%%
%% This is file `statex.sty'.
%%
%% Copyright (C) 2002-2006 by Rodney A Sparapani <rsparapa@mcw.edu>
%%
%% This file may be distributed and/or modified under the
%% conditions of the LaTeX Project Public License, either version 1.2
%% of this license or (at your option) any later version.
%% The latest version of this license is in
%%
%% http://www.latex-project.org/lppl.txt
%%
%% and version 1.2 or later is part of all distributions of LaTeX
%% version 1999/12/01 or later.
%%
\NeedsTeXFormat{LaTeX2e}
\ProvidesPackage{statex}[2006/05/17 v1.6 a statistics style for latex]
\RequirePackage{ifthen}
\RequirePackage{amsmath}
\RequirePackage{amssymb}
\RequirePackage{bm}
\RequirePackage{color}
%\RequirePackage[dvipsnames,usenames]{color}
%begin: borrowed from upgreek; thanks to Walter Schmidt <was@VR-Web.de>
%use Adobe Symbol for upright pi (constant)
\DeclareSymbolFont{ugrf@m}{U}{psy}{m}{n}
\DeclareMathSymbol{\cpi}{\mathord}{ugrf@m}{`p}
%to use Euler Roman comment previous lines and uncomment rest of block
% \DeclareFontFamily{U}{eur}{\skewchar\font'177}
% \DeclareFontShape{U}{eur}{m}{n}{%
% <-6> eurm5 <6-8> eurm7 <8-> eurm10}{}
% \DeclareFontShape{U}{eur}{b}{n}{%
% <-6> eurb5 <6-8> eurb7 <8-> eurb10}{}
% \DeclareSymbolFont{ugrf@m}{U}{eur}{m}{n}
% \SetSymbolFont{ugrf@m}{bold}{U}{eur}{b}{n}
% \DeclareMathSymbol{\cpi}{\mathord}{ugrf@m}{"19}
%end
%new commands
\DeclareMathAlphabet{\sfsl}{OT1}{cmss}{m}{sl}
%the next command seems to have no effect when used in conjunction with bm!?!
\SetMathAlphabet{\sfsl}{bold}{OT1}{cmss}{bx}{sl}
\DeclareMathOperator{\logit}{logit}
\DeclareMathOperator{\diag}{diag}
\DeclareMathOperator{\erf}{erf}
\newcommand*{\chisq}{\relax\ifmmode\chi^2\else$\chi^2$\fi}
%\newcommand*{\e}[1]{\mathrm{e}\ifthenelse{\equal{#1}{}}{}{^{#1}}}
\newcommand*{\e}[1]{\mathrm{e}^{#1}}
%\newcommand*{\exp}[1]{\mathrm{e}^{#1}}
\newcommand*{\E}[2][]{\text{E}\ifthenelse{\equal{#1}{}}{}{_{#1}} \wrap{#2}}
\newcommand*{\ha}{{\frac{\alpha}{2}}}
\newcommand*{\I}[2][]{\text{I}\ifthenelse{\equal{#1}{}}{}{_{#1}} \wrap[()]{#2}}
\newcommand*{\IBeta}[2]{\frac{\Gamma[#1+#2]}{\Gamma[#1]\Gamma[#2]}}
\newcommand*{\If}{\;\text{if}\;\;}
%\newcommand*{\ij}{{i,j}}
\newcommand*{\im}{\mathrm{i}}
%\newcommand*{\lb}{\left[}
%\newcommand*{\lp}{\left(}
%\newcommand*{\lr}[1][]{\left[ #1 \right]}
\newcommand*{\ol}{\overline}
\newcommand*{\ow}{\;\text{otherwise}\;\;}
\newcommand*{\rb}{\right]}
\newcommand*{\rp}{\right)}
\newcommand*{\sd}{\sigma}
\newcommand*{\ul}{\underline}
\newcommand*{\V}[2][]{\text{V}\ifthenelse{\equal{#1}{}}{}{_{#1}} \wrap{#2}}
\newcommand*{\where}{\;\;\text{where}\;\;}
\newcommand*{\wrap}[2][]%
{\ifthenelse{\equal{#1}{}}{\left[ #2 \right]}%
{\ifthenelse{\equal{#1}{()}}{\left( #2 \right)}%
