Title :
An admissible solution approach for diffuse optical tomography
Author :
Brooks, D.H. ; Gaudette, R.J. ; Miller, E.L. ; Di Marzio, C.A. ; Boas, D. ; Kilmer, M.
Author_Institution :
Dept. of Electr. & Comput. Eng., Northeastern Univ., Boston, MA, USA
fDate :
Oct. 29 2000-Nov. 1 2000
Abstract :
Our goal is to characterize the space-varying absorption coefficient from observations of diffuse light propagating through tissue. Sensor array measurements from illumination with several sources leads to an inverse problem which, due to the physics and the restriction of sensors to the surface, is ill-posed and underdetermined. Accurate, reliable solutions require a priori constraints. Here we adopt an admissible solution approach, with convex constraint functions defining admissibility conditions, implemented via the ellipsoid algorithm. The joint use of measurement-model agreement, amplitude, and total variation type constraints produces more accurate reconstructions in a variety of simulation scenarios.
Keywords :
absorption coefficients; bio-optics; image reconstruction; inverse problems; mean square error methods; medical image processing; optical tomography; MSE; a priori constraints; admissibility conditions; admissible solution approach; biological tissue; convex constraint functions; diffuse light propagation; diffuse optical tomography; ellipsoid algorithm; forward model; ill-posed problem; inverse problem; measurement-model agreement; space-varying absorption coefficient; subgradients; truncated SVD; Absorption; Inverse problems; Lighting; Optical propagation; Optical sensors; Physics; Sensor arrays; Sensor phenomena and characterization; Surface reconstruction; Tomography;
Conference_Titel :
Signals, Systems and Computers, 2000. Conference Record of the Thirty-Fourth Asilomar Conference on
Conference_Location :
Pacific Grove, CA, USA
Print_ISBN :
0-7803-6514-3
DOI :
10.1109/ACSSC.2000.910973
