Santaló's formula


In differential geometry, Santaló's formula describes how to integrate a function on the unit sphere bundle of a Riemannian manifold by first integrating along every geodesic separately and then
over the space of all geodesics. It is a standard tool in integral geometry and has applications in isoperimetric and rigidity results. The formula is named after Luis Santaló, who first proved the result in 1952.

Formulation

Let be a compact, oriented Riemannian manifold with boundary. Then for a function, Santaló's formula takes the form
where
Under the assumptions that
  1. is non-trapping and
  2. is strictly convex,
Santaló's formula is valid for all. In this case it is equivalent to the following identity of measures:
where and is defined by. In particular
this implies that the geodesic X-ray transform extends to a bounded linear map, where and thus there is the following, -version of Santaló's formula:
If the non-trapping or the convexity condition from above fail, then there is a set of positive measure, such that the geodesics emerging from either fail to hit the boundary of or hit it non-transversely. In this case Santaló's formula only remains true for functions with support disjoint from this exceptional set.

Proof

The following proof is taken from , adapted to the and 2) from above are true. Santaló's formula follows from the following two ingredients, noting that has measure zero.
For the integration by parts formula, recall that leaves the Liouville-measure invariant and hence, the divergence with respect to the Sasaki-metric. The result thus follows from the divergence theorem and the observation that, where is the inward-pointing unit-normal to. The resolvent is explicitly given by and the mapping property follows from the smoothness of, which is a consequence of the non-trapping and the convexity assumption.