උදවු:Displaying a formula

සැකිල්ල:Redirect2 සැකිල්ල:Wikipedia how-to MediaWiki renders mathematical equations using a combination of html markup and a variant of LaTeX.

The version of LaTeX used is a subset of AMS-LaTeX markup, a superset of LaTeX markup which is in turn a superset of TeX markup, for mathematical formulae. Only a limited part of the full TeX language is supported; see below for details.සැකිල්ල:Efn

By default SVG images with non-visible MathML are generated. The older PNG images can be set via user preferences.සැකිල්ල:Efn On some browsers like Firefox, it is possible to use MathML for display via extensions; see the main extension page at mw:Extension:Math for details. Client side MathJax is no longer supported.

Math markup goes inside සැකිල්ල:Tag. Chemistry markup goes inside <math chem>...</math> or සැකිල්ල:Tag. All these tags use TeX.

The TeX code has to be put literally: MediaWiki templates, predefined templates, and parameters cannot be used within math tags: pairs of double braces are ignored and "#" gives an error message. However, math tags work in the then and else part of #if, etc. See සැකිල්ල:Tim for more information.

The now deprecated tag <ce> was considered too ambiguous, and it has been replaced by <chem>.^[1] A script will be used to replace all <ce> with <chem> ^[2]

LaTeX commands are case-sensitive, and take one of the following two formats:

• They start with a backslash \ and then have a name consisting of letters only. Command names are terminated by a space, a number or any other "non-letter".
• They consist of a backslash \ and exactly one non-letter.

Some commands need an argument, which has to be given between curly braces { } after the command name. Some commands support optional parameters, which are added after the command name in square brackets []. The general syntax is:

\commandname[option1,option2,...]{argument1}{argument2}...

The following symbols are reserved characters that either have a special meaning under LaTeX or are unavailable in all the fonts. If you enter them directly in your text, they will normally not render, but rather do things you did not intend.

# $ % ^ & _ { } ~ \

These characters can be entered by adding a prefix backslash or using special sequences:

\# \$ \% ^\wedge \& \_ \{ \} \sim \backslash

yielding

${\displaystyle \mathrm{\#}\mathrm{\$}{\mathrm{\%}}^{\wedge }\mathrm{\&}\mathrm{\_}\{\}\sim \mathrm{\setminus }}$.

The backslash character \ can not be entered by adding another backslash in front of it (\\); this sequence is used for line breaking. For introducing a backslash in math mode, you can use \backslash instead which gives ${\displaystyle \mathrm{\setminus }}$.

The command \tilde produces a tilde which is placed over the next letter. For example, \tilde{a} gives ${\displaystyle \tilde{a}}$. To produce just a tilde character ~, use \tilde{} which gives ${\displaystyle \stackrel{}{~}}$, placing a ~ over an empty box. Alternatively \sim produces ${\displaystyle \sim }$, a large centred ~ which may be more appropriate in some situations.

The command \hat produces a hat over the next character, for example \hat{o} produces ${\displaystyle \hat{o}}$. For a stretchable version use \widehat{abc} giving ${\displaystyle \widehat{abc}}$. The wedge \wedge is normally used as a mathematical operator ${\displaystyle \wedge }$ the sequence ^\wedge produces ${\wedge }^{}$ the best equivalent to the ASCII caret ^ character.

"Whitespace" characters, such as blank or tab, are treated uniformly as "space" by LaTeX. Several consecutive whitespace characters are treated as one "space". See below for commands that produces spaces of different size.

Environments in LaTeX have a role that is quite similar to commands, but they usually have effect on a wider part of formula. Their syntax is:

 \begin{environmentname}
   text to be influenced
 \end{environmentname}

Environments supported by Wikipedia include matrix, align, etc. See below.

The colors, as well as font sizes and types, are independent of browser settings or CSS. Font sizes and types will often deviate from what HTML renders. Vertical alignment with the surrounding text can also be a problem; a work-around is described in the "Alignment with normal text flow" section below. The css selector of the images is img.tex.

