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Based on the original Rocket Workbench on SourceForge in CVS at: https://sourceforge.net/projects/rocketworkbench
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RocketWorkbench/rocketworkbench/Documentation/gba/star/html/images.tex

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\batchmode
\documentclass[11pt,titlepage]{article}
\RequirePackage{ifthen}
\usepackage{amsmath,graphicx}
\usepackage[dvips]{color}
\pagecolor[gray]{.7}
\usepackage[]{inputenc}
\makeatletter
\makeatletter
\count@=\the\catcode`\_ \catcode`\_=8
\newenvironment{tex2html_wrap}{}{}%
\catcode`\<=12\catcode`\_=\count@
\newcommand{\providedcommand}[1]{\expandafter\providecommand\csname #1\endcsname}%
\newcommand{\renewedcommand}[1]{\expandafter\providecommand\csname #1\endcsname{}%
\expandafter\renewcommand\csname #1\endcsname}%
\newcommand{\newedenvironment}[1]{\newenvironment{#1}{}{}\renewenvironment{#1}}%
\let\newedcommand\renewedcommand
\let\renewedenvironment\newedenvironment
\makeatother
\let\mathon=$
\let\mathoff=$
\ifx\AtBeginDocument\undefined \newcommand{\AtBeginDocument}[1]{}\fi
\newbox\sizebox
\setlength{\hoffset}{0pt}\setlength{\voffset}{0pt}
\addtolength{\textheight}{\footskip}\setlength{\footskip}{0pt}
\addtolength{\textheight}{\topmargin}\setlength{\topmargin}{0pt}
\addtolength{\textheight}{\headheight}\setlength{\headheight}{0pt}
\addtolength{\textheight}{\headsep}\setlength{\headsep}{0pt}
\setlength{\textwidth}{349pt}
\newwrite\lthtmlwrite
\makeatletter
\let\realnormalsize=\normalsize
\global\topskip=2sp
\def\preveqno{}\let\real@float=\@float \let\realend@float=\end@float
\def\@float{\let\@savefreelist\@freelist\real@float}
\def\liih@math{\ifmmode$\else\bad@math\fi}
\def\end@float{\realend@float\global\let\@freelist\@savefreelist}
\let\real@dbflt=\@dbflt \let\end@dblfloat=\end@float
\let\@largefloatcheck=\relax
\let\if@boxedmulticols=\iftrue
\def\@dbflt{\let\@savefreelist\@freelist\real@dbflt}
\def\adjustnormalsize{\def\normalsize{\mathsurround=0pt \realnormalsize
\parindent=0pt\abovedisplayskip=0pt\belowdisplayskip=0pt}%
\def\phantompar{\csname par\endcsname}\normalsize}%
\def\lthtmltypeout#1{{\let\protect\string \immediate\write\lthtmlwrite{#1}}}%
\newcommand\lthtmlhboxmathA{\adjustnormalsize\setbox\sizebox=\hbox\bgroup\kern.05em }%
\newcommand\lthtmlhboxmathB{\adjustnormalsize\setbox\sizebox=\hbox to\hsize\bgroup\hfill }%
\newcommand\lthtmlvboxmathA{\adjustnormalsize\setbox\sizebox=\vbox\bgroup %
\let\ifinner=\iffalse \let\)\liih@math }%
\newcommand\lthtmlboxmathZ{\@next\next\@currlist{}{\def\next{\voidb@x}}%
\expandafter\box\next\egroup}%
\newcommand\lthtmlmathtype[1]{\gdef\lthtmlmathenv{#1}}%
\newcommand\lthtmllogmath{\lthtmltypeout{l2hSize %
:\lthtmlmathenv:\the\ht\sizebox::\the\dp\sizebox::\the\wd\sizebox.\preveqno}}%
\newcommand\lthtmlfigureA[1]{\let\@savefreelist\@freelist
\lthtmlmathtype{#1}\lthtmlvboxmathA}%
\newcommand\lthtmlpictureA{\bgroup\catcode`\_=8 \lthtmlpictureB}%
\newcommand\lthtmlpictureB[1]{\lthtmlmathtype{#1}\egroup
\let\@savefreelist\@freelist \lthtmlhboxmathB}%
\newcommand\lthtmlpictureZ[1]{\hfill\lthtmlfigureZ}%
\newcommand\lthtmlfigureZ{\lthtmlboxmathZ\lthtmllogmath\copy\sizebox
\global\let\@freelist\@savefreelist}%
