Author: bugman Date: Mon Oct 7 15:41:55 2013 New Revision: 21008 URL: http://svn.gna.org/viewcvs/relax?rev=21008&view=rev Log: Fixed several typo errors of "Is it selected"->"It is selected". A copy-paste error which have spreaded. Progress sr #3071: https://gna.org/support/index.php?3071 - Implementation of Tollinger/Kay dispersion model (2001) Following the guide at: http://wiki.nmr-relax.com/Tutorial_for_adding_relaxation_dispersion_models_to_relax Troels E. Linnet provided this patch. Commit by: tlinnet _aaattt_ gmail_dot_com Signed-off-by: Edward d'Auvergne <edward@xxxxxxxxxxxxx> 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=21008&r1=21007&r2=21008&view=diff ============================================================================== --- branches/relax_disp/docs/latex/dispersion.tex (original) +++ branches/relax_disp/docs/latex/dispersion.tex Mon Oct 7 15:41:55 2013 @@ -371,7 +371,7 @@ \index{relaxation dispersion!CR72 full model|textbf} This is the model for 2-site exchange on all times scales (with the constraint that $\pA > \pB$), named after \citet{CarverRichards72}. -Is it selected by setting the model to `CR72 full'. +It is selected by setting the model to `CR72 full'. The equation is \begin{equation} \Rtwoeff = \frac{1}{2} \Big( \textrm{R}_\textrm{2A}^0 + \textrm{R}_\textrm{2B}^0 + \kex - 2\nucpmg\cosh^{-1} \big( D_+\cosh(\eta_+) - D_-\cos(\eta_-) \big) \Big) , @@ -400,7 +400,7 @@ \index{relaxation dispersion!CR72 model|textbf} This is the model for 2-site exchange on all times scales (with the constraint that $\pA > \pB$), named after \citet{CarverRichards72}. -Is it selected by setting the model to `CR72'. +It is selected by setting the model to `CR72'. It is the same as the full CR72 model described above, but with the simplification that $\RtwozeroA = \RtwozeroB$. This simplifies the equations to \begin{equation} @@ -422,7 +422,7 @@ \label{sect: dispersion: IT99 model} \index{relaxation dispersion!IT99 model|textbf} -This is the model for 2-site exchange on all times scales (with the constraint that $\pA \gg \pB$), named after Ishima and Torchia 1999. Is it selected by setting the model to `IT99'. The equation is: +This is the model for 2-site exchange on all times scales (with the constraint that $\pA \gg \pB$), named after Ishima and Torchia 1999. It is selected by setting the model to `IT99'. The equation is: \begin{align} \Rex &\simeq \frac{\Phiex\tex}{1 + \omega_a^2\tex^2} , \\ \omega_a^2 &= \sqrt{\omega_\textrm{1eff}^4 + \pA^2\dw^4} , \\ @@ -455,7 +455,7 @@ -This is the model for 2-site very-slow exchange model for time scales within range of microsecond to second time scale, where $\pA \gg \pB$, and named after Tollinger \textit{et al.}. Is it selected by setting the model to `TSMFK01'. A particularly interesting feature of the dispersion curves is the damped oscillations, which occur at low CPMG field strengths, and is solely a function of the chemical shift difference between the two sites (i.e., independent of the rate of exchange). +This is the model for 2-site very-slow exchange model for time scales within range of microsecond to second time scale, where $\pA \gg \pB$, and named after Tollinger \textit{et al.}. It is selected by setting the model to `TSMFK01'. A particularly interesting feature of the dispersion curves is the damped oscillations, which occur at low CPMG field strengths, and is solely a function of the chemical shift difference between the two sites (i.e., independent of the rate of exchange). The equation is: \begin{align} @@ -485,7 +485,7 @@ \index{relaxation dispersion!NS CPMG 2-site 3D full model|textbf} This is the numerical model for 2-site exchange using 3D magnetisation vectors. -Is it selected by setting the model to `NS CPMG 2-site 3D full'. +It is selected by setting the model to `NS CPMG 2-site 3D full'. The simple constraint $\pA > \pB$ is used to halve the optimisation space, as both sides of the limit are mirror image spaces. @@ -497,7 +497,7 @@ \index{relaxation dispersion!NS CPMG 2-site 3D 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 CPMG 2-site 3D'. +It is selected by setting the model to `NS CPMG 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. @@ -509,7 +509,7 @@ \index{relaxation dispersion!NS CPMG 2-site star full model|textbf} This is the numerical model for 2-site exchange using complex conjugate matrices. -Is it selected by setting the model to `NS CPMG 2-site star full'. +It is selected by setting the model to `NS CPMG 2-site star full'. The simple constraint $\pA > \pB$ is used to halve the optimisation space, as both sides of the limit are mirror image spaces. @@ -521,7 +521,7 @@ \index{relaxation dispersion!NS CPMG 2-site star 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 CPMG 2-site star'. +It is selected by setting the model to `NS CPMG 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. @@ -533,7 +533,7 @@ \index{relaxation dispersion!NS CPMG 2-site expanded model|textbf} This is the numerical model for 2-site exchange expanded using Maple by Nikolai Skrynnikov. -Is it selected by setting the model to `NS CPMG 2-site expanded'. +It is selected by setting the model to `NS CPMG 2-site expanded'. The simple constraint $\pA > \pB$ is used to halve the optimisation space, as both sides of the limit are mirror image spaces. @@ -647,7 +647,7 @@ \index{relaxation dispersion!NS R1rho 2-site model|textbf} This is the numerical model for 2-site exchange using 3D magnetisation vectors. -Is it selected by setting the model to `NS R1rho 2-site'. +It is selected by setting the model to `NS R1rho 2-site'. The simple constraint $\pA > \pB$ is used to halve the optimisation space, as both sides of the limit are mirror image spaces.