Title :
Adaptive Compressed Tomography Sensing
Author :
Barkan, Oren ; Weill, Jonathan ; Averbuch, Amir ; Dekel, Shai
Abstract :
One of the main challenges in Computed Tomography (CT) is how to balance between the amount of radiation the patient is exposed to during scan time and the quality of the CT image. We propose a mathematical model for adaptive CT acquisition whose goal is to reduce dosage levels while maintaining high image quality at the same time. The adaptive algorithm iterates between selective limited acquisition and improved reconstruction, with the goal of applying only the dose level required for sufficient image quality. The theoretical foundation of the algorithm is nonlinear Ridgelet approximation and a discrete form of Ridgelet analysis is used to compute the selective acquisition steps that best capture the image edges. We show experimental results where for the same number of line projections, the adaptive model produces higher image quality, when compared with standard limited angle, non-adaptive acquisition algorithms.
Keywords :
Radon transforms; adaptive signal detection; compressed sensing; computerised tomography; discrete wavelet transforms; image reconstruction; medical image processing; CT image; adaptive CT acquisition; adaptive algorithm; compressed tomography sensing; computed tomography; discrete Ridgelet analysis; dosage levels; image edges; image quality; improved reconstruction; line projections; nonlinear Ridgelet approximation; scan time; selective limited acquisition; Adaptation models; Approximation algorithms; Approximation methods; Computed tomography; Image reconstruction; TV; Transforms; Adaptive Compressed Sensing; Computed Tomography; Low-dose CT; Ridgelets;
Conference_Titel :
Computer Vision and Pattern Recognition (CVPR), 2013 IEEE Conference on
Conference_Location :
Portland, OR
DOI :
10.1109/CVPR.2013.285
