The finite element model for the propagation of light in scattering media: A direct method for domains with nonscattering regions
- 6 January 2000
- journal article
- research article
- Published by Wiley in Medical Physics
- Vol. 27 (1) , 252-264
- https://doi.org/10.1118/1.598868
Abstract
We present a method for handling nonscattering regions within diffusing domains. The method develops from an iterative radiosity-diffusion approach using Green's functions that was computationally slow. Here we present an improved implementation using a finite element method (FEM) that is direct. The fundamental idea is to introduce extra equations into the standard diffusion FEM to represent nondiffusive light propagation across a nonscattering region. By appropriate mesh node ordering the computational time is not much greater than for diffusion alone. We compare results from this method with those from a discrete ordinate transport code, and with Monte Carlo calculations. The agreement is very good, and, in addition, our scheme allows us to easily model time-dependent and frequency domain problems.Keywords
This publication has 30 references indexed in Scilit:
- Recovery of region boundaries of piecewise constant coefficients of an elliptic PDE from boundary dataInverse Problems, 1999
- Index mismatch for diffuse photon density waves at both flat and rough diffuse–diffuse interfacesJournal of the Optical Society of America A, 1999
- Optical tomography in medical imagingInverse Problems, 1999
- Scattering of electromagnetic waves from a body over a random rough surfaceOptics Communications, 1997
- Reconstruction algorithm for near-infrared imaging in turbid media by means of time-domain dataJournal of the Optical Society of America A, 1997
- An investigation of light transport through scattering bodies with non-scattering regionsPhysics in Medicine & Biology, 1996
- Direct calculation of the moments of the distribution of photon time of flight in tissue with a finite-element methodApplied Optics, 1995
- Iteration and extrapolation methods for the approximate solution of the even-parity transport equation for systems with voidsAnnals of Nuclear Energy, 1989
- Improving radiosity solutions through the use of analytically determined form-factorsACM SIGGRAPH Computer Graphics, 1989
- A progressive refinement approach to fast radiosity image generationACM SIGGRAPH Computer Graphics, 1988