\newcommand\lthtmldisplayA{\bgroup\catcode`\_=8 \lthtmldisplayAi}%
\newcommand\lthtmldisplayAi[1]{\lthtmlmathtype{#1}\egroup\lthtmlvboxmathA}%
\newcommand\lthtmldisplayB[1]{\edef\preveqno{(\theequation)}%
\lthtmldisplayA{#1}\let\@eqnnum\relax}%
\newcommand\lthtmldisplayZ{\lthtmlboxmathZ\lthtmllogmath\lthtmlsetmath}%
\newcommand\lthtmlinlinemathA{\bgroup\catcode`\_=8 \lthtmlinlinemathB}
\newcommand\lthtmlinlinemathB[1]{\lthtmlmathtype{#1}\egroup\lthtmlhboxmathA
\vrule height1.5ex width0pt }%
\newcommand\lthtmlinlineA{\bgroup\catcode`\_=8 \lthtmlinlineB}%
\newcommand\lthtmlinlineB[1]{\lthtmlmathtype{#1}\egroup\lthtmlhboxmathA}%
\newcommand\lthtmlinlineZ{\egroup\expandafter\ifdim\dp\sizebox>0pt %
\expandafter\centerinlinemath\fi\lthtmllogmath\lthtmlsetinline}
\newcommand\lthtmlinlinemathZ{\egroup\expandafter\ifdim\dp\sizebox>0pt %
\expandafter\centerinlinemath\fi\lthtmllogmath\lthtmlsetmath}
\newcommand\lthtmlindisplaymathZ{\egroup %
\centerinlinemath\lthtmllogmath\lthtmlsetmath}
\def\lthtmlsetinline{\hbox{\vrule width.1em \vtop{\vbox{%
\kern.1em\copy\sizebox}\ifdim\dp\sizebox>0pt\kern.1em\else\kern.3pt\fi
\ifdim\hsize>\wd\sizebox \hrule depth1pt\fi}}}
\def\lthtmlsetmath{\hbox{\vrule width.1em\kern-.05em\vtop{\vbox{%
\kern.1em\kern0.8 pt\hbox{\hglue.17em\copy\sizebox\hglue0.8 pt}}\kern.3pt%
\ifdim\dp\sizebox>0pt\kern.1em\fi \kern0.8 pt%
\ifdim\hsize>\wd\sizebox \hrule depth1pt\fi}}}
\def\centerinlinemath{%
\dimen1=\ifdim\ht\sizebox<\dp\sizebox \dp\sizebox\else\ht\sizebox\fi
\advance\dimen1by.5pt \vrule width0pt height\dimen1 depth\dimen1
\dp\sizebox=\dimen1\ht\sizebox=\dimen1\relax}
\def\lthtmlcheckvsize{\ifdim\ht\sizebox<\vsize
\ifdim\wd\sizebox<\hsize\expandafter\hfill\fi \expandafter\vfill
\else\expandafter\vss\fi}%
\providecommand{\selectlanguage}[1]{}%
\makeatletter \tracingstats = 1
\providecommand{\Eta}{\textrm{H}}
\providecommand{\Mu}{\textrm{M}}
\providecommand{\Alpha}{\textrm{A}}
\providecommand{\Iota}{\textrm{J}}
\providecommand{\Nu}{\textrm{N}}
\providecommand{\Omicron}{\textrm{O}}
\providecommand{\omicron}{\textrm{o}}
\providecommand{\Chi}{\textrm{X}}
\providecommand{\Beta}{\textrm{B}}
\providecommand{\Kappa}{\textrm{K}}
\providecommand{\Tau}{\textrm{T}}
\providecommand{\Epsilon}{\textrm{E}}
\providecommand{\Zeta}{\textrm{Z}}
\providecommand{\Rho}{\textrm{R}}
\begin{document}
\pagestyle{empty}\thispagestyle{empty}\lthtmltypeout{}%
\lthtmltypeout{latex2htmlLength hsize=\the\hsize}\lthtmltypeout{}%
\lthtmltypeout{latex2htmlLength vsize=\the\vsize}\lthtmltypeout{}%
\lthtmltypeout{latex2htmlLength hoffset=\the\hoffset}\lthtmltypeout{}%
\lthtmltypeout{latex2htmlLength voffset=\the\voffset}\lthtmltypeout{}%
\lthtmltypeout{latex2htmlLength topmargin=\the\topmargin}\lthtmltypeout{}%
\lthtmltypeout{latex2htmlLength topskip=\the\topskip}\lthtmltypeout{}%
\lthtmltypeout{latex2htmlLength headheight=\the\headheight}\lthtmltypeout{}%
\lthtmltypeout{latex2htmlLength headsep=\the\headsep}\lthtmltypeout{}%
\lthtmltypeout{latex2htmlLength parskip=\the\parskip}\lthtmltypeout{}%
\lthtmltypeout{latex2htmlLength oddsidemargin=\the\oddsidemargin}\lthtmltypeout{}%
\makeatletter
\if@twoside\lthtmltypeout{latex2htmlLength evensidemargin=\the\evensidemargin}%
\else\lthtmltypeout{latex2htmlLength evensidemargin=\the\oddsidemargin}\fi%
\lthtmltypeout{}%