{\ifthenelse{\equal{#1}{\{\}}}{\left\{ #2 \right\}}%
%{\ifthenelse{\equal{#1}{(.}}{\left( #2 \right.}%
%{\ifthenelse{\equal{#1}{[.}}{\left[ #2 \right.}%
{\ifthenelse{\equal{#1}{\{.}}{\left\{ #2 \right.}{}}}}}
\newcommand*{\xy}{{xy}}
\newcommand*{\XY}{{XY}}
%\newcommand*{\n}[1][]{_{n #1}}
%\def\bp(#1){\left(#1\right)}
%\newcommand*{\bb}[1][]{\left[ #1 \right]}
%re-definitions
%\def~{\relax\ifmmode\sim\else\nobreakspace{}\fi}
\renewcommand*{~}{\relax\ifmmode\sim\else\nobreakspace{}\fi}
\newcommand*{\iid}{\;\stackrel{\text{iid}}{~}\;}
\newcommand*{\ind}{\;\stackrel{\text{ind}}{~}\;}
\newcommand*{\indpr}{\;\stackrel{\text{ind}}{\stackrel{\text{prior}}{~}}\;}
\newcommand*{\post}{\;\stackrel{\text{post}}{~}\;}
\newcommand*{\prior}{\;\stackrel{\text{prior}}{~}\;}
%\let\STATEXi=\i
%\renewcommand*{\i}[1][]{\ifthenelse{\equal{#1}{}}{\STATEXi}{_{i #1}}}
\let\STATEXGamma=\Gamma
\renewcommand*{\Gamma}[1][]{\STATEXGamma\ifthenelse{\equal{#1}{}}{}{\wrap[()]{#1}}}
\let\STATEXand=\and
\renewcommand*{\and}{\relax\ifmmode\expandafter\;\;\text{and}\;\;\else\expandafter\STATEXand\fi}
\let\STATEXH=\H
\renewcommand*{\H}{\relax\ifmmode\expandafter\text{H}\else\expandafter\STATEXH\fi}
\let\STATEXP=\P
\renewcommand*{\P}[2][]{\ifthenelse{\equal{#2}{}}{\STATEXP}%
{\text{P}\ifthenelse{\equal{#1}{}}{}{_{#1}}\wrap{#2}}}
\renewcommand*{\|}{\relax\ifmmode\expandafter\mid\else\expandafter$\mid$\fi}
%%Discrete distributions
%declarations
\newcommand*{\B}[1]{\mathrm{B}\wrap[()]{#1}}
\newcommand*{\BB}[1]{\mathrm{Beta\!-\!Bin}\wrap[()]{#1}}
\newcommand*{\Bin}[1]{\mathrm{Bin}\wrap[()]{#1}}
\newcommand*{\Dir}[1]{\mathrm{Dirichlet}\wrap[()]{#1}}
\newcommand*{\HG}[1]{\mathrm{Hypergeometric}\wrap[()]{#1}}
\newcommand*{\M}[1]{\mathrm{Multinomial}\wrap[()]{#1}}
\newcommand*{\NB}[1]{\mathrm{Neg\!-\!Bin}\wrap[()]{#1}}
\newcommand*{\Poi}[1]{\mathrm{Poisson}\wrap[()]{#1}}
\let\Poisson=\Poi
%probability mass functions
\newcommand*{\pBB}[4][x]{\frac{\Gamma[#2+1]\Gamma[#3+#1]\Gamma[#2+#4-#1]\Gamma[#3+#4]}%
{\Gamma[#1+1]\Gamma[#2-#1+1]\Gamma[#2+#3+#4]\Gamma[#3]\Gamma[#4]}%
\I[#1]{\{0, 1,\., #2\}}, \where #3>0,\; #4>0 \and n=1, 2,\.}
%\newcommand{\pBB}[4][x]{\frac{\Gamma[#2+1]}{\Gamma[#1+1]\Gamma[#2-#1+1]}%
%\frac{\Gamma[#3+#1]\Gamma[#2+#4-#1]}{\Gamma[#2+#3+#4]}%
%\frac{\Gamma[#3+#4]}{\Gamma[#3]\Gamma[#4]}\I[#1]{\{0, 1,\., #2\}},%
%\where #3>0,\; #4>0 \and n=1, 2,\.}
\newcommand*{\pBin}[3][x]{\binom{#2}{#1}#3^#1 \wrap[()]{1-#3}^{#2-#1}%
\I[#1]{\{0,1,\.,#2\}}, \where p \in \wrap[()]{0, 1} \and n=1, 2,\.}
\newcommand*{\pPoi}[2][x]{\frac{1}{#1!}#2^{#1}\e{-#2}\I[#1]{\{0, 1,\.\}}, \where #2>0}
%%Continuous distributions
%declarations
\newcommand*{\Cau}[1]{\mathrm{Cauchy}\wrap[()]{#1}}
\let\Cauchy=\Cau
\newcommand*{\Chi}[1]{\mathrm{\chi^2}\wrap[()]{#1}}
