Title :
Maximum-Likelihood Methods for Processing Signals From Gamma-Ray Detectors
Author :
Barrett, Harrison H. ; Hunter, William C J ; Miller, Brian William ; Moore, Stephen K. ; Chen, Yichun ; Furenlid, Lars R.
Author_Institution :
Dept. of Radiol., Univ. of Arizona, Tucson, AZ
fDate :
6/1/2009 12:00:00 AM
Abstract :
In any gamma-ray detector, each event produces electrical signals on one or more circuit elements. From these signals, we may wish to determine the presence of an interaction; whether multiple interactions occurred; the spatial coordinates in two or three dimensions of at least the primary interaction; or the total energy deposited in that interaction. We may also want to compute listmode probabilities for tomographic reconstruction. Maximum-likelihood methods provide a rigorous and in some senses optimal approach to extracting this information, and the associated Fisher information matrix provides a way of quantifying and optimizing the information conveyed by the detector. This paper will review the principles of likelihood methods as applied to gamma-ray detectors and illustrate their power with recent results from the Center for Gamma-ray Imaging.
Keywords :
gamma-ray detection; image reconstruction; information analysis; maximum likelihood estimation; nuclear electronics; photomultipliers; semiconductor counters; solid scintillation detectors; Fisher information matrix; PMT; analog electronics; circuit elements; electrical signals; gamma-ray detector; maximum-likelihood methods; optimal approach; scintillation camera; semiconductor detectors; tomographic image reconstruction; Circuits; Data mining; Gamma ray detectors; Image reconstruction; Maximum likelihood detection; Nuclear imaging; Optimization methods; Signal detection; Signal processing; Tomography; Depth of interaction; gamma-ray detectors; maximum-likelihood estimation; scintillation cameras; semiconductor arrays;
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2009.2015308
