Litcius/Paper detail

Non-Uniform Sampling in NMR Spectroscopy and the Preservation of Spectral Knowledge in the Time and Frequency Domains

Manpreet Kaur, Callie M. Lewis, Aaron M. Chronister, Gabriel S. Phun, Leonard J. Mueller

2020The Journal of Physical Chemistry A22 citationsDOIOpen Access PDF

Abstract

The increased sensitivity under weighted non-uniform sampling (NUS) is demonstrated and quantified using Monte Carlo simulations of nuclear magnetic resonance (NMR) time- and frequency-domain signals. The concept of spectral knowledge is introduced and shown to be superior to the frequency-domain signal-to-noise ratio for assessing the quality of NMR data. Two methods for rigorously preserving spectral knowledge and the time-domain NUS knowledge enhancement upon transformation to the frequency domain are demonstrated, both theoretically and numerically. The first, non-uniform weighted sampling using consistent root-mean-square noise, is applicable to data sampled on the Nyquist grid, whereas the second, the block Fourier transform using consistent root-mean-square noise, can be used to transform time-domain data acquired with arbitrary, off-grid NUS.

Topics & Concepts

Sampling (signal processing)Nyquist–Shannon sampling theoremFrequency domainNyquist frequencyNoise (video)Fourier transformRoot mean squareMonte Carlo methodTime domainMathematicsGridSquare rootAlgorithmNonuniform samplingSignal-to-noise ratio (imaging)SIGNAL (programming language)Computer scienceStatisticsPhysicsOpticsMathematical analysisArtificial intelligenceTelecommunicationsQuantum mechanicsGeometryQuantization (signal processing)Image (mathematics)Bandwidth (computing)Programming languageDetectorComputer visionNMR spectroscopy and applicationsBlind Source Separation TechniquesImage and Signal Denoising Methods