Author: bugman Date: Thu Apr 26 16:44:32 2012 New Revision: 15836 URL: http://svn.gna.org/viewcvs/relax?rev=15836&view=rev Log: Added colons to all entries of the abbreviation chapter in the relax user manual. Modified: 1.3/docs/latex/relax.tex Modified: 1.3/docs/latex/relax.tex URL: http://svn.gna.org/viewcvs/relax/1.3/docs/latex/relax.tex?rev=15836&r1=15835&r2=15836&view=diff ============================================================================== --- 1.3/docs/latex/relax.tex (original) +++ 1.3/docs/latex/relax.tex Thu Apr 26 16:44:32 2012 @@ -150,33 +150,33 @@ \begin{description} -\item[AIC] Akaike's Information Criteria -\item[AICc] small sample size corrected AIC -\item[BIC] Bayesian Information Criteria -\item[$C(\tau)$] correlation function -\item[$\chi^2$] chi-squared function -\item[CSA] chemical shift anisotropy -\item[$\Diff$] the set of diffusion tensor parameters -\item[$\Diff_\Par$] the eigenvalue of the spheroid diffusion tensor corresponding to the unique axis of the tensor -\item[$\Diff_\Per$] the eigenvalue of the spheroid diffusion tensor corresponding to the two axes perpendicular to the unique axis -\item[$\Diff_a$] the anisotropic component of the Brownian rotational diffusion tensor -\item[$\Diff_{iso}$] the isotropic component of the Brownian rotational diffusion tensor -\item[$\Diff_r$] the rhombic component of the Brownian rotational diffusion tensor -\item[$\Diff_{ratio}$] the ratio of $\Diff_\Par$ to $\Diff_\Per$ -\item[$\Diff_x$] the eigenvalue of the Brownian rotational diffusion tensor in which the corresponding eigenvector defines the x-axis of the tensor -\item[$\Diff_y$] the eigenvalue of the Brownian rotational diffusion tensor in which the corresponding eigenvector defines the y-axis of the tensor -\item[$\Diff_z$] the eigenvalue of the Brownian rotational diffusion tensor in which the corresponding eigenvector defines the z-axis of the tensor -\item[$\epsilon_i$] elimination value -\item[$J(\omega)$] spectral density function -\item[NOE] nuclear Overhauser effect -\item[pdf] probability distribution function -\item[$r$] bond length -\item[$\Rone$] spin-lattice relaxation rate -\item[$\Rtwo$] spin-spin relaxation rate +\item[AIC:] Akaike's Information Criteria +\item[AICc:] small sample size corrected AIC +\item[BIC:] Bayesian Information Criteria +\item[$C(\tau)$:] correlation function +\item[$\chi^2$:] chi-squared function +\item[CSA:] chemical shift anisotropy +\item[$\Diff$:] the set of diffusion tensor parameters +\item[$\Diff_\Par$:] the eigenvalue of the spheroid diffusion tensor corresponding to the unique axis of the tensor +\item[$\Diff_\Per$:] the eigenvalue of the spheroid diffusion tensor corresponding to the two axes perpendicular to the unique axis +\item[$\Diff_a$:] the anisotropic component of the Brownian rotational diffusion tensor +\item[$\Diff_{iso}$:] the isotropic component of the Brownian rotational diffusion tensor +\item[$\Diff_r$:] the rhombic component of the Brownian rotational diffusion tensor +\item[$\Diff_{ratio}$:] the ratio of $\Diff_\Par$ to $\Diff_\Per$ +\item[$\Diff_x$:] the eigenvalue of the Brownian rotational diffusion tensor in which the corresponding eigenvector defines the x-axis of the tensor +\item[$\Diff_y$:] the eigenvalue of the Brownian rotational diffusion tensor in which the corresponding eigenvector defines the y-axis of the tensor +\item[$\Diff_z$:] the eigenvalue of the Brownian rotational diffusion tensor in which the corresponding eigenvector defines the z-axis of the tensor +\item[$\epsilon_i$:] elimination value +\item[$J(\omega)$:] spectral density function +\item[NOE:] nuclear Overhauser effect +\item[pdf:] probability distribution function +\item[$r$:] bond length +\item[$\Rone$:] spin-lattice relaxation rate +\item[$\Rtwo$:] spin-spin relaxation rate \item[$R_{ex}$] chemical exchange relaxation rate -\item[$S^2$, $S^2_f$, and $S^2_s$] model-free generalised order parameters -\item[$\tau_e$, $\tau_f$, and $\tau_s$] model-free effective internal correlation times -\item[$\tau_m$] global rotational correlation time +\item[$S^2$, $S^2_f$, and $S^2_s$:] model-free generalised order parameters +\item[$\tau_e$, $\tau_f$, and $\tau_s$:] model-free effective internal correlation times +\item[$\tau_m$:] global rotational correlation time \end{description}