Solving the geodesic equations

On an n-dimensional Riemannian manifold ${\displaystyle M}$, the geodesic equation written in a coordinate chart with coordinates ${\displaystyle x^{a}}$ is:

${\displaystyle {\frac {d^{2}x^{a}}{ds^{2}}}+\Gamma _{bc}^{a}{\frac {dx^{b}}{ds}}{\frac {dx^{c}}{ds}}=0}$

where the coordinates x^a(s) are regarded as the coordinates of a curve γ(s) in ${\displaystyle M}$ and ${\displaystyle \Gamma _{bc}^{a}}$ are the Christoffel symbols. The Christoffel symbols are functions of the metric and are given by:

${\displaystyle \Gamma _{bc}^{a}={\frac {1}{2}}g^{ad}\left(g_{cd,b}+g_{bd,c}-g_{bc,d}\right)}$

where the comma indicates a partial derivative with respect to the coordinates:

${\displaystyle g_{ab,c}={\frac {\partial {g_{ab}}}{\partial {x^{c}}}}}$

As the manifold has dimension ${\displaystyle n}$, the geodesic equations are a system of ${\displaystyle n}$ ordinary differential equations for the ${\displaystyle n}$ coordinate variables. Thus, allied with initial conditions, the system can, according to the Picard–Lindelöf theorem, be solved. One can also use a Lagrangian approach to the problem: defining

${\displaystyle L={\sqrt {g_{\mu \nu }{\frac {dx^{\mu }}{ds}}{\frac {dx^{\nu }}{ds}}}}}$

and applying the Euler–Lagrange equation.

As the laws of physics can be written in any coordinate system, it is convenient to choose one that simplifies the geodesic equations. Mathematically, this means a coordinate chart is chosen in which the geodesic equations have a particularly tractable form.

When the geodesic equations can be separated into terms containing only an undifferentiated variable and terms containing only its derivative, the former may be consolidated into an effective potential dependent only on position. In this case, many of the heuristic methods of analysing energy diagrams apply, in particular the location of turning points.