The alt text of the PNG images, which is displayed to visually impaired and other readers who cannot see the images, and is also used when the text is selected and copied, defaults to the wikitext that produced the image, excluding the <math> and </math>. You can override this by explicitly specifying an alt attribute for the math element. For example, <math alt="Square root of pi">\sqrt{\pi}</math> generates an image ${\displaystyle \sqrt{\pi }}$ whose alt text is "Square root of pi". This should not be confused with the title attribute that produces popup text when the hovering over the PNG image, for example <math title="pi">\pi</math> generates an image ${\displaystyle \pi }$ whose popup text is "pi".

Apart from function and operator names, as is customary in mathematics, variables and letters are in italics; digits are not. For other text, (like variable labels) to avoid being rendered in italics like variables, use \text or \mathrm. You can also define new function names using \operatorname{...}. For example, \text{abc} gives ${\displaystyle \text{abc}}$. \operatorname{...} provides spacing before and after the operator name when appropriate, as when a\operatorname{sn}b is rendered as ${\displaystyle a\mathrm{sn}b}$ (with space to the left and right of "sn") and a\operatorname{sn}(b+c) as ${\displaystyle a\mathrm{sn}(b+c)}$ (with space to the left and not to the right). LaTeX's starred version, \operatorname* is not supported, but a workaround is to add \limits instead. For example, \operatorname{sn}_{b>c}(b+c) \qquad \operatorname{sn}\limits_{b>c}(b+c) renders as

${\displaystyle {\mathrm{sn}}_{b>c}(b+c)\underset{b>c}{\mathrm{sn}}(b+c)}$.

Latex does not have full support for Unicode characters, and not all characters render. Most Latin characters with accents render correctly. However some do not, in particular those that include multiple diacritics (e.g. with Latin letters used in Vietnamese) or that cannot be precomposed into a single character (such as the uppercase Latin letter W with ring), or that use other diacritics (like the ogonek or the double grave accent, used in Central European languages like Polish, or the horn attached above some vowels in Vietnamese), or other modified letter forms (used in IPA notations, or African languages, or in medieval texts), some digram ligatures (like IJ in Dutch), or Latin letters borrowed from Greek, or small capitals, as well as superscripts and subscript letters. For example, \text{ð} and \text{þ} (used in Icelandic) will give errors.

The normal way of entering quotation marks in text mode (two back ticks for the left and two apostrophes for the right), such as \text{a ``quoted'' word} will not work correctly. As a workaround, you can use the Unicode left and right quotation mark characters, which are available from the "Symbols" dropdown panel beneath the editor: \text{a “quoted” word}.

MediaWiki stores rendered formulas in a cache so that the images of those formulas do not need to be created each time the page is opened by a user. To force the rerendering of all formulas of a page, you must open it with the getter variables action=purge&mathpurge=true. Imagine for example there is a wrong rendered formula in the article Integral. To force the re-rendering of this formula you need to open the URL https://en.wikipedia.org/w/index.php?title=Integral&action=purge&mathpurge=true . Afterwards you need to bypass your browser cache so that the new created images of the formulas are actually downloaded. See also mw:Extension:Math#Purging pages that contain equations for more details.

සැකිල්ල:See also TeX markup is not the only way to produce special characters. As this comparison table shows, sometimes similar results can be achieved in HTML using Template:Math. See also Help:Special characters.

The codes on the left produce the symbols on the right, but the latter can also be put directly in the wikitext, except for ‘=’.

α β γ δ ε ζ
η θ ι κ λ μ ν
ξ ο π ρ σ ς
τ υ φ χ ψ ω

Γ Δ Θ Λ Ξ Π
Σ Φ Ψ Ω

∫ ∑ ∏ √ − ± ∞
≈ ∝ = ≡ ≠ ≤ ≥
× · ⋅ ÷ ∂ ′ ″
∇ ‰ ° ∴ ∅

∈ ∉ ∩ ∪ ⊂ ⊃ ⊆ ⊇
¬ ∧ ∨ ∃ ∀
⇒ ⇔ → ↔ ↑ ↓
ℵ - – —

The project has not reached a consensus on HTML and TeX because each has advantages in some situations.