\makeatother
\setcounter{page}{1}
\onecolumn
% !!! IMAGES START HERE !!!
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline767}%
$ L$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline771}%
$ r_2$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
\stepcounter{section}
\stepcounter{section}
{\newpage\clearpage
\lthtmlpictureA{tex2html_wrap463}%
\includegraphics[height=5in]{img/variable.ps}%
\lthtmlpictureZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay779}%
$\displaystyle w$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay780}%
$\displaystyle =$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay781}%
$\displaystyle r_1$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay783}%
$\displaystyle r_2$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay785}%
$\displaystyle R$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay787}%
$\displaystyle \eta$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay789}%
$\displaystyle \varepsilon$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay791}%
$\displaystyle N$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlpictureA{tex2html_wrap471}%
\includegraphics[height=4in]{img/mainstar.ps}%
\lthtmlpictureZ
\lthtmlcheckvsize\clearpage}
\stepcounter{section}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline799}%
$ w_x$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
\stepcounter{subsection}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline802}%
$ r_1$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline804}%
$ R-w+w_x$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline806}%
$ (R-w+w_x)(\pi/N - \varepsilon)$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline810}%
$ a$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline812}%
$ (r_1+w_x)a$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlpictureA{tex2html_wrap489}%
\includegraphics[height=5in]{img/starL.ps}%
\lthtmlpictureZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline828}%
$ x + y$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay829}%
$\displaystyle b + z$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay830}%
$\displaystyle = (R-w-r_1)\sin{\varepsilon}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay831}%
$\displaystyle x$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay832}%
$\displaystyle = (r_1+w_x)\tan{\eta}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay833}%
$\displaystyle \cos{\eta}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay834}%
$\displaystyle = \frac{r_1+w_x}{z}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay835}%
$\displaystyle \sin{\eta}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay836}%
$\displaystyle = \frac{b}{y}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay838}%
$\displaystyle = \frac{(R-w-r_1)\sin{\varepsilon} - \frac{r_1+w_x}{\cos{\eta}}}{y}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay839}%
$\displaystyle L = y + x$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay840}%
$\displaystyle = (R-w-r_1)\frac{\sin{\varepsilon}}{\sin{\eta}} - \frac{r_1+w_x}{\cos{\eta}\sin{\eta}} + (r_1+w_x)\tan{\eta}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay841}%
$\displaystyle \sin^2{\eta} -1$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay842}%
