Filtered-backprojection and the exponential Radon transform

The mathematical problem of generating a desired dose distribution in a patient who has to undergo external beam radiotherapy is closely related to the problem of reconstructing an image from its projections. Under some simplifying assumptions the theory of the exponential Radon transform as develop

## Abstract The exponential Radon transform, which arises in single photon emission computed tomography, is defined by ℛ ƒ(μ:ω,__s__) = ∫~R~ƒ(__s__ω + __t__omega;^⟂^) e^μ__t__^ d__t__ƒ. Here ƒ is a compactly supported distribution in the plane which represents the location and intensity of a radio‐

We prove that under certain conditions the inversion problem for the generalized Radon transform reduces to solvinga Fredholm integral equation and we obtain the asymptoticexpansionof the symbolof the integral operator in this equation. We consider applications of the generalized Radon transform to

## Abstract The Radon transform __R__(__p__, θ), θ∈__S__^__n__−1^, __p__∈ℝ^1^, of a compactly supported function __f__(__x__) with support in a ball __B__~__a__~ of radius a centred at the origin is given for all \documentclass{article}\pagestyle{empty}\begin{document}$ \theta \in \mathop {S^{n - 1

We derive the regularity properties of the Radon transform of Melrose and Taylor for the scattering on a compact, convex obstacle with a smooth boundary. The result is formulated in terms of the highest order of contact of tangent lines with the boundary of an obstacle. The main ingredients of the p