Patched conic approximation
The simplification is achieved by dividing space into various parts by assigning each of the n bodies (e.g. the Sun, planets, moons) its own sphere of influence. When the spacecraft is within the sphere of influence of a smaller body, only the gravitational force between the spacecraft and that smaller body is considered, otherwise the gravitational force between the spacecraft and the larger body is used. This reduces a complicated n-body problem to multiple two-body problems, for which the solutions are the well-known conic sections of the Kepler orbits.
Although this method gives a good approximation of trajectories for interplanetary spacecraft missions, there are missions for which this approximation does not provide sufficiently accurate results. Notably, it does not model Lagrangian points.
On an Earth-to-Mars transfer, a hyperbolic trajectory is required to escape from Earth's gravity well, then an elliptic or hyperbolic trajectory in the Sun's sphere of influence is required to transfer from Earth's sphere of influence to that of Mars, etc. By patching these conic sections together—matching the position and velocity vectors between segments—the appropriate mission trajectory can be found.
- Two-body problem
- N-body problem
- Sphere of influence
- Kerbal Space Program, a popular simulator based on the patched conic approximation
- Bate, R. R., D. D. Mueller, and J. E. White , Fundamentals of Astrodynamics. Dover, New York.
- Lagerstrom, P. A. and Kevorkian, J. , Earth-to-moon trajectories in the restricted three-body problem, Journal de mecanique, p. 189-218.
- Koon, W.S., Lo, M.W., Marsden, J.E., Ross, S.D. (2008) Dynamical Systems, the Three-Body Problem and Space Mission Design. Marsden Books. pp 5. ISBN 978-0-615-24095-4.
- Carlson, K. M., An Analytical Solution to Patched Conic Trajectories Satisfying Initial and Final boundary Conditions, Bellcomm TM-70-2011-1, https://ntrs.nasa.gov/search.jsp?R=19710007291&qs=Ns%3DLoaded-Date%7C0%26N%3D4294795459