The default MathML/SVG renderer option, selectable through My Preferences - Appearance - Math, generates hidden MathML code. This code can be used by screen readers and other assistive technology. To actually display the MathML in Firefox you can install the Native MathML extension, or simply copy its CSS rules to your Wikipedia user stylesheet. In either case, you must have fonts that support MathML installed on your system. For copy-paste support also install MathML Copy. Details on using MathML in other systems can be found at mw:Extension:Math.

For a little more semantics on these symbols, see the brief TeX Cookbook.

The සැකිල්ල:Tag tag can take a display attribute with possible values of inline and block.

If the value of the display attribute is inline, the contents will be rendered in inline mode; i.e., there will be no new paragraph for the equation and the operators will be rendered to consume only a small amount of vertical space.

The sum ${\sum }_{i=0}^{\mathrm{\infty }}{2}^{-i}$ converges to 2.

The next line-width is not disturbed by large operators.

The code for the math example reads:

<math display="inline">\sum_{i=0}^\infty 2^{-i}</math>

Technically the command \textstyle will be added to the user input before the tex command is passed to the renderer. The result will be displayed without further formatting by outputting the image or MathMLelement to the page.

In block-style the equation is rendered in its own paragraph and the operators are rendered consuming less horizontal space.

The equation $${\displaystyle \text{geometric series:}\begin{array}{c}{\displaystyle \sum _{i=0}^{\mathrm{\infty }}}{2}^{-i}=2\end{array}}$$

It was entered as

<math display="block">\text{geometric series:}\quad \sum_{i=0}^\infty 2^{-i}=2 </math>

Technically it will add the command \displaystyle will be added to the user input, if the user input does not contain the string \displaystyle or \align before the tex command is passed to the renderer. The result will be displayed in a new paragraph. Therefore, the style of the MathImage is altered i.e. the style attribute "display:block;margin:auto" is added. For MathML it is ensured that display=inline is replaced by display block which produces a new paragraph

If nothing is specified the current behavior is preserved. That means all equations are rendered in display style but not using a new paragraph.

The sum ${\displaystyle {\displaystyle \sum _{i=0}^{\mathrm{\infty }}}{2}^{-i}}$ converges to 2.

The next line-width is disturbed by large operators.

The code for the math example reads:

<math>\sum_{i=0}^\infty 2^{-i}</math>

The equation

${\displaystyle \text{geometric series:}{\displaystyle \sum _{i=0}^{\mathrm{\infty }}}{2}^{-i}=2}$

It was entered as

<math>\text{geometric series:}\quad \sum_{i=0}^\infty 2^{-i}=2 </math>

\begin{matrix}
x & y \\
z & v
\end{matrix}

\begin{vmatrix}
x & y \\
z & v
\end{vmatrix}

\begin{Vmatrix}
x & y \\
z & v
\end{Vmatrix}

\begin{bmatrix}
0 & \cdots & 0 \\
\vdots & \ddots & \vdots \\
0 & \cdots & 0
\end{bmatrix}

\begin{Bmatrix}
x & y \\
z & v
\end{Bmatrix}

\begin{pmatrix}
x & y \\
z & v
\end{pmatrix}

\bigl( \begin{smallmatrix}
a&b\\ c&d
\end{smallmatrix} \bigr)

f(n) =
\begin{cases}
n/2, & \text{if }n\text{ is even} \\
3n+1, & \text{if }n\text{ is odd}
\end{cases}

\begin{align}
f(x) & = (a+b)^2 \\
& = a^2+2ab+b^2 \\
\end{align}

\begin{alignat}{2}
f(x) & = (a-b)^2 \\
& = a^2-2ab+b^2 \\
\end{alignat}

\begin{array}{lcl}
z & = & a \\
f(x,y,z) & = & x + y + z
\end{array}

\begin{array}{lcr}
z & = & a \\
f(x,y,z) & = & x + y + z
\end{array}

f(x) =
\sum_{n=0}^\infty a_n x^n =
a_0+a_1x+a_2x^2+\cdots

\begin{cases}
3x + 5y + z \\
7x - 2y + 4z \\
-6x + 3y + 2z
\end{cases}

\begin{array}{|c|c|c|} a & b & S \\
\hline
0&0&1\\
0&1&1\\
1&0&1\\
1&1&0\\
\end{array}

