[Uni Tübingen] - [Mat.-Nat. Fakultät] - [Fachbereich Chemie] - [Anorg. Chemie] - [Klaus Eichele] - [NMR Ramblings] - [Processing] - [Convolution] - Shifted Sine Bell - SINE, QSINE

NMR Processing:
Convolution: Shifted Sine Bell - SINE, QSINE

Function:

The figure shows the continuous example FID after sinm with SSB = 1, SSB = 2, and SSB = 8; these are datasets fid/104, fid/105, and fid/106 in the download package.

Sine-bell multiplication multiplies the FID with a sinusoidal function with a period twice the acqusition time. The value of SSB determines the phase of the sinusoidal function and results in the following filter functions:

SSB Result

0, 1 sine

2 cosine

>2 increasingly sine

Examples/Exercises:

Click on the figure to see how sinm with SSB = 0 or SSB = 1 (sine) applied to the synthetic dataset synth/112 in the download package affects the spectrum. Note the resolution enhancement and apodisation at the expense of signal-to-noise ratio. Also, note the negative contributions.

Click on the figure to see how sinm with SSB = 2 (cosine) applied to the synthetic dataset synth/113 in the download package affects the spectrum. Note the apodisation and slight increase of signal-to-noise ratio without significant loss in resolution.

The apodization effect is also visible in this second example: A truncated FID shows after zero-filling and FT excessive "wiggles" in the spectrum (black, left). Application of a cosine filter results in apodization without significant broadening (red, right).

SSB > 2: weighted mixture of both objectives.

Properties/Purpose:

the resolution enhancement is only modest
may result in negative wings of the peaks -> integration is hampered
primarily used for 2D spectra, especially if the acquisition time is short and the FIDs truncated
also used for 2D spectra to convert Lorentzian line shapes into something with less excessive wings; to that end, the squared sine bell version might be more useful

Literature:

Hoffman, Levy, Progr. NMR Spectrosc. 1991, 23, 211; doi:10.1016/0079-6565(91)80005-M
Lindon, Ferrige, Progr. NMR Spectrosc. 1980, 14, 27; doi:10.1016/0079-6565(80)80002-1
Gassner, Jardetzky, Conover, J. Magn. Reson. 1978, 30, 141; doi:10.1016/0022-2364(78)90234-2
Guéron, J. Magn. Reson. 1978, 30, 515; doi:10.1016/0022-2364(78)90277-9

[ Anorg. Chemie ] | [ Go Home ] | webm@ster | last modified: 18.03.2020

	Click on the figure to see how `sinm` with `SSB = 0` or `SSB = 1` (sine) applied to the synthetic dataset `synth/112` in the download package affects the spectrum. Note the resolution enhancement and apodisation at the expense of signal-to-noise ratio. Also, note the negative contributions.
	Click on the figure to see how `sinm` with `SSB = 2` (cosine) applied to the synthetic dataset `synth/113` in the download package affects the spectrum. Note the apodisation and slight increase of signal-to-noise ratio without significant loss in resolution.
	The apodization effect is also visible in this second example: A truncated FID shows after zero-filling and FT excessive "wiggles" in the spectrum (black, left). Application of a cosine filter results in apodization without significant broadening (red, right).
	`SSB > 2`: weighted mixture of both objectives.

[Uni Tübingen] - [Mat.-Nat. Fakultät] - [Fachbereich Chemie] - [Anorg. Chemie] - [Klaus Eichele] - [NMR Ramblings] - [Processing] - [Convolution] - Shifted Sine Bell - SINE, QSINE

Klaus Eichele

NMR Processing:Convolution: Shifted Sine Bell - SINE, QSINE

NMR Processing:
Convolution: Shifted Sine Bell - SINE, QSINE