Ghost Tomography

TL;DR

This paper demonstrates a novel method called ghost tomography that uses single-pixel detection and random x-ray patterns to reconstruct three-dimensional images of opaque objects, expanding ghost imaging to volumetric imaging with potential dose and resolution benefits.

Contribution

It introduces the first experimental demonstration of ghost tomography with hard x-rays, enabling 3D imaging using single-pixel detection and random illumination patterns.

Findings

Successful 3D reconstruction of specimens using ghost tomography.

Use of synchrotron hard x-rays for volumetric imaging.

Potential to improve image quality and resolution independently of detector performance.

Abstract

Ghost tomography using single-pixel detection extends the emerging field of ghost imaging to three dimensions, with the use of penetrating radiation. In this work, a series of spatially random x-ray intensity patterns is used to illuminate a specimen in various tomographic angular orientations with only the total transmitted intensity being recorded by a single-pixel camera (or bucket detector). The set of zero-dimensional intensity readings, combined with knowledge of the corresponding two-dimensional illuminating patterns and specimen orientations, is sufficient for three-dimensional reconstruction of the specimen. The experimental demonstration of ghost tomography is presented here using synchrotron hard x-rays. This result expands the scope of ghost imaging to encompass volumetric imaging (i.e., tomography), of optically opaque objects using penetrating radiation. For hard x-rays, ghost tomography has the potential to decouple image quality from dose rate as well as image resolution from detector performance.