$\displaystyle = -\cos^2{\eta}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay843}%
$\displaystyle \tan{\eta}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay844}%
$\displaystyle = \frac{1}{\tan{(\frac{\pi}{2}-\eta)}}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmldisplayA{displaymath846}%
\begin{displaymath}\begin{split} L &= (R-w-r_1)\frac{\sin{\varepsilon}}{\sin{\eta}} + (r_1+w_x)\left[ \frac{\sin^2{\eta}-1}{\cos{\eta}\sin{\eta}} \right]\\ &= (R-w-r_1)\frac{\sin{\varepsilon}}{\sin{\eta}} + (r_1+w_x)\left[ \frac{-\cos{\eta}}{\sin{\eta}} \right]\\ &= (R-w-r_1)\frac{\sin{\varepsilon}}{\sin{\eta}} + (r_1+w_x)\left[ \frac{-1}{\tan{\eta}} \right]\\ &= (R-w-r_1)\frac{\sin{\varepsilon}}{\sin{\eta}} - (r_1+w_x)\tan{(\frac{\pi}{2}-\eta)}\\ \end{split}\end{displaymath}%
\lthtmldisplayZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlpictureA{tex2html_wrap507}%
\includegraphics[height=3in]{img/arc.ps}%
\lthtmlpictureZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay856}%
$\displaystyle = (r_2-wx)(\frac{\pi}{2}-\eta)$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay858}%
$\displaystyle x = \frac{r_2-wx}{\tan{\eta}}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline862}%
$ 0 < w_x < r_2$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmldisplayA{displaymath864}%
\begin{displaymath}\begin{split} \frac{S}{2N} &= (R-w+w_x)(\frac{\pi}{N} - \varepsilon) + (r_1+w_x)a+(R-w-r_1)\frac{\sin{\varepsilon}}{\sin{\eta}}\\ & \quad - (r_1+w_x)\tan{(\frac{\pi}{2}-\eta)} + (r_2-w_x)(\frac{\pi}{2}-\eta) \\ & \quad - (r_2-wx)\tan{(\frac{\pi}{2}-\eta)}\\ &= (R-w+w_x)(\frac{\pi}{N} - \varepsilon) + (r_1+w_x)a+(R-w-r_1)\frac{\sin{\varepsilon}}{\sin{\eta}}\\ & \quad - (r_1+r_2)\tan{(\frac{\pi}{2}-\eta)} + (r_2-w_x)(\frac{\pi}{2}-\eta)\\ \end{split}\end{displaymath}%
\lthtmldisplayZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay866}%
$\displaystyle \frac{\delta S}{\delta w_x} = 2N\left[ \frac{\pi}{N} - \varepsilon + a - \frac{\pi}{2} + \eta \right]$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay868}%
$\displaystyle a = \frac{\pi}{2} - \eta + \varepsilon$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay870}%
$\displaystyle \frac{\delta S}{\delta w_x} = 2\pi$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
\stepcounter{subsection}
{\newpage\clearpage
\lthtmldisplayA{displaymath877}%
\begin{displaymath}\begin{split} \frac{S}{2N} &= (R-w+w_x)(\frac{\pi}{N} - \varepsilon) + (r_1+w_x)a+(R-w-r_1)\frac{\sin{\varepsilon}}{\sin{\eta}}\\ & \quad - (r_1+w_x)\tan{(\frac{\pi}{2}-\eta)}\\ \end{split}\end{displaymath}%
\lthtmldisplayZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmldisplayA{displaymath879}%
\begin{displaymath}\begin{split} \frac{\delta S}{\delta w_x} &= 2N\left[ \frac{\pi}{N} -\varepsilon + a - \tan{(\frac{\pi}{2} - \eta)} \right]\\ &= 2N\left[ \frac{\pi}{2} - \eta + \frac{\pi}{N} - \tan{(\frac{\pi}{2} - \eta)} \right]\\ \end{split}\end{displaymath}%
\lthtmldisplayZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline881}%
$ \eta$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline883}%
$ N$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline885}%
$ \varepsilon$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay887}%
