Application of linear prediction and rapid acquisition to nuclear magnetic resonance

In pulse nuclear magnetic resonance (NMR) spectroscopy, data are obtained by perturbing the nucleus from its equilibrium position and acquiring the transient response. Fourier transformation is the preferred mode used in data processing of the signals due to its ability to compute the NMR spectrum r...

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Main Authors:	Chainani, Edward T, Dayrit, Fabian M, Sison, L G
Format:	text
Published:	Archīum Ateneo 2002
Subjects:	Nuclear magnetic resonance Spectroscopy Transient response Data processing Signal processing Signal to noise ratio Signal resolution Fourier transforms Time domain analysis Magnetic resonance Chemistry
Online Access:	https://archium.ateneo.edu/chemistry-faculty-pubs/133 https://ieeexplore.ieee.org/abstract/document/1181019
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Institution:	Ateneo De Manila University

id	ph-ateneo-arc.chemistry-faculty-pubs-1132
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spelling	ph-ateneo-arc.chemistry-faculty-pubs-11322020-07-29T04:17:15Z Application of linear prediction and rapid acquisition to nuclear magnetic resonance Chainani, Edward T Dayrit, Fabian M Sison, L G In pulse nuclear magnetic resonance (NMR) spectroscopy, data are obtained by perturbing the nucleus from its equilibrium position and acquiring the transient response. Fourier transformation is the preferred mode used in data processing of the signals due to its ability to compute the NMR spectrum rapidly. To obtain good signal-to-noise ratio, it is common practice to average many transients. To obtain good resolution, lengthier acquisition times are favored. For insensitive nuclei, where thousands of collected transients are necessary, this is a time-consuming procedure; especially if the nuclear relaxation time constant is in the order of seconds or minutes. A faster acquisition method is proposed. Using a modified NMR pulse sequence, the proposed method acquires signals more rapidly than by conventional acquisition methods; however, the signals are truncated. In processing truncated data; the shortcomings of the Fourier transform must be overcome by alternative spectral estimation methods. An alternative processing method - linear prediction (LP) - is used to reconstruct the spectrum from the incomplete time-domain magnetic resonance data. The LP method's application to truncated, fast acquisition of data is discussed in detail. This combination of methods is a novel way of acquiring and processing NMR spectroscopic data. 2002-01-01T08:00:00Z text https://archium.ateneo.edu/chemistry-faculty-pubs/133 https://ieeexplore.ieee.org/abstract/document/1181019 Chemistry Faculty Publications Archīum Ateneo Nuclear magnetic resonance Spectroscopy Transient response Data processing Signal processing Signal to noise ratio Signal resolution Fourier transforms Time domain analysis Magnetic resonance Chemistry
institution	Ateneo De Manila University
building	Ateneo De Manila University Library
country	Philippines
collection	archium.Ateneo Institutional Repository
topic	Nuclear magnetic resonance Spectroscopy Transient response Data processing Signal processing Signal to noise ratio Signal resolution Fourier transforms Time domain analysis Magnetic resonance Chemistry
spellingShingle	Nuclear magnetic resonance Spectroscopy Transient response Data processing Signal processing Signal to noise ratio Signal resolution Fourier transforms Time domain analysis Magnetic resonance Chemistry Chainani, Edward T Dayrit, Fabian M Sison, L G Application of linear prediction and rapid acquisition to nuclear magnetic resonance
description	In pulse nuclear magnetic resonance (NMR) spectroscopy, data are obtained by perturbing the nucleus from its equilibrium position and acquiring the transient response. Fourier transformation is the preferred mode used in data processing of the signals due to its ability to compute the NMR spectrum rapidly. To obtain good signal-to-noise ratio, it is common practice to average many transients. To obtain good resolution, lengthier acquisition times are favored. For insensitive nuclei, where thousands of collected transients are necessary, this is a time-consuming procedure; especially if the nuclear relaxation time constant is in the order of seconds or minutes. A faster acquisition method is proposed. Using a modified NMR pulse sequence, the proposed method acquires signals more rapidly than by conventional acquisition methods; however, the signals are truncated. In processing truncated data; the shortcomings of the Fourier transform must be overcome by alternative spectral estimation methods. An alternative processing method - linear prediction (LP) - is used to reconstruct the spectrum from the incomplete time-domain magnetic resonance data. The LP method's application to truncated, fast acquisition of data is discussed in detail. This combination of methods is a novel way of acquiring and processing NMR spectroscopic data.
format	text
author	Chainani, Edward T Dayrit, Fabian M Sison, L G
author_facet	Chainani, Edward T Dayrit, Fabian M Sison, L G
author_sort	Chainani, Edward T
title	Application of linear prediction and rapid acquisition to nuclear magnetic resonance
title_short	Application of linear prediction and rapid acquisition to nuclear magnetic resonance
title_full	Application of linear prediction and rapid acquisition to nuclear magnetic resonance
title_fullStr	Application of linear prediction and rapid acquisition to nuclear magnetic resonance
title_full_unstemmed	Application of linear prediction and rapid acquisition to nuclear magnetic resonance
title_sort	application of linear prediction and rapid acquisition to nuclear magnetic resonance
publisher	Archīum Ateneo
publishDate	2002
url	https://archium.ateneo.edu/chemistry-faculty-pubs/133 https://ieeexplore.ieee.org/abstract/document/1181019
_version_	1681506788404363264

Application of linear prediction and rapid acquisition to nuclear magnetic resonance

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