Author: bugman Date: Wed Jul 17 14:37:59 2013 New Revision: 20356 URL: http://svn.gna.org/viewcvs/relax?rev=20356&view=rev Log: Updated all of the numerical model sections of the dispersion chapter of the manual. This includes additions for the 'NS 2-site 3D' and 'NS 2-site 3D red' models. Modified: branches/relax_disp/docs/latex/dispersion.tex Modified: branches/relax_disp/docs/latex/dispersion.tex URL: http://svn.gna.org/viewcvs/relax/branches/relax_disp/docs/latex/dispersion.tex?rev=20356&r1=20355&r2=20356&view=diff ============================================================================== --- branches/relax_disp/docs/latex/dispersion.tex (original) +++ branches/relax_disp/docs/latex/dispersion.tex Wed Jul 17 14:37:59 2013 @@ -364,26 +364,52 @@ \end{itemize} +% NS 2-site 3D model. +%~~~~~~~~~~~~~~~~~~~~ + +\subsection{The NS 2-site 3D CPMG model} +\label{sect: dispersion: NS 2-site 3D model} +\index{relaxation dispersion!NS 2-site 3D model|textbf} + +This is the numerical model for 2-site exchange using 3D magnetisation vectors. +Is it selected by setting the model to `NS 2-site 3D'. +The simple constraint $\pA > \pB$ is used to halve the optimisation space, as both sides of the limit are mirror image spaces. + + +% NS 2-site 3D red model. +%~~~~~~~~~~~~~~~~~~~~~~~~ + +\subsection{The NS 2-site 3D reduced CPMG model} +\label{sect: dispersion: NS 2-site 3D red model} +\index{relaxation dispersion!NS 2-site 3D red model|textbf} + +This is the numerical model for 2-site exchange using 3D magnetisation vectors, whereby the simplification $\RtwozeroA = \RtwozeroB$ is assumed. +Is it selected by setting the model to `NS 2-site 3D red'. +The simple constraint $\pA > \pB$ is used to halve the optimisation space, as both sides of the limit are mirror image spaces. + + +% NS 2-site star model. +%~~~~~~~~~~~~~~~~~~~~~~ + +\subsection{The NS 2-site star CPMG model} +\label{sect: dispersion: NS 2-site star model} +\index{relaxation dispersion!NS 2-site star model|textbf} + +This is the numerical model for 2-site exchange using complex conjugate matrices. +Is it selected by setting the model to `NS 2-site star'. +The simple constraint $\pA > \pB$ is used to halve the optimisation space, as both sides of the limit are mirror image spaces. + + % NS 2-site star red model. %~~~~~~~~~~~~~~~~~~~~~~~~~~ -\subsection{The NS 2-site star red CPMG model} +\subsection{The NS 2-site star reduced CPMG model} \label{sect: dispersion: NS 2-site star red model} \index{relaxation dispersion!NS 2-site star red model|textbf} This is the numerical model for 2-site exchange using complex conjugate matrices, whereby the simplification $\RtwozeroA = \RtwozeroB$ is assumed. Is it selected by setting the model to `NS 2-site star red'. The simple constraint $\pA > \pB$ is used to halve the optimisation space, as both sides of the limit are mirror image spaces. - - -% NS 2-site star model. -%~~~~~~~~~~~~~~~~~~~~~~ - -\subsection{The NS 2-site star CPMG model} -\label{sect: dispersion: NS 2-site star model} -\index{relaxation dispersion!NS 2-site star model|textbf} - -This is the numerical model for 2-site exchange using complex conjugate matrices. Is it selected by setting the model to `NS 2-site star'. The simple constraint $\pA > \pB$ is used to halve the optimisation space, as both sides of the limit are mirror image spaces. % M61 model.