YSO coded aperture camera based on depth of interaction for location correction

Purpose Coded aperture imaging was a widely used imaging method for radiation sources. However, the traditional gamma camera based on two-dimensional projection information for coded aperture imaging ignored the influence of the interaction depth of particles and detectors on the projection informat...

Full description

Saved in:
Bibliographic Details
Published in:Radiation detection technology and methods 2023-12, Vol.7 (4), p.589-598
Main Authors: Han, Yiding, Jiang, Xiaopan, Tang, Haohui, Liang, Xiuzuo, Hu, Xuanhou, Huang, Xianchao, Zhang, Zhiming, Shuai, Lei, Guo, Jing, Wei, Long
Format: Article
Language:English
Subjects:
Beam Physics
Hadrons
Heavy Ions
Nuclear Energy
Nuclear Physics
Original Paper
Particle Acceleration and Detection
Physics
Physics and Astronomy
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Purpose Coded aperture imaging was a widely used imaging method for radiation sources. However, the traditional gamma camera based on two-dimensional projection information for coded aperture imaging ignored the influence of the interaction depth of particles and detectors on the projection information, which reduced the imaging quality of the camera to some extent. Therefore, a method of correcting the coded gamma camera based on the interaction depth of particles and detectors is proposed to improve the location accuracy of detectors. Methods The camera developed in this work uses a 7 × 7 YSO crystal array coupled with two 7 × 7 Si-PM arrays. The crystal is evenly divided into 11 parts in the depth direction, with a voxel size of 3 × 3 × 3 mm 3 . The coded mask is a 13 × 13 array, which is a mosaic of two cycles of 7 × 7 modified uniformly redundant array mask. The depth resolution of the detector is obtained via the subsurface laser engraving dual-end readout method. After obtaining the three-dimensional position information of the interaction point the projection information obtained by the detector is layered, and the image is reconstructed. According to the spatial position information of the detector and the coded mask, the corresponding field of view of each layer of the detector is calculated, and the reconstructed image of each layer is amplified and superimposed according to the ratio of the field of view to obtain the reconstructed image combined with the depth information. Results and conclusion According to Monte Carlo simulation and radiation source imaging experiment results, this method can effectively improve the positioning ability of the detector. For the experimental scenario mentioned in the paper, the location accuracy can be improved by up to 1.54°.
ISSN:2509-9930
2509-9949
DOI:10.1007/s41605-023-00415-y