You can use various delimiters with \left and \right:

The templates සැකිල්ල:Tl and සැකිල්ල:Tl can be used to number equations. The template සැකිල්ල:Tl can be used to refer to a numbered equation from surrounding text. For example, the following syntax:

{{NumBlk|:|<math>x^2 + y^2 + z^2 = 1</math>|{{EquationRef|1}}}}

produces the following result (note the equation number in the right margin):

සැකිල්ල:NumBlk

Later on, the text can refer to this equation by its number using syntax like this:

As seen in equation ({{EquationNote|1}}), blah blah blah...

The result looks like this:

As seen in equation (සැකිල්ල:EquationNote), blah blah blah...

The equation number produced by සැකිල්ල:Tl is a link that the user can click to go immediately to the cited equation.

සැකිල්ල:See also Texvc cannot render arbitrary Unicode characters. Those it can handle can be entered by the expressions below. For others, such as Cyrillic, they can be entered as Unicode or HTML entities in running text, but cannot be used in displayed formulas.

Equations can use color with the \color command. For example,

• {\color{Blue}x^2}+{\color{Orange}2x}-{\color{LimeGreen}1}

  ${\displaystyle x^2+2x-1}$

• x_{1,2}=\frac{{\color{Blue}-b}\pm\sqrt{\color{Red}b^2-4ac}}{\color{Green}2a }

  ${\displaystyle x_{1,2}=\frac{-b\pm \sqrt{b^2-4ac}}{2a}}$

There are several alternate notations styles

• {\color{Blue}x^2}+{\color{Orange}2x}-{\color{LimeGreen}1} works with both texvc and MathJax

  ${\displaystyle x^2+2x-1}$

• \color{Blue}x^2\color{Black}+\color{Orange}2x\color{Black}-\color{LimeGreen}1 works with both texvc and MathJax

  ${\displaystyle x^2+2x-1}$

• \color{Blue}{x^2}+\color{Orange}{2x}-\color{LimeGreen}{1} only works with MathJax

  ${\displaystyle x^2+2x-1}$

Some color names are predeclared according to the following table, you can use them directly for the rendering of formulas (or for declaring the intended color of the page background).

Color should not be used as the only way to identify something, because it will become meaningless on black-and-white media or for color-blind people. See WP:Manual of Style (accessibility)#Color.

Latex does not have a command for setting the background color. The most effective of setting a background color is by setting a CSS styling rules for a table cell

{| class="wikitable" align="center"
| style="background: gray;"      | <math>x^2</math>
| style="background: Goldenrod;" | <math>y^3</math>
|}

Rendered as

Custom colours can be defined using

\definecolor{myorange}{rgb}{1,0.65,0.4}\color{myorange}e^{i \pi}\color{Black} + 1 = 0

${\displaystyle e^{i\pi }+1=0}$

TeX handles most spacing automatically, but you may sometimes want manual control.

Automatic spacing may be broken in very long expressions (because they produce an overfull hbox in TeX):

0+1+2+3+4+5+6+7+8+9+10+11+12+13+14+15+16+17+18+19+20+\cdots

${\displaystyle 0+1+2+3+4+5+6+7+8+9+10+11+12+13+14+15+16+17+18+19+20+\cdots }$

This can be remedied by putting a pair of braces { } around the whole expression:

{0+1+2+3+4+5+6+7+8+9+10+11+12+13+14+15+16+17+18+19+20+\cdots}

${\displaystyle 0+1+2+3+4+5+6+7+8+9+10+11+12+13+14+15+16+17+18+19+20+\cdots }$

Because of the default CSS

img.tex { vertical-align: middle; }

an inline expression like ${\displaystyle {\displaystyle \underset{-N}{\overset{N}{\int }}}{e}^{x}dx}$ should look good.

