Title :
Maximum-Entropy Density Estimation for MRI Stochastic Surrogate Models
Author :
Zheng Zhang ; Farnoosh, Niloofar ; Klemas, Thomas ; Daniel, Luca
Author_Institution :
Res. Lab. of Electron., Massachusetts Inst. of Technol. (MIT), Cambridge, MA, USA
Abstract :
Stochastic spectral methods can generate accurate compact stochastic models for electromagnetic problems with material and geometric uncertainties. This letter presents an improved implementation of the maximum-entropy algorithm to compute the density function of an obtained generalized polynomial chaos expansion in magnetic resonance imaging (MRI) applications. Instead of using statistical moments, we show that the expectations of some orthonormal polynomials can be better constraints for the optimization flow. The proposed algorithm is coupled with a finite element-boundary element method (FEM-BEM) domain decomposition field solver to obtain a robust computational prototyping for MRI problems with low- and high-dimensional uncertainties.
Keywords :
biomedical MRI; boundary-elements methods; finite element analysis; maximum entropy methods; polynomials; stochastic processes; FEM-BEM domain decomposition field solver; MRI problems; MRI stochastic surrogate models; compact stochastic models; computational prototyping; density function; electromagnetic problems; finite element-boundary element method; geometric uncertainties; magnetic resonance imaging; material uncertainties; maximum-entropy density estimation; obtained generalized polynomial chaos expansion; optimization flow; orthonormal polynomials; stochastic spectral methods; Antennas; Density functional theory; Impedance; Magnetic resonance imaging; Polynomials; Stochastic processes; Uncertainty; Density function; electromagnetics; magnetic resonance imaging (MRI); uncertainty quantification;
Journal_Title :
Antennas and Wireless Propagation Letters, IEEE
DOI :
10.1109/LAWP.2014.2349933
