature Geoscience, 2019, 12(4): 222–223.

   Article  Google Scholar 

4. Padma, T. V. India lands on the Moon! Scientists celebrate as Chandrayaan-3 touches down. Nature, 2023, 620(7976): 927–928.

   Article  Google Scholar 

5. Yamauchi, D., Nosé, M., Harada, Y., Yamamoto, K., Keika, K., Nagamatsu, A., Yokota, S., Saito, Y., Glocer, A. Terrestrial-origin O⁺ ions below 1 keV near the Moon measured with the Kaguya satellite. Earth Planets Space, 2024, 76: 162.

   Article  Google Scholar 

6. Turchinskaya, O. I., Slyuta, E. N. Landing site choice for Luna-27 mission in the Moon south polar region. Acta Astronautica, 2024, 222: 346–358.

   Article  Google Scholar 

7. Jo, W., Garrick-Bethell, I., Jin, H., Fatemi, S., Poppe, A. R., Park, H. H., Kim, K. H. Measurement of lunar induced fields on the lunar farside using KPLO and Artemis. In: Proceedings of the 55th Lunar and Planetary Science Conference, 2024: 1779.

   Google Scholar 

8. Almarzooqi, H., Almatroushi, H., Els, S. G., Almaeeni, S., Alzaabi, M. Emirates lunar mission past, present, and future. In: Proceedings of the Annual Meeting of the Lunar Exploration Analysis Group, 2024: 5070.

   Google Scholar 

9. Fuller, S., Lehnhardt, E., Zaid, C., Halloran, K. Gateway program status and overview. Journal of Space Safety Engineering, 2022, 9(4): 625–628.

   Article  Google Scholar 

10. Hu, T., Yang, Z., Li, M., van der Bogert, C. H., Kang, Z. Z., Xu, X. J., Hiesinger, H. Possible sites for a Chinese international lunar research station in the lunar south polar region. Planetary and Space Science, 2023, 227: 105623.

    Article  Google Scholar 

11. Koon, W. S., Lo, M. W., Marsden, J. E., Ross, S. D. Dynamical systems, the three-body problem and space mission design. In: International Conference on Differential Equations. Fiedler, B., et al. Eds. World Scientific, 2000: 1167–1181.

    Google Scholar 

12. Santos, L. B. T., Sousa-Silva, P. A., Terra, M. O., Mani, K. V., de Almeida Jr., A. K., Sanchez, D. M., Prado, A. F. B. A. Optimal transfers from Moon to L₂ halo orbit of the Earth–Moon system. Advances in Space Research, 2022, 70(11): 3362–3372.

    Article  Google Scholar 

13. Henry, D. B., Scheeres, D. J. Fully numerical computation of heteroclinic connection families in the spatial three-body problem. Communications in Nonlinear Science and Numerical Simulation, 2024, 130: 107780.

    Article  MathSciNet  Google Scholar 

14. Topputo, F., Vasile, M., Bernelli-Zazzera, F. Earth-to-Moon low energy transfers targeting L₁ hyperbolic transit orbits. Annals of the New York Academy of Sciences, 2005, 1065(1): 55–76.

    Article  Google Scholar 

15. Leake, C., Johnson, H. R., Mortari, D. The Theory of Functional Connections: A Functional Interpolation Framework with Applications. Morrisville, NC, USA: Lulu, 2022.

    Google Scholar 

16. Leake, C., Johnston, H., Smith, L., Mortari, D. Analytically embedding differential equation constraints into least squares support vector machines using the theory of functional connections. Machine Learning and Knowledge Extraction, 2019, 1(4): 1058–1083.

    Article  Google Scholar 

17. Leake, C., Johnston, H., Mortari, D. The multivariate theory of functional connections: Theory, proofs, and application in partial differential equations. Mathematics, 2020, 8(8): 1303.

    Article  Google Scholar 

18. Johnston, H., Schiassi, E., Furfaro, R., Mortari, D. Fuel-efficient powered descent guidance on large planetary bodies via theory of functional connections. The Journal of the Astronautical Sciences, 2020, 67(4): 1521–1552.