\let\Chisq=\Chi
\newcommand*{\Bet}[1]{\mathrm{Beta}\wrap[()]{#1}}
\let\Beta=\Bet
\newcommand*{\Exp}[1]{\mathrm{Exp}\wrap[()]{#1}}
\newcommand*{\F}[1]{\mathrm{F}\wrap[()]{#1}}
\newcommand*{\Gam}[1]{\mathrm{Gamma}\wrap[()]{#1}}
\newcommand*{\IC}[1]{\mathrm{\chi^{-2}}\wrap[()]{#1}}
\newcommand*{\IG}[1]{\mathrm{Gamma^{-1}}\wrap[()]{#1}}
\newcommand*{\IW}[1]{\mathrm{Wishart^{-1}}\wrap[()]{#1}}
\newcommand*{\Log}[1]{\mathrm{Logistic}\wrap[()]{#1}}
\newcommand*{\LogN}[1]{\mathrm{Log\!-\!N}\wrap[()]{#1}}
\newcommand*{\N}[3][]{\mathrm{N}\ifthenelse{\equal{#1}{}}{}{_{#1}}\wrap[()]{#2,\ #3}}
\newcommand*{\Par}[1]{\mathrm{Pareto}\wrap[()]{#1}}
\let\Pareto=\Par
\newcommand*{\Tsq}[1]{\mathrm{T^2}\wrap[()]{#1}}
\newcommand*{\U}[1]{\mathrm{U}\wrap[()]{#1}}
\newcommand*{\W}[1]{\mathrm{Wishart}\wrap[()]{#1}}
\let\STATEXt=\t
\renewcommand*{\t}[1]{\relax\ifmmode\expandafter\mathrm{t}\wrap[()]{#1}%
\else\expandafter\STATEXt{#1}\fi}
%probability density functions
\newcommand*{\pBet}[3][x]{\IBeta{#2}{#3}%
#1^{#2-1}\wrap[()]{1-#1}^{#3-1}\I[#1]{0,\ 1}, \where #2>0 \and #3>0}
\newcommand*{\pCau}[3][x]{\ifthenelse{\equal{#2, #3}{0, 1}}{\frac{1}{\cpi\wrap[()]{1+#1}^2}}%
{\frac{1}{#3\cpi\left\{1+\wrap{\wrap[()]{x-#2}/#3}^2\right\}}, \where #3>0}}
\newcommand*{\pChi}[2][x]{\frac{2^{-#2/2}}{\Gamma[#2/2]}#1^{#2/2-1}\e{-#1/2}%
\I[#1]{0,\infty}, \where #2>0}
\newcommand*{\pExp}[2][x]{\frac{1}{#2}\e{-#1/#2}\I[#1]{0,\infty},%
\where #2>0}
\newcommand*{\pGam}[3][x]{\frac{#3^{#2}}{\Gamma[#2]}#1^{#2-1}\e{-#3#1}%
\I[#1]{0,\infty}, \where #2>0 \and #3>0}
\newcommand*{\pN}[3][x]{\ifthenelse{\equal{#2, #3}{0, 1}}%
{\frac{1}{\sqrt{2\cpi}}\e{-#1^2/2}}%
{\frac{1}{\sqrt{2\cpi#3}}\e{-\wrap[()]{#1-#2}^2/2#3}}}
\newcommand*{\pPar}[3][x]{\frac{#3}{#2\wrap[()]{1+#1/#2}^{#3+1}}\I[#1]{0,\infty},%
\where #2>0 \and #3>0}
\newcommand*{\pU}[3][x]{\ifthenelse{\equal{#2, #3}{0, 1}}{\I[#1]{0,\ 1}}%
{\frac{1}{#3-#2}\I[#1]{#2,\ #3}, \where #2<#3}}
%re-define other accents
\let\STATEXequal=\=
\renewcommand*{\=}{\relax\ifmmode\expandafter\bar\else\expandafter\STATEXequal\fi}
\let\STATEXhat=\^
\renewcommand*{\^}{\relax\ifmmode\expandafter\widehat\else\expandafter\STATEXhat\fi}
\let\STATEXtilde=\~
\renewcommand*{\~}{\relax\ifmmode\expandafter\widetilde\else\expandafter\STATEXtilde\fi}
\let\STATEXsinglequote=\'
\renewcommand*{\'}[1]{\relax\ifmmode\expandafter{\wrap[()]{#1}}\else\expandafter\STATEXsinglequote{#1}\fi}
\let\STATEXb=\b
\renewcommand*{\b}{\relax\ifmmode\expandafter\bar\else\expandafter\STATEXb\fi}
\let\STATEXc=\c
\renewcommand*{\c}[1]{\relax\ifmmode\expandafter\mathrm{#1}\else\expandafter\STATEXc{#1}\fi}
\let\STATEXd=\d
\renewcommand*{\d}[1]{\relax\ifmmode\expandafter\,\mathrm{d}#1\else\expandafter\STATEXd{#1}\fi}
\let\STATEXdot=\.
