diff --git a/IV/mj-msc.tex b/IV/mj-msc.tex index 839df8e..4f46c90 100644 --- a/IV/mj-msc.tex +++ b/IV/mj-msc.tex @@ -588,17 +588,17 @@ table~\ref{table:scale-halfcirlce-diameter}. \end{table} Sometimes, when working with {\WM}, it is useful to convert between -half-circle's diameter and adjusted size. These easily derive from circle's -area formula $A = 2\pi r^2$. Diameter: +half-circle's diameter $D$ and adjusted size $A_{adj}$. These easily derive +from circle's area formula $A = 2\pi r^2$. Diameter: \[ - D = 2\sqrt{\frac{2 adjsize}{\pi}} + D = 2\sqrt{\frac{2 A_{adj}}{\pi}} \] -In reverse, half-circle's area from it's diameter (adjusted size): +In reverse, adjusted size $A_{adj}$ from half-circle's diameter: \[ - adjsize = \frac{\pi D^2}{8} + A_{adj} = \frac{\pi D^2}{8} \] \subsection{Definition of a Bend} @@ -785,23 +785,24 @@ compactness index is calculated as follows: \item Construct a polygon by joining first and last vertices of the bend. - \item Calculate area of the polygon $A_p$. + \item Calculate area of the polygon $A_{p}$. \item Calculate perimeter $P$ of the polygon. The same value is the circumference of the circle: $C = P$. - \item Given circle's circumference $C$, circle's area $A_c$ is: + \item Given circle's circumference $C$, circle's area $A_{c}$ is: \[ - A_{c} = \frac{C^2}{4\pi} + A_{circle} = \frac{C^2}{4\pi} \] - \item Compactness index is $\frac{A_p}{A_c}$: + \item Compactness index $c$ is are of the polygon divided by the area of the + circle: \[ - cmp = \frac{A_p}{A_c} = - \frac{A_p}{ \frac{C^2}{4\pi} } = - \frac{4\pi A_p}{C^2} + c = \frac{A_{p}}{A_{c}} = + \frac{A_{p}}{ \frac{C^2}{4\pi} } = + \frac{4\pi A_{p}}{C^2} \] \end{enumerate} @@ -812,11 +813,11 @@ of properties, upon which actions later will be performed. \subsection{Shape of a Bend} \label{sec:shape-of-a-bend} -This section introduces \textsc{adjusted size}, which trivially derives from -\textsc{compactness index} $cmp$ and shape's area $A$: +This section introduces \textsc{adjusted size} $A_{adj}$, which trivially +derives from \textsc{compactness index} $c$ and "polygonized" bend's area $A_{p}$: \[ - adjsize = \frac{0.75 A}{cmp} + A_{adj} = \frac{0.75 A_{p}}{c} \] Adjusted size becomes necessary later to compare bends with each other, and @@ -848,19 +849,19 @@ Two conditions must be true to claim that a bend is isolated: To find out whether two bends are similar, they are compared by 3 components: \begin{enumerate} - \item \textsc{adjusted size} - \item \textsc{compactness index} - \item Baseline length + \item \textsc{adjusted size} $A_{adj}$ + \item \textsc{compactness index} $c$ + \item \textsc{Baseline length} $l$ \end{enumerate} Components 1, 2 and 3 represent a point in a 3-dimensional space, and Euclidean -distance $d$ between those is calculated to differentiate between bends $p$ and +distance $d(p,q)$ between those is calculated to differentiate bends $p$ and $q$: \[ - d(p,q) = \sqrt{(adjsize_p-adjsize_q)^2 + - (cmp_p-cmp_q)^2 + - (baseline_p-baseline_q)^2} + d(p,q) = \sqrt{(A_{adj(p)}-A_{adj(q)})^2 + + (c_p-c_q)^2 + + (l_p-l_q)^2} \] The smaller the distance $d$, the more similar the bends are.