    Article  Google Scholar 

19. Li, S. Y., Yan, Y. S., Zhang, K., Li, X. G. Fuel-optimal ascent trajectory problem for launch vehicle via theory of functional connections. International Journal of Aerospace Engineering, 2021, 2021: 2734230.

    Article  Google Scholar 

20. Schiassi, E., De Florio, M., Ganapol, B. D., Picca, P., Furfaro, R. Physics-informed neural networks for the point kinetics equations for nuclear reactor dynamics. Annals of Nuclear Energy, 2022, 167: 108833.

    Article  Google Scholar 

21. Daryakenari, N. A., De Florio, M., Shukla, K., Karniadakis, G. E. AI-Aristotle: A physics-informed framework for systems biology gray-box identification. PLoS Computational Biology, 2024, 20(3): e1011916.

    Article  Google Scholar 

22. Mortari, D. Using the theory of functional connections to solve boundary value geodesic problems. Mathematical and Computational Applications, 2022, 27(4): 64.

    Article  Google Scholar 

23. De Almeida Jr., A. K., Aljbaae, S., Vaillant, T., Piñeros, J. M., Coelho, B., Barbosa, D., Bergano, M., Pandeirada, J., Carvalho, F. C., Santos, L. B. T., et al. Theory of functional connections and Nelder–Mead optimization methods applied in satellite characterization. Acta Astronautica, 2024, 215: 548–559.

    Article  Google Scholar 

24. De Almeida Jr., A. K., Prado, A. F. B. A., Mortari, D. Using the theory of functional connections to create periodic orbits with a linear variable thrust. New Astronomy, 2023, 104: 102068.

    Article  Google Scholar 

25. De Almeida Jr., A. K., Vaillant, T., Santos, L. B. T., Maia, D. Low-thrust transfer with Theory of Functional Connections: Application to 243 Ida with a solar sail. Advances in Space Research, 2025, 75(2): 2108–2125.

    Article  Google Scholar 

26. De Almeida Jr., A. K., Prado, A. F. B. A., Mortari, D. Orbit transfer using Theory of Functional Connections via change of variables. The European Physical Journal Special Topics, 2023, 232(18–19): 3161–3173.

    Article  Google Scholar 

27. De Almeida Jr., A. K., Johnston, H., Leake, C., Mortari, D. Fast 2-impulse non-Keplerian orbit transfer using the Theory of Functional Connections. The European Physical Journal Plus, 2021, 136(2): 223.

    Article  Google Scholar 

28. De Almeida Jr., A. K., Vaillant, T., de Oliveira, V. M., Barbosa, D., Maia, D., Aljbaae, S., Coelho, B., Bergano, M., Pandeirada, J., Prado, A. F. B. A., et al. Tangential velocity constraint for orbital maneuvers with Theory of Functional Connections. Scientific Reports, 2024, 14: 7479.

    Article  Google Scholar 

29. Qi, Y., de Ruiter, A. Transfers to lunar libration point orbits. Communications in Nonlinear Science and Numerical Simulation, 2019, 74: 180–200.

    Article  MathSciNet  Google Scholar 

30. Symon, K. R. Mechanics. Addison-Wesley Inc., 1953.

    Google Scholar 

31. Szebehely, V. Theory of Orbits: The Restricted Problem of Three Bodies. New York: Academic Press, 1967.

    Google Scholar 

32. Mingotti, G., Topputo, F., Bernelli-Zazzera, F. Optimal low-thrust invariant manifold trajectories via attainable sets. Journal of Guidance, Control, and Dynamics, 2011, 34(6): 1644–1656.

    Article  Google Scholar 

33. Santos, L. B. T., de Almeida Jr., A. K., Sousa-Silva, P. A., Terra, M. O., Sanchez, D. M., Aljbaae, S., Prado, A. F. B. A., Monteiro, F. Numerical investigations of the orbital dynamics around a synchronous binary system of asteroids. arXiv preprint, 2023, arXiv: 2307.09658.