\renewcommand*{\.}{\relax\ifmmode\expandafter\dots\else\expandafter\STATEXdot\fi}
%commands to create documentation for TI-83 calculators
\newcommand*{\Alpha}[1][]{{\fcolorbox{black}{ForestGreen}{\color{white}\textsf{ALPHA}}}\textbf{\color{ForestGreen}\textsf{#1}}}
\newcommand*{\Alock}{\Snd[A-LOCK]}
\newcommand*{\Blackbox}{\relax\ifmmode\expandafter\blacksquare\else\expandafter$\blacksquare$\fi}
\newcommand*{\Distr}{\Snd[DISTR]}
\newcommand*{\Down}{\framebox{\footnotesize$^\Downarrow$}}
\newcommand*{\EE}{\Snd[EE]}
\newcommand*{\Enter}{\framebox{\textsf{ENTER}}}
\newcommand*{\Graph}{\framebox{\textsf{GRAPH}}}
\newcommand*{\List}[1]{\textbf{\color{Dandelion}\textsf{$\text{L}_#1$}}}
\newcommand*{\Left}{\framebox{$^\Leftarrow$}}
\newcommand*{\Math}{\framebox{\textsf{MATH}}}
\newcommand*{\Matrx}{\Snd[MATRX]}
\newcommand*{\Prgm}{\framebox{\textsf{PRGM}}}
\newcommand*{\Quit}{\Snd[QUIT]}
\newcommand*{\Rect}{\rule{4pt}{6pt}}
\newcommand*{\Right}{\framebox{$^\Rightarrow$}}
\newcommand*{\Snd}[1][]{{\fcolorbox{black}{Dandelion}{\color{white}\textsf{2nd}}}\textbf{\color{Dandelion}\textsf{#1}}}
\newcommand*{\Solve}{\Alpha[SOLVE]}
\newcommand*{\Stat}{\framebox{\textsf{STAT}}}
\newcommand*{\Statplot}{\Snd[STAT PLOT]}
\newcommand*{\Sto}{\framebox{\textsf{STO}$\Rightarrow$}}
\newcommand*{\Signm}{\framebox{\textsf{(-)}}}
\newcommand*{\Up}{\framebox{\footnotesize$^\Uparrow$}}
\newcommand*{\Window}{\framebox{\textsf{WINDOW}}}
\let\STATEXBox=\Box
\renewcommand*{\Box}{\relax\ifmmode\expandafter\STATEXBox\else\expandafter$\STATEXBox$\fi}
\let\STATEXto=\to
\renewcommand*{\to}{\relax\ifmmode\expandafter\STATEXto\else\expandafter$\STATEXto$\fi}
\endinput
\documentclass[dvipsnames,usenames]{report}
\usepackage{statex}
\usepackage{shortvrb}
\MakeShortVerb{@}
% Examples
\begin{document}
Many accents have been re-defined
@ c \c{c} \pi \cpi@ $$ c \c{c} \pi \cpi$$ %upright constants like the speed of light and 3.14159...