If you need to align it otherwise, use <math style="vertical-align:-100%;">...</math> and play with the vertical-align argument until you get it right; however, how it looks may depend on the browser and the browser settings.

If you rely on this workaround, if and when the rendering on the server gets fixed in a future release, this extra manual offset will suddenly make every affected formula align incorrectly. So use it sparingly, if at all.

Elements which are not yet implemented are \oiint, namely a two-fold integral \iint සැකිල්ල:Nowrap with a circular curve through the centre of the two integrals, and similarly \oiiint, a circular curve through three integrals. In contrast, \oint සැකිල්ල:Nowrap exists for the single dimension (integration over a curved line within a plane or any space with higher dimension).

These elements appear in many contexts: \oiint denotes a surface integral over the closed 2d boundary of a 3d region (which occurs in much of 3d vector calculus and physical applications – like Maxwell's equations), likewise \oiiint denotes integration over the closed 3d boundary (surface volume) of a 4d region, and they would be strong candidates for the next TeX version. As such there are a lot of workarounds in the present version.

\oiint and \oiiint using currently implemented symbols

\oiint looks like: ${\displaystyle \underset{S}{\iint }\subset \supset 𝐃\cdot \mathrm{d}𝐀}$, which uses \iint along with \subset and \supset (overdrawn after backspacing): \iint\limits_{S}\!\!\!\!\!\!\!\!\!\!\!\subset\!\supset \mathbf D \cdot \mathrm{d}\mathbf A ${\displaystyle \int \underset{\partial V}{\int }◯𝐃\cdot \mathrm{d}𝐀}$, which uses \int twice (with some backward kerning) along with \bigcirc (also overdrawn after backpacing) to produce a more consistent circle: \int\!\!\!\!\int_{\partial V}\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\;\;\;\bigcirc\,\,\mathbf D\cdot\mathrm{d}\mathbf A \oiiint (should also be preferably more tightly kerned) looks more or less like: ${\displaystyle \int \int \underset{\partial V}{\int }\subset \supset 𝐃\cdot \mathrm{d}𝐀}$ which uses three \int symbols (with more backward kerning) with \subset and \supset (overdrawn after backspacing): \int\!\!\!\!\!\int\!\!\!\!\!\int_{\partial V}\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\;\;\;\subset\!\supset \mathbf D\;\cdot\mathrm{d}\mathbf A ${\displaystyle \int \int \underset{\partial V}{\int }◯𝐃\cdot \mathrm{d}𝐀}$, which uses three \int symbols (with more backward kerning) along with \bigcirc (also overdrawn after backspacing): \int\!\!\!\!\!\int\!\!\!\!\!\int_{\partial V}\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\;\;\;\bigcirc\,\,\mathbf D\;\cdot\mathrm{d}\mathbf A

However, since no standardisation exists as yet, any workaround like this (which uses many \! symbols for backspacing) should be avoided, if possible. See below for a possibility using PNG image enforcement.

Note that \iint (the double integral) and \iiint (the triple integral) are still not kerned as they should preferably be, and are currently rendered as if they were successive \int symbols; this is not a major problem for reading the formulas, even if the integral symbols before the last one do not have bounds, so it's best to avoid backspacing "hacks" as they may be inconsistent with a possible future better implementation of integrals symbols (with more precisely computed kerning positions).

These symbols are available as PNG images which are also integrated into two templates, සැකිල්ල:Tl and සැකිල්ල:Tl, which take care of the formatting around the symbols.

