Title :
Three-dimensional radiative transfer tomography for turbid media
Author :
Cai, W. ; Xu, M. ; Alfano, R.R.
Author_Institution :
Dept. of Phys., City Univ. of New York, NY, USA
Abstract :
The photon distribution, as a function of position, angle, and time, is computed using the analytical cumulant solution of the Boltzmann radiative transfer equation (RTE). A linear forward model for light propagation in turbid media for three-dimensional (3-D) optical tomography is formed based on this solution. The model can be used with time resolved, continuous wave (CW), and frequency-domain measurements in parallel geometries. This cumulant forward model (CFM) is more accurate than that based on the diffusion approximation of RTE. An inverse algorithm that incorporates this CFM is developed, based on a fast 3-D hybrid-dual-Fourier tomographic approach using multiple detectors and multiple sources in parallel geometries. The inverse algorithm can produce a 3-D image of a turbid medium with more than 20 000 voxels in 1-2 min using a personal computer. A 3-D image reconstructed from simulated data is presented.
Keywords :
Boltzmann equation; bio-optics; biomedical optical imaging; frequency-domain analysis; image reconstruction; inverse problems; light propagation; medical image processing; optical tomography; radiative transfer; turbidity; 1 to 2 min; 3-D optical tomography; Boltzmann radiative transfer equation; analytical cumulant solution; angle; continuous wave measurements; cumulant forward model; diffusion approximation; fast 3-D hybrid-dual-Fourier tomographic approach; frequency-domain measurements; inverse algorithm; light propagation; linear forward model; multiple detectors; multiple sources; parallel geometries; personal computer; photon distribution; position; reconstructed 3-D image; simulated data; three-dimensional radiative transfer tomography; time; time resolved measurements; turbid media; Distributed computing; Equations; Frequency domain analysis; Frequency measurement; Geometrical optics; Optical computing; Optical propagation; Solid modeling; Time measurement; Tomography;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2003.813312