$\displaystyle \frac{\delta S}{\delta w_x} = 0 = \frac{\pi}{2} - \eta + \frac{\pi}{N} - \tan{(\frac{\pi}{2} - \eta)}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay893}%
$\displaystyle \eta = \frac{\pi}{N} - \tan{(\frac{\pi}{2} - \eta)} + \frac{\pi}{2}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline901}%
$ \pi/N$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline927}%
$ \eta < \pi/N$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline929}%
$ \varepsilon < \pi/N$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
\stepcounter{subsection}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline936}%
$ w_x = Y*$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay940}%
$\displaystyle \frac{S}{2N} = (R-w+w_x)(\frac{\pi}{N}-\varepsilon) + (r_1+w_x)\left[ \varepsilon + \arcsin{(\frac{R-w-r_1}{r_1+w_x}\sin{\varepsilon}}) \right]$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmldisplayA{displaymath942}%
\begin{displaymath}\begin{split} \frac{\delta S}{\delta w_x} &= 2N \biggl[ \frac{\pi}{N} + \arcsin{\biggl(\frac{R-w-r_1}{r_1+w_x}\sin{\varepsilon}\biggr)} - \\ &\quad \frac{w_x(R-w-r_1)\sin{\varepsilon}}{(r_1+w_x)^2\sqrt{1-\frac{(R-w-r_1)^2\sin^2{\varepsilon}}{(r_1+w_x)^2}}} \biggr]\\ \end{split}\end{displaymath}%
\lthtmldisplayZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay944}%
$\displaystyle Y* = (R-w-r_1)\frac{\sin{\varepsilon}}{\cos{\eta}} - r_1 = w$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay946}%
$\displaystyle \sin{\varepsilon} = \frac{w+r_1}{R-w-r_1}\cos{\eta}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline950}%
$ w$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
\stepcounter{subsection}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay965}%
$\displaystyle c^2 = a^2 + b^2 - 2ab\cos{\theta}$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmldisplayA{displaymath967}%
\begin{displaymath}\begin{split} \frac{S}{2N} = (r_1+w_x) \biggl[ & \varepsilon + \arcsin{\biggl(\frac{R-w-r_1}{r_1+w_x}\sin{\varepsilon}\biggr)} - \pi\\ & \quad + \arccos{\biggl(\frac{(r_1+w_x)^2+(R-r_1-w)^2-R^2}{2(r_1+w_x)(R-r_1-w)}\biggr)} \biggr]\\ \end{split}\end{displaymath}%
\lthtmldisplayZ
\lthtmlcheckvsize\clearpage}
\stepcounter{section}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline970}%
$ 3 inch$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline984}%
$ N=6$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline986}%
$ \eta >
\pi/N$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay988}%
$\displaystyle N = 6$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay990}%
$\displaystyle \eta = 33.53 deg$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay992}%
$\displaystyle \varepsilon = 30 deg$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_inline998}%
$ r_1 = 1/16 in$%
\lthtmlinlinemathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlinlinemathA{tex2html_wrap_indisplay1004}%
$\displaystyle w = 0.500$%
\lthtmlindisplaymathZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlpictureA{tex2html_wrap617}%
\includegraphics[]{img/res.ps}%
\lthtmlpictureZ
\lthtmlcheckvsize\clearpage}
{\newpage\clearpage
\lthtmlpictureA{tex2html_wrap625}%
\includegraphics[height=4in]{img/perimeter.ps}%
\lthtmlpictureZ
\lthtmlcheckvsize\clearpage}
\stepcounter{section}
\end{document}