The templates have three parameters:

preintegral

the text or formula immediately before the integral

intsubscpt

the subscript below the integral

integrand

the text or formula immediately after the integral

• Stokes' theorem: <math>\oiint_{\scriptstyle S}( \nabla \times \mathbf{F} ) \cdot {\rm d}\mathbf{S} = \oint_{\partial S} \mathbf{F} \cdot {\rm d}\boldsymbol{\ell} </math>

${\displaystyle {\text{∯}}_S(\mathrm{\nabla }\times 𝐅)\cdot \mathrm{d}𝐒={{\displaystyle \oint }}_{\partial S}𝐅\cdot \mathrm{d}\mathit{\ell }}$

• Ampère's law + correction: {{oiint | preintegral=<math>\oint_C \mathbf{B} \cdot {\rm d} \boldsymbol{\ell} = \mu_0 </math> | intsubscpt = <math>{\scriptstyle S}</math> | integrand = <math>\left ( \mathbf{J} + \epsilon_0\frac{\partial \mathbf{E}}{\partial t} \right ) \cdot {\rm d}\mathbf{S}</math> }}

සැකිල්ල:Oiint

• Continuity of 4-momentum flux (in general relativity):^[3]<math display=block> \mathbf{P} = \oiiint_{\scriptstyle \partial \Omega} \mathbf{T} \cdot {\rm d}^3\boldsymbol{\Sigma} = 0 </math>

$${\displaystyle 𝐏={\text{∰}}_{\partial \mathrm{\Omega }}𝐓\cdot {\mathrm{d}}^3\mathrm{\Sigma }=0}$$

Some variants of \oiint and \oiiint have arrows on them to indicate the sense of integration, such as a line integral around a closed curve in the clockwise sense, and higher dimensional analogues. These are not implemented in TeX on Wikipedia either, although the template සැකිල්ල:Tl is available - see link for details.

\overarc is not yet implemented to display the arc notation. However, there exists a workaround: use \overset{\frown}{AB}, which gives ${\displaystyle \stackrel{⌢}{AB}}$

\dddot is not implemented. For a workaround use \overset{...}{x}, which gives ${\displaystyle \stackrel{...}{x}}$.

The starred version of \operatorname is not currently supported. A workaround for

\operatorname*{median}_{j\,\ne\,i} X_{i,j}

is

\operatorname{\underset{\mathit{j\,\ne\,i}}{median}} X_{i,j}

The texvc processor accepts some non-standard syntax. These should be avoided as the MathJax based renderers do not support these syntax.

Texvc accepts % for representing percentages. This causes an error with MathJax and should be replaced with \% in all renderers.

In texvc spaces need to be represented inside the \textrm environment using \, \ and normal spaces are ignored i.e. \textrm{A\,B C} would render as සැකිල්ල:Math. In mathjax \textrm is an alias for \text which is renders its argument as normal text, hence \textrm{A\,B C} renders as සැකිල්ල:Math. To ensure compatibility between versions alway use the \text environment: \text{A B C}.

Non-ASCII Unicode characters like සැකිල්ල:Pi work in MathML, and MathJax but not in texvc so should be avoided.

සැකිල්ල:Shortcut There are three ways to render chemical sum formulae as used in chemical equations:

• සැකිල්ල:Xtag (more recommended for chemical equation than the alias සැකිල්ල:Xtag)
• සැකිල්ල:Xtag
• සැකිල්ල:Tlx and සැකිල්ල:Tlx

සැකිල්ල:Xtag is short for <math chem>\ce{X}</math> (where X is a chemical sum formula)

Technically, සැකිල්ල:Xtag is a math tag with the extension mhchem enabled, according to the MathJax documentation.

Note, that the commands \cee and \cf are disabled, because they are marked as deprecated in the mhchem LaTeX package documentation.

Please note that there are still major issues with mhchem support in MediaWiki. Some issue can be solved by enabling the extension using සැකිල්ල:Xtag and formatting individual items with \ce. For example, සැකිල්ල:Markup2

States Subscripting is not IUPAC recommendation.

