Title :
Radiation field estimation using a Gaussian mixture
Author :
Morelande, Mark R. ; Skvortsov, Alex
Author_Institution :
Melbourne Syst. Lab., Univ. of Melbourne, Melbourne, VIC, Australia
Abstract :
The problem of estimating the spatial distribution of radiation using measurements from a collection of spatially distributed sensors is considered. A parametric approach is adopted in which the field is modelled by a weighted sum of Gaussians, i.e., a Gaussian mixture. This is a valid approach for a large class of fields, e.g., absolutely integrable fields. Two Bayesian estimators based on progressive correction are proposed to estimate the mixture parameters. The first performs progressive correction using a Gaussian approximation while the second uses a Monte Carlo approximation. It is demonstrated that the Gaussian approximation is capable of accurate estimation using both simulated and real data.
Keywords :
Geiger counters; Monte Carlo methods; dosimetry; radioactivity measurement; Bayesian estimator; Gaussian approximation; Gaussian mixture; Geiger-Muller counters; Monte Carlo approximation; radiation dose; radiation field estimation; spatially distributed sensors; Bayesian methods; Convolution; Gaussian approximation; Inverse problems; Kernel; Monte Carlo methods; Parameter estimation; Radiation detectors; Sensor phenomena and characterization; Smoothing methods; Bayesian estimation; Radiological field estimation;
Conference_Titel :
Information Fusion, 2009. FUSION '09. 12th International Conference on
Conference_Location :
Seattle, WA
Print_ISBN :
978-0-9824-4380-4