@int \e{\im x} \d{x}@ $$\int \e{\im x} \d{x}$$ %\d{x}; also note new commands \e and \im
@\^{\beta_1}=b_1@ $$\^{\beta_1}=b_1$$
@\=x=\frac{1}{n}\sum x_i@ $$\=x=\frac{1}{n}\sum x_i$$ %also, \b{x}, but see \ol{x} below
@\b{x} = \frac{1}{n} \wrap[()]{x_1 +\.+ x_n}@ $$\b{x} = \frac{1}{n} \wrap[()]{x_1 +\.+ x_n}$$
Sometimes overline is better: @\b{x}\ vs.\ \ol{x}@ $$\b{x}\ vs.\ \ol{x}$$
And, underlines are nice too: @\ul{x}@ $$\ul{x}$$
A few other nice-to-haves:
@\Gamma[n+1]=n!@ $$\Gamma[n+1]=n!$$
@\binom{n}{x}@ $$\binom{n}{x}$$ %provided by amsmath package
@\e{x}@ $$\e{x}$$
%$\H_0: \mu_\ij=0$ vs. $\H_1: \mu_\ij \neq 0$ %\ijk too
@\logit \wrap{p} = \log \wrap{\frac{p}{1-p}}@ $$\logit \wrap{p} = \log \wrap{\frac{p}{1-p}}$$
\pagebreak
Common distributions along with other features follows:
Normal Distribution
@Z ~ \N{0}{1}, \where \E{Z}=0 \and \V{Z}=1@ $$Z ~ \N{0}{1}, \where \E{Z}=0 \and \V{Z}=1$$
@\P{|Z|>z_\ha}=\alpha@ $$\P{|Z|>z_\ha}=\alpha$$
@\pN[z]{0}{1}@ $$\pN[z]{0}{1}$$
or, in general
@\pN[z]{\mu}{\sd^2}@ $$\pN[z]{\mu}{\sd^2}$$
Sometimes, we subscript the following operations:
@\E[z]{Z}=0, \V[z]{Z}=1, \and \P[z]{|Z|>z_\ha}=\alpha@ $$\E[z]{Z}=0, \V[z]{Z}=1, \and \P[z]{|Z|>z_\ha}=\alpha$$
Multivariate Normal Distribution
@\bm{X} ~ \N[p]{\bm{\mu}}{\sfsl{\Sigma}}@ $$\bm{X} ~ \N[p]{\bm{\mu}}{\sfsl{\Sigma}}$$ %\bm provided by the bm package
Chi-square Distribution
@Z_i \iid \N{0}{1}, \where i=1 ,\., n@ $$Z_i \iid \N{0}{1}, \where i=1 ,\., n$$
@\chisq = \sum_i Z_i^2 ~ \Chi{n}@ $$\chisq = \sum_i Z_i^2 ~ \Chi{n}$$
@\pChi[z]{n}@ $$\pChi[z]{n}$$
t Distribution
@\frac{\N{0}{1}}{\sqrt{\frac{\Chisq{n}}{n}}} ~ \t{n}@ $$\frac{\N{0}{1}}{\sqrt{\frac{\Chisq{n}}{n}}} ~ \t{n}$$
\pagebreak
F Distribution
@X_i, Y_{\~i} \iid \N{0}{1} \where i=1 ,\., n; \~i=1 ,\., m \and \V{X_i, Y_{\~i}}=\sd_\xy=0@ $$X_i, Y_{\~i} \iid \N{0}{1} \where i=1 ,\., n; \~i=1 ,\., m \and \V{X_i, Y_{\~i}}=\sd_\xy=0$$%\XY too
@\chisq_x = \sum_i X_i^2 ~ \Chi{n}@ $$\chisq_x = \sum_i X_i^2 ~ \Chi{n}$$
@\chisq_y = \sum_{\~i} Y_{\~i}^2 ~ \Chi{m}@ $$\chisq_y = \sum_{\~i} Y_{\~i}^2 ~ \Chi{m}$$
@\frac{\chisq_x}{\chisq_y} ~ \F{n, m}@ $$\frac{\chisq_x}{\chisq_y} ~ \F{n, m}$$
Beta Distribution
@B=\frac{\frac{n}{m}F}{1+\frac{n}{m}F} ~ \Bet{\frac{n}{2}, \frac{m}{2}}@ $$B=\frac{\frac{n}{m}F}{1+\frac{n}{m}F} ~ \Bet{\frac{n}{2}, \frac{m}{2}}$$
@\pBet{\alpha}{\beta}@ $$\pBet{\alpha}{\beta}$$
Gamma Distribution
@G ~ \Gam{\alpha, \beta}@ $$G ~ \Gam{\alpha, \beta}$$
