Image Reconstruction with a LaBr3-based Rotational Modulator

TL;DR

This paper presents a novel rotational modulator gamma-ray imager with a new image reconstruction technique that significantly improves angular resolution and reduces instrument complexity, demonstrated with a prototype achieving 1.9° resolution.

Contribution

The paper introduces a new image reconstruction method for rotational modulators, enabling higher resolution imaging with fewer detectors compared to traditional systems.

Findings

Achieved 1.9° geometric angular resolution

Resolved sources within 35 arcminutes separation

Demonstrated improved resolution over geometric limits

Abstract

A rotational modulator (RM) gamma-ray imager is capable of obtaining significantly better angular resolution than the fundamental geometric resolution defined by the ratio of detector diameter to mask-detector separation. An RM imager consisting of a single grid of absorbing slats rotating ahead of an array of a small number of position-insensitive detectors has the advantage of fewer detector elements (i.e., detector plane pixels) than required by a coded aperture imaging system with comparable angular resolution. The RM therefore offers the possibility of a major reduction in instrument complexity, cost, and power. A novel image reconstruction technique makes it possible to deconvolve the raw images, remove sidelobes, reduce the effects of noise, and provide resolving power a factor of 6 - 8 times better than the geometric resolution. A 19-channel prototype RM developed in our laboratory at Louisiana State University features 13.8 deg full-angle field of view, 1.9 deg geometric angular resolution, and the capability of resolving sources to within 35' separation. We describe the technique, demonstrate the measured performance of the prototype instrument, and describe the prospects for applying the technique to either a high-sensitivity standoff gamma-ray imaging detector or a satellite- or balloon-borne gamma-ray astronomy telescope.