Corrections for sinusoidal background and non-orthogonality of signal channels in sinusoidal rapid magnetic field scans

[Display omitted] ► Rapid scan EPR signals are separated from sinusoidal background in the frequency domain. ► The sinusoidal background signal is fitted and subtracted. ► This background subtraction method does not require recording an off-resonance signal. ► This procedure also corrects for non-or...

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Veröffentlicht in:	Journal of magnetic resonance (1997) 2012-10, Vol.223, p.80-84
Hauptverfasser:	Tseitlin, Mark, Mitchell, Deborah G., Eaton, Sandra S., Eaton, Gareth R.
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Arrays Background correction Channels Data Interpretation, Statistical Electrochemistry Electromagnetic Fields Enzymes - chemistry EPR Extrapolation Fourier Analysis Magnetic fields Magnetic Resonance Spectroscopy - methods Mathematical analysis Orthogonality in quadrature detector Oscillations Quadratures Rapid scan Signal to noise ratio
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creator	Tseitlin, Mark Mitchell, Deborah G. Eaton, Sandra S. Eaton, Gareth R.
description	[Display omitted] ► Rapid scan EPR signals are separated from sinusoidal background in the frequency domain. ► The sinusoidal background signal is fitted and subtracted. ► This background subtraction method does not require recording an off-resonance signal. ► This procedure also corrects for non-orthogonality of the quadrature detection channels. ► Signal to noise is improved by removing half of the noise in the frequency domain. The rapidly-changing magnetic field of sinusoidal rapid scans creates background signals that are dominated by oscillations at the scan frequency. The background oscillations can be removed without acquiring off-resonance data. For data acquired in quadrature, up-field and down-field scan signals can be separated in the frequency domain. For each scan direction, the background oscillation can be calculated by fitting to the half cycle that does not contain the EPR signal. The extrapolated fit function is then subtracted from the half cycle that contains the EPR signal. By zeroing the array for the half cycles that do not contain the EPR signal, the signal-to-noise is improved and the data are corrected for non-orthogonality of the quadrature channels.
doi_str_mv	10.1016/j.jmr.2012.07.023
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The rapidly-changing magnetic field of sinusoidal rapid scans creates background signals that are dominated by oscillations at the scan frequency. The background oscillations can be removed without acquiring off-resonance data. For data acquired in quadrature, up-field and down-field scan signals can be separated in the frequency domain. For each scan direction, the background oscillation can be calculated by fitting to the half cycle that does not contain the EPR signal. The extrapolated fit function is then subtracted from the half cycle that contains the EPR signal. 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The rapidly-changing magnetic field of sinusoidal rapid scans creates background signals that are dominated by oscillations at the scan frequency. The background oscillations can be removed without acquiring off-resonance data. For data acquired in quadrature, up-field and down-field scan signals can be separated in the frequency domain. For each scan direction, the background oscillation can be calculated by fitting to the half cycle that does not contain the EPR signal. The extrapolated fit function is then subtracted from the half cycle that contains the EPR signal. 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subjects	Algorithms Arrays Background correction Channels Data Interpretation, Statistical Electrochemistry Electromagnetic Fields Enzymes - chemistry EPR Extrapolation Fourier Analysis Magnetic fields Magnetic Resonance Spectroscopy - methods Mathematical analysis Orthogonality in quadrature detector Oscillations Quadratures Rapid scan Signal to noise ratio
title	Corrections for sinusoidal background and non-orthogonality of signal channels in sinusoidal rapid magnetic field scans
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