@\pGam{\alpha}{\beta}@ $$\pGam{\alpha}{\beta}$$
Cauchy Distribution
@C ~ \Cau{\theta, \nu}@ $$C ~ \Cau{\theta, \nu}$$
@\pCau{\theta}{\nu}@ $$\pCau{\theta}{\nu}$$
Uniform Distribution
@X ~ \U{0, 1}@ $$X ~ \U{0, 1}$$
@\pU{0}{1}@ $$\pU{0}{1}$$
or, in general
@\pU{a}{b}@ $$\pU{a}{b}$$
Exponential Distribution
@X ~ \Exp{\lambda}@ $$X ~ \Exp{\lambda}$$
@\pExp{\lambda}@ $$\pExp{\lambda}$$
Hotelling's $T^2$ Distribution
@X ~ \Tsq{\nu_1, \nu_2}@ $$X ~ \Tsq{\nu_1, \nu_2}$$
Inverse Chi-square Distribution
@X ~ \IC{\nu}@ $$X ~ \IC{\nu}$$
Inverse Gamma Distribution
@X ~ \IG{\alpha, \beta}@ $$X ~ \IG{\alpha, \beta}$$
Pareto Distribution
@X ~ \Par{\alpha, \beta}@ $$X ~ \Par{\alpha, \beta}$$
@\pPar{\alpha}{\beta}@ $$\pPar{\alpha}{\beta}$$
Wishart Distribution
@\sfsl{X} ~ \W{\nu, \sfsl{S}}@ $$\sfsl{X} ~ \W{\nu, \sfsl{S}}$$
Inverse Wishart Distribution
@\sfsl{X} ~ \IW{\nu, \sfsl{S^{-1}}}@ $$\sfsl{X} ~ \IW{\nu, \sfsl{S^{-1}}}$$
Binomial Distribution
@X ~ \Bin{n, p}@ $$X ~ \Bin{n, p}$$
@\pBin{n}{p}@ $$\pBin{n}{p}$$
Bernoulli Distribution
@X ~ \B{p}@ $$X ~ \B{p}$$
Beta-Binomial Distribution
@X ~ \BB{p}@ $$X ~ \BB{p}$$
@\pBB{n}{\alpha}{\beta}@ $$\pBB{n}{\alpha}{\beta}$$
Negative-Binomial Distribution
@X ~ \NB{n, p}@ $$X ~ \NB{n, p}$$
Hypergeometric Distribution
@X ~ \HG{n, M, N}@ $$X ~ \HG{n, M, N}$$
Poisson Distribution
@X ~ \Poi{\mu}@ $$X ~ \Poi{\mu}$$
@\pPoi{\mu}@ $$\pPoi{\mu}$$
Dirichlet Distribution
@\bm{X} ~ \Dir{\alpha_1 \. \alpha_k}@ $$\bm{X} ~ \Dir{\alpha_1 \. \alpha_k}$$
Multinomial Distribution
@\bm{X} ~ \M{n, \alpha_1 \. \alpha_k}@ $$\bm{X} ~ \M{n, \alpha_1 \. \alpha_k}$$
\pagebreak
To compute critical values for the Normal distribution, create the
NCRIT program for your TI-83 (or equivalent) calculator. At each step, the
calculator display is shown, followed by what you should do (\Rect\ is the
cursor):\\
\Rect\\
\Prgm\to@NEW@\to@1:Create New@\\
@Name=@\Rect\\
NCRIT\Enter\\
@:@\Rect\\
\Prgm\to@I/O@\to@2:Prompt@\\
@:Prompt@ \Rect\\
\Alpha[A],\Alpha[T]\Enter\\
@:@\Rect\\
\Distr\to@DISTR@\to@3:invNorm(@\\
@:invNorm(@\Rect\\
1-(\Alpha[A]$\div$\Alpha[T]))\Sto\Alpha[C]\Enter\\
@:@\Rect\\
\Prgm\to@I/O@\to@3:Disp@\\
@:Disp@ \Rect\\
\Alpha[C]\Enter\\
@:@\Rect\\
\Quit\\
Suppose @A@ is $\alpha$ and @T@ is the number of tails. To run the program:\\
\Rect\\
\Prgm\to@EXEC@\to@NCRIT@\\
@prgmNCRIT@\Rect\\
\Enter\\
@A=?@\Rect\\
0.05\Enter\\
@T=?@\Rect\\
2\Enter\\
@1.959963986@
\end{document}