A wavelet-based multiresolution regularized least squares reconstruction approach for optical tomography

The authors present a wavelet-based multigrid approach to solve the perturbation equation encountered in optical tomography. With this scheme, the unknown image, the data, as well as the weight matrix are all represented by wavelet expansions, thus yielding a multiresolution representation of the original perturbation equation in the wavelet domain. This transformed equation is then solved using a multigrid scheme, by which an increasing portion of wavelet coefficients of the unknown image are solved in successive approximations. One can also quickly identify regions of interest (ROI's) from a coarse level reconstruction and restrict the reconstruction in the following fine resolutions to those regions. At each resolution level a regularized least squares solution is obtained using the conjugate gradient descent method. This approach has been applied to continuous wave data calculated based on the diffusion approximation of several two-dimensional (2-D) test media. Compared to a previously reported one grid algorithm, the multigrid method requires substantially shorter computation time under the same reconstruction quality criterion.

[1]  K. Miller Least Squares Methods for Ill-Posed Problems with a Prescribed Bound , 1970 .

[2]  Harry L. Graber,et al.  MRI-guided optical tomography: prospects and computation for a new imaging method , 1995 .

[3]  Stéphane Mallat,et al.  A Theory for Multiresolution Signal Decomposition: The Wavelet Representation , 1989, IEEE Trans. Pattern Anal. Mach. Intell..

[4]  Harry L. Graber,et al.  Layer-stripping approach for recovery of scattering media from time-resolved data , 1992, Optics & Photonics.

[5]  Yuqi Yao,et al.  Frequency domain optical tomography in human tissue , 1995, Optics + Photonics.

[6]  Simon R. Arridge,et al.  The forward and inverse problems in time resolved infrared imaging , 1993, Other Conferences.

[7]  Harry L. Graber,et al.  Imaging of scattering media by diffusion tomography: an iterative perturbation approach , 1992, Photonics West - Lasers and Applications in Science and Engineering.

[8]  Randall L. Barbour,et al.  A perturbation approach for optical diffusion tomography using continuous-wave and time-resolved data , 1993, Other Conferences.

[9]  Harry L. Graber,et al.  Scattering characteristics of photon density waves from an object in a spherically two-layer medium , 1995 .

[10]  William H. Press,et al.  Book-Review - Numerical Recipes in Pascal - the Art of Scientific Computing , 1989 .

[11]  F. A. Seiler,et al.  Numerical Recipes in C: The Art of Scientific Computing , 1989 .

[12]  Gaofeng Wang,et al.  Solution of inverse problems in image processing by wavelet expansion , 1995, IEEE Trans. Image Process..

[13]  Simon R. Arridge,et al.  New results for the development of infrared absorption imaging , 1990, Other Conferences.

[14]  M W Vannier,et al.  Image reconstruction of the interior of bodies that diffuse radiation. , 1992, Investigative radiology.

[15]  Michel Barlaud,et al.  A fast tomographic reconstruction algorithm in the 2-D wavelet transform domain , 1994, Proceedings of ICASSP '94. IEEE International Conference on Acoustics, Speech and Signal Processing.

[16]  Y Wang,et al.  Regularized progressive expansion algorithm for recovery of scattering media from time-resolved data. , 1997, Journal of the Optical Society of America. A, Optics, image science, and vision.

[17]  Harry L. Graber,et al.  Total least squares approach for the solution of the perturbation equation , 1995, Photonics West.

[18]  Yoram Bresler,et al.  Multiresolution tomographic reconstruction using wavelets , 1994, Proceedings of 1st International Conference on Image Processing.

[19]  William L. Briggs,et al.  A multigrid tutorial , 1987 .

[20]  G. Müller,et al.  Medical Optical Tomography: Functional Imaging and Monitoring , 1993 .