Difference between revisions of "HowToEnterMathSymbols"

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Line 47: Line 47:
 
</syntaxhighlight>
 
</syntaxhighlight>
 
(Which comes from a preprint of ''Jon M. Borwein, et. al. Some arithmetic properties of short random walk integrals.'')
 
(Which comes from a preprint of ''Jon M. Borwein, et. al. Some arithmetic properties of short random walk integrals.'')
 
  +
This renders as http://www.cs.kuleuven.be/~dirkn/Extension_MathJax/MathJaxExample.png.
+
This renders as http://www.cs.kuleuven.be/~dirkn/Extension_MathJax/MathJaxExample.png.
   
 
<!-- some LaTeX macros we want to use: -->
 
<!-- some LaTeX macros we want to use: -->
Line 56: Line 56:
 
$
 
$
   
We consider, for various values of $s$, the $n$-dimensional integral
+
We consider, for various values of $s$, the $n$-dimensional integral
\begin{align}
+
\begin{align}
\label{def:Wns}
+
\label{def:Wns}
W_n (s)
+
W_n (s)
&:=
+
&:=
\int_{[0, 1]^n}
+
\int_{[0, 1]^n}
\left| \sum_{k = 1}^n \mathrm{e}^{2 \pi \mathrm{i} \, x_k} \right|^s \mathrm{d}\boldsymbol{x}
+
\left| \sum_{k = 1}^n \mathrm{e}^{2 \pi \mathrm{i} \, x_k} \right|^s \mathrm{d}\boldsymbol{x}
\end{align}
+
\end{align}
which occurs in the theory of uniform random walk integrals in the plane,
+
which occurs in the theory of uniform random walk integrals in the plane,
where at each step a unit-step is taken in a random direction. As such,
+
where at each step a unit-step is taken in a random direction. As such,
the integral \eqref{def:Wns} expresses the $s$-th moment of the distance
+
the integral \eqref{def:Wns} expresses the $s$-th moment of the distance
to the origin after $n$ steps.
+
to the origin after $n$ steps.
+
By experimentation and some sketchy arguments we quickly conjectured and
+
By experimentation and some sketchy arguments we quickly conjectured and
strongly believed that, for $k$ a nonnegative integer
+
strongly believed that, for $k$ a nonnegative integer
\begin{align}
+
\begin{align}
\label{eq:W3k}
+
\label{eq:W3k}
W_3(k) &= \Re \, \pFq32{\frac12, -\frac k2, -\frac k2}{1, 1}{4}.
+
W_3(k) &= \Re \, \pFq32{\frac12, -\frac k2, -\frac k2}{1, 1}{4}.
\end{align}
+
\end{align}
Appropriately defined, \eqref{eq:W3k} also holds for negative odd integers.
+
Appropriately defined, \eqref{eq:W3k} also holds for negative odd integers.
The reason for \eqref{eq:W3k} was long a mystery, but it will be explained
+
The reason for \eqref{eq:W3k} was long a mystery, but it will be explained
at the end of the paper.
+
at the end of the paper.
   
 
This documentation comes from the [http://www.mediawiki.org/wiki/Extension:MathJax MathJax Extension page]. Additional documentation on using MathJax can be found at www.mathjax.org.
 
This documentation comes from the [http://www.mediawiki.org/wiki/Extension:MathJax MathJax Extension page]. Additional documentation on using MathJax can be found at www.mathjax.org.

Revision as of 09:56, 24 July 2012

We use the MathJax Extension by Dirk Nuyens. This extension enables MathJax (http://www.mathjax.org/) which is a Javascript library written by Davide Cervone.

Usage

The following math environments are defined for inline style math:

  • $...$ (can be turned off, even per page),
  • \(...\) and
  • <math>...</math>.

And the following math environments are defined for display style math:

  • $$...$$ (can be turned off, even per page),
  • \[...\],
  • \begin{...}...\end{...} and
  • :<math>...</math>.

MathJax produces nice and scalable mathematics, see their website (http://www.mathjax.org/) for a demonstration. This extension also enables the usage of \label{} and \eqref{} tags with automatic formula numbering. If needed you can still hand label by using \tag{}.

This extension allows for typical LaTeX math integration. For example: <syntaxhighlight lang="latex"> $

 \newcommand{\Re}{\mathrm{Re}\,}
 \newcommand{\pFq}[5]{{}_{#1}\mathrm{F}_{#2} \left( \genfrac{}{}{0pt}{}{#3}{#4} \bigg| {#5} \right)}

$

We consider, for various values of $s$, the $n$-dimensional integral \begin{align}

 \label{def:Wns}
 W_n (s)
 &:=
 \int_{[0, 1]^n}
   \left| \sum_{k = 1}^n \mathrm{e}^{2 \pi \mathrm{i} \, x_k} \right|^s \mathrm{d}\boldsymbol{x}

\end{align} which occurs in the theory of uniform random walk integrals in the plane, where at each step a unit-step is taken in a random direction. As such, the integral \eqref{def:Wns} expresses the $s$-th moment of the distance to the origin after $n$ steps.

By experimentation and some sketchy arguments we quickly conjectured and strongly believed that, for $k$ a nonnegative integer \begin{align}

 \label{eq:W3k}
 W_3(k) &= \Re \, \pFq32{\frac12, -\frac k2, -\frac k2}{1, 1}{4}.

\end{align} Appropriately defined, \eqref{eq:W3k} also holds for negative odd integers. The reason for \eqref{eq:W3k} was long a mystery, but it will be explained at the end of the paper. </syntaxhighlight> (Which comes from a preprint of Jon M. Borwein, et. al. Some arithmetic properties of short random walk integrals.)

This renders as http://www.cs.kuleuven.be/~dirkn/Extension_MathJax/MathJaxExample.png.

$

 \newcommand{\Re}{\mathrm{Re}\,}
 \newcommand{\pFq}[5]{{}_{#1}\mathrm{F}_{#2} \left( \genfrac{}{}{0pt}{}{#3}{#4} \bigg| {#5} \right)}

$

We consider, for various values of $s$, the $n$-dimensional integral
\begin{align}
  \label{def:Wns}
  W_n (s)
  &:=
  \int_{[0, 1]^n}
    \left| \sum_{k = 1}^n \mathrm{e}^{2 \pi \mathrm{i} \, x_k} \right|^s \mathrm{d}\boldsymbol{x}
\end{align}
which occurs in the theory of uniform random walk integrals in the plane,
where at each step a unit-step is taken in a random direction.  As such,
the integral \eqref{def:Wns} expresses the $s$-th moment of the distance
to the origin after $n$ steps.

By experimentation and some sketchy arguments we quickly conjectured and
strongly believed that, for $k$ a nonnegative integer
\begin{align}
  \label{eq:W3k}
  W_3(k) &= \Re \, \pFq32{\frac12, -\frac k2, -\frac k2}{1, 1}{4}.
\end{align}
Appropriately defined, \eqref{eq:W3k} also holds for negative odd integers.
The reason for \eqref{eq:W3k} was  long a mystery, but it will be explained
at the end of the paper.

This documentation comes from the MathJax Extension page. Additional documentation on using MathJax can be found at www.mathjax.org.