34. Jorba, À., Masdemont, J. Dynamics in the center manifold of the collinear points of the restricted three body problem. Physica D: Nonlinear Phenomena, 1999, 132(1–2): 189–213.

    Article  MathSciNet  Google Scholar 

35. Gómez, G., Mondelo, J. M. The dynamics around the collinear equilibrium points of the RTBP. Physica D: Nonlinear Phenomena, 2001, 157(4): 283–321.

    Article  MathSciNet  Google Scholar 

36. Topputo, F. Fast numerical approximation of invariant manifolds in the circular restricted three-body problem. Communications in Nonlinear Science and Numerical Simulation, 2016, 32: 89–98.

    Article  MathSciNet  Google Scholar 

37. Howell, K. C. Three-dimensional, periodic, “halo” orbits. Celestial Mechanics, 1984, 32(1): 53–71.

    Article  MathSciNet  Google Scholar 

38. Howell, K. C., Pernicka, H. J. Numerical determination of Lissajous trajectories in the restricted three-body problem. Celestial Mechanics, 1987, 41(1–4): 107–124.

    Article  Google Scholar 

39. Gómez, G., Jorba, A., Masdemont J., Simó G. C. Study of the transfer from the Earth to a halo orbit around the equilibrium point L₁. Celestial Mechanics and Dynamical Astronomy, 1993, 56(4): 541–562.

    Article  Google Scholar 

40. Sousa-Silva, P., Terra, M. O., Ceriotti, M. Fast Earth–Moon transfers with ballistic capture. Astrophysics and Space Science, 2018, 363(10): 210.

    Article  MathSciNet  Google Scholar 

41. de Oliveira, V. M., Sousa-Silva, P. A., Caldas, I. L. Orderchaos-order and invariant manifolds in the bounded planar Earth–Moon system. Celestial Mechanics and Dynamical Astronomy, 2020, 132(11–12): 51.

    Article  Google Scholar 

42. de Oliveira, V. M., Palmero, M. S., Caldas, I. L. Measure, dimension, and complexity of the transient motion in Hamiltonian systems. Physica D: Nonlinear Phenomena, 2022, 431: 133126.

    Article  MathSciNet  Google Scholar 

43. Marchal, C. Synthèse des résultats analytiques sur les transferts optimaux entre orbites képlériennes (Durée indifférente). In: Advanced Problems and Methods for Space Flight Optimization. De Veubeke, B. F. Ed. Amsterdam: Elsevier, 1969: 91–156.

    Chapter  Google Scholar 

44. Vallado, D. A. Fundamentals of Astrodynamics and Applications, 3rd edn. Springer, 2007.

    Google Scholar 

45. Lawden, D. F. Impulsive transfer between elliptical orbits. In: Optimization Techniques—With Applications to Aerospace Systems. Leitmann, G. Ed. Amsterdam: Elsevier, 1962: 323–351.

    Chapter  Google Scholar 

46. Topputo, F. On optimal two-impulse Earth–Moon transfers in a four-body model. Celestial Mechanics and Dynamical Astronomy, 2013, 117(3): 279–313.

    Article  MathSciNet  Google Scholar 

47. Folta, D. C., Pavlak, T. A., Haapala, A. F., Howell, K. Preliminary design considerations for access and operations in Earth–Moon L₁/L₂ orbits. In: Proceedings of the 23rd AAS/AIAA Space Flight Mechanics Meeting, 2013: 10–14.

    Google Scholar 

48. De Almeida Jr., A. K. Segmentation of the spacecraft transfer problem through overdetermined and continuity constraints based on the Theory of Functional Connections. Acta Astronautica, 2026, 242: 251–263.

    Article  Google Scholar 

49. Grossi, G., Buonagura, C., Giordano, C., Topputo, F. On optimal three-impulse Earth–Moon transfers in a four-body model. Celestial Mechanics and Dynamical Astronomy, 2024, 136(3): 22.