සැකිල්ල:Markup

සැකිල්ල:Markup

<math chem>\begin{align}
\overbrace{\ce{2Fe3O4}}^{\text{magnetite}} + \ce{1/2 O2 ->}\ &{\color{Brown}\overbrace{\ce{3(\lambda{-}Fe2O3)}}^{\text{maghemite}}}\\
\underbrace{\ce{2Fe3O4}}_{\text{magnetite}} + \ce{1/2 O2 ->}\ &{\color{Red}\underbrace{\ce{3(\alpha{-}Fe2O3)}}_{\text{hematite}}}
\end{align}</math>

${\displaystyle \begin{array}{cc}\stackrel{\text{magnetite}}{\overbrace{2\mathrm{F}\mathrm{e}{\phantom{A}}_3\mathrm{O}{\phantom{A}}_4}}+\frac{1}{2}\mathrm{O}{\phantom{A}}_2⟶& \stackrel{\text{maghemite}}{\overbrace{3(\mathrm{\lambda }\text{-}\mathrm{F}\mathrm{e}{\phantom{A}}_2\mathrm{O}{\phantom{A}}_3)}}\\ \underset{\text{magnetite}}{\underbrace{2\mathrm{F}\mathrm{e}{\phantom{A}}_3\mathrm{O}{\phantom{A}}_4}}+\frac{1}{2}\mathrm{O}{\phantom{A}}_2⟶& \underset{\text{hematite}}{\underbrace{3(\mathrm{\alpha }\text{-}\mathrm{F}\mathrm{e}{\phantom{A}}_2\mathrm{O}{\phantom{A}}_3)}}\end{array}}$

To align the equations or color them, use සැකිල්ල:Xtag and සැකිල්ල:Code. සැකිල්ල:-

To make a commutative diagram, there are three steps:

1. write the diagram in TeX
2. convert to SVG
3. upload the file to Wikimedia Commons

Xy-pic (online manual) is the most powerful and general-purpose diagram package in TeX. Diagrams created using it can be found at Commons: Category:Xy-pic diagrams.

Simpler packages include:

• AMS's amscd
• Paul Taylor's diagrams
• François Borceux Diagrams

The following is a template for Xy-pic, together with a hack to increase the margins in dvips, so that the diagram is not truncated by over-eager cropping (suggested in TUGboat: TUGboat, Volume 17 1996, No. 3):

\documentclass{amsart}
\usepackage[all, ps, dvips]{xy}  % Loading the XY-Pic package
                                 % Using postscript driver for smoother curves
\usepackage{color}  % For invisible frame
\begin{document}
\thispagestyle{empty}  % No page numbers
\SelectTips{eu}{}  % Euler arrowheads (tips)
\setlength{\fboxsep}{0pt}  % Frame box margin
{\color{white}\framebox{{\color{black}$$  % Frame for margin

\xymatrix{
%%% Diagram goes here %%%
}

$$}}} % end math, end frame
\end{document}

Once you have produced your diagram in LaTeX (or TeX), you can convert it to an SVG file using the following sequence of commands:

pdflatex file.tex
pdfcrop --clip file.pdf tmp.pdf
pdf2svg tmp.pdf file.svg
rm tmp.pdf

The pdfcrop and pdf2svg utilities are needed for this procedure. You can alternatively use pdf2svg from PDFTron for the last step.

If you do not have pdfTeX (which is unlikely) you can use the following commands to replace the first step (TeX → PDF):

latex file.tex
dvipdfm file.dvi

In general, you will not be able to get anywhere with diagrams without TeX and Ghostscript, and the inkscape program is a useful tool for creating or modifying your diagrams by hand. There is also a utility pstoedit which supports direct conversion from Postscript files to many vector graphics formats, but it requires a non-free plugin to convert to SVG, and regardless of the format, this editor has not been successful in using it to convert diagrams with diagonal arrows from TeX-created files.

These programs are:

• a working TeX distribution, such as TeX Live
• Ghostscript
• pstoedit
• Inkscape

සැකිල්ල:See also සැකිල්ල:See also

As the diagram is your own work, upload it to Wikimedia Commons, so that all projects (notably, all languages) can use it without having to copy it to their language's Wiki. (If you've previously uploaded a file to somewhere other than Commons, to Commons.)

Check size

Before uploading, check that the default size of the image is neither too large nor too small by opening in an SVG application and viewing at default size (100% scaling), otherwise adjust the -y option to dvips.

Name

Make sure the file has a meaningful name.

Upload

Login to Wikimedia Commons, then upload the file; for the Summary, give a brief description.