Author: bugman Date: Wed Dec 4 16:04:30 2013 New Revision: 21780 URL: http://svn.gna.org/viewcvs/relax?rev=21780&view=rev Log: Editing of the introduction section of the dispersion chapter of the manual. Modified: trunk/docs/latex/dispersion.tex Modified: trunk/docs/latex/dispersion.tex URL: http://svn.gna.org/viewcvs/relax/trunk/docs/latex/dispersion.tex?rev=21780&r1=21779&r2=21780&view=diff ============================================================================== --- trunk/docs/latex/dispersion.tex (original) +++ trunk/docs/latex/dispersion.tex Wed Dec 4 16:04:30 2013 @@ -44,10 +44,9 @@ \right] . \end{equation} -The solution to this equation then Fourier transformed to produce the NMR spectrum. However the analytic or closed-form frequency-domain solution remains intractable. - +The analytic or closed-form frequency-domain solution for this equation however remains intractable. Solutions can nevertheless be found by either making assumptions or restrictions about the exchange process and then analytically solving~\ref{eq: Bloch-McConnell} or by finding numeric solutions. -The modelling of relaxation dispersion data can hence be catergorised into these two distinct methodologies: +The modelling of relaxation dispersion data can hence be categorised into these two distinct methodologies: \begin{description} \item[Analytical models:]\index{relaxation dispersion!Analytical model} Optimisation of models based on analytical, closed-form expressions derived from the Bloch-McConnell equations subject to certain conditions (see Section~\ref{sect: dispersion: analytic CPMG models} on page~\pageref{sect: dispersion: analytic CPMG models} and Section~\ref{sect: dispersion: analytic R1rho models} on page~\pageref{sect: dispersion: analytic R1rho models}).