Title :
Optimal sampling and reconstruction of NMR signals with time-varying gradients
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., California Univ., Berkeley, CA, USA
Abstract :
Summary form only given. An optimal sampling and reconstruction scheme has been derived for free induction decay (FID) signals resulting from sinusoidal gradients that occur in nuclear magnetic resonance (NMR) imaging. The problem has been formulated as a linear parameter estimation problem by writing the observed signal, r(t), as the sum of the noise-free FID signal and a zero mean, white, Gaussian random process with intensity σ2 . The noise-free FID signal is modeled to be a linear combination of the uniform samples of the object distribution, f(n 1,n2). The optimal maximum-likelihood (ML) estimate of f(n1,n2) is derived for the constant-gradient case and then generalized to arbitrary time varying gradients
Keywords :
nuclear magnetic resonance; signal processing; Gaussian random process; NMR imaging; NMR signals; constant-gradient; free induction decay signals; linear parameter estimation; maximum likelihood estimate; noise free signal; nuclear magnetic resonance; object distribution; optimal reconstruction; optimal sampling; sinusoidal gradients; time-varying gradients; white Gaussian process; zero mean process; Gaussian noise; Image reconstruction; Magnetic noise; Magnetic resonance imaging; Maximum likelihood estimation; Nuclear magnetic resonance; Parameter estimation; Sampling methods; Signal processing; Writing;
Conference_Titel :
Multidimensional Signal Processing Workshop, 1989., Sixth
Conference_Location :
Pacific Grove, CA
DOI :
10.1109/MDSP.1989.97022