    Article  MathSciNet  Google Scholar 

50. Mortari, D. The theory of connections: Connecting points. Mathematics, 2017, 5(4): 57.

    Article  MathSciNet  Google Scholar 

51. De Almeida Jr., A. K., Prado, A. F. B. A., Mortari, D. Orbit transfer using Theory of Functional Connections via change of variables. The European Physical Journal Special Topics, 2023, 232(18–19): 3161–3173.

    Article  Google Scholar 

52. Abramowitz, M., Stegun, I. A. Handbook of Mathematical Functions. Dover Publications, 1972.

    Google Scholar 

53. Lanczos, C. Applied Analysis. Courier Corporation, 1988.

    Google Scholar 

54. Mortari, D., Leake, C. The multivariate Theory of Connections. Mathematics, 2019, 7(3): 296.

    Article  Google Scholar 

55. De Oliveira, V. Numerical explorer for the planar circular restricted three-body problem. 2020. Available at https://github.com/vitor-de-oliveira/PCRTBP-explorer

    Google Scholar 

56. De Almeida Jr., A. K. Earth–Moon transfer code via TFC in polar coordinates. 2025. Available at https://github.com/fenixcinzajr/Earth–Moon-transfers-in-polar-coordinates

    Google Scholar 

57. Leake, C., Johnston, H. TFC: A functional interpolation framework. 2021. Available at https://github.com/leakec/tfc

    Google Scholar 

58. Bradbury, J., Frostig, R., Hawkins, P., Johnson, M. J., Leary, C., Maclaurin, D., Necula, G., Paszke, A., VanderPlas, J., Wanderman-Milne, S. JAX: Composable transformations of Python+NumPy programs. 2018. Available at http://github.com/google/jax

    Google Scholar 

59. Simó, C., Gómez, G., Jorba, À., Masdemont, J. The bicircular model near the triangular libration points of the RTBP. In: From Newton to Chaos. Roy, A. E., et al. Eds. Springer Boston, 1995: 343–370.

    Chapter  Google Scholar 

60. Yagasaki, K. Sun-perturbed Earth-to-Moon transfers with low energy and moderate flight time. Celestial Mechanics and Dynamical Astronomy, 2004, 90(3–4): 197–212.

    Article  MathSciNet  Google Scholar 

61. Parker, J. S., Born, G. H. Direct lunar halo orbit transfers. The Journal of the Astronautical Sciences, 2008, 56: 441–476.

    Article  Google Scholar 

62. Raoul, R. Earth to halo orbit transfer trajectories. M. S. Thesis. Purdue University, 2005.

    Google Scholar 

63. Zeng, H., Zhang, J. R. Design of impulsive Earth–Moon halo transfers: Lunar proximity and direct options. Astrophysics and Space Science, 2016, 361(10): 328.

    Article  MathSciNet  Google Scholar 

64. Li, M. T., Zheng, J. H. Indirect transfer to the Earth–Moon L1 libration point. Celestial Mechanics and Dynamical Astronomy, 2010, 108(2): 203–213.

    Article  MathSciNet  Google Scholar 

65. Qi, Y., Xu, S. J. Optimal Earth–Moon transfers using lunar gravity assist in the restricted four-body problem. Acta Astronautica, 2017, 134: 106–120.

    Article  Google Scholar 

66. Yagasaki, K. Computation of low energy Earth-to-Moon transfers with moderate flight time. Physica D: Nonlinear Phenomena, 2004, 197(3–4): 313–331.

    Article  MathSciNet  Google Scholar 

67. Mengali, G., Quarta, A. A. Optimization of biimpulsive trajectories in the Earth–Moon restricted three-body system. Journal of Guidance, Control, and Dynamics, 2005, 28(2): 209–216.

    Article  Google Scholar 

68. Pernicka, H. J., Scarberry, D. P., Marsh, S. M., Sweetser, T. H. A search for low ΔV Earth-to-Moon trajectories. In: Proceedings of the Astrodynamics Conference, 1994: AIAA-94-3772-C.

    Google Scholar 

Download references