1. Reconstructing the Position and Intensity of Multiple Gamma-Ray Point Sources With a Sparse Parametric Algorithm
- Author
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Vavrek, Jayson R, Hellfeld, Daniel, Bandstra, Mark S, Negut, Victor, Meehan, Kathryn, Vanderlip, William Joe, Cates, Joshua W, Pavlovsky, Ryan, Quiter, Brian J, Cooper, Reynold J, and Joshi, Tenzing HY
- Subjects
Synchrotrons and Accelerators ,Physical Sciences ,Biomedical Imaging ,Bioengineering ,Gamma-ray imaging ,maximum likelihood ,Poisson likelihood ,radiological source search ,source localization ,physics.ins-det ,NSD-Applied Nuclear Physics ,Atomic ,Molecular ,Nuclear ,Particle and Plasma Physics ,Other Physical Sciences ,Biomedical Engineering ,Nuclear & Particles Physics ,Nuclear and plasma physics - Abstract
We present an experimental demonstration of additive point source localization (APSL), a sparse parametric imaging algorithm that reconstructs the 3-D positions and activities of multiple gamma-ray point sources. Using a handheld gamma-ray detector array and up to four 8 mu Ci 137Cs gamma-ray sources, we performed both source-search and source-separation experiments in an indoor laboratory environment. In the majority of the source-search measurements, APSL reconstructed the correct number of sources with position accuracies of 20 cm and activity accuracies (unsigned) of 20%, given measurement times of 2 to 3 min and distances of closest approach (to any source) of 20 cm. In source-separation measurements where the detector could be moved freely about the environment, APSL was able to resolve two sources separated by 75 cm or more given only 60 s of measurement time. In these source-separation measurements, APSL produced larger total activity errors of 40%, but obtained source-separation distances accurate to within 15 cm. We also compare our APSL results against traditional maximum likelihood-expectation maximization (ML-EM) reconstructions and demonstrate improved image accuracy and interpretability using APSL over ML-EM. These results indicate that APSL is capable of accurately reconstructing gamma-ray source positions and activities using measurements from existing detector hardware.
- Published
- 2020