Help:Displaying a formula

MediaWiki renders mathematical equations using a combination of html markup and a variant of LaTeX via the .

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.^[a]

By default SVG images with non-visible MathML are generated. The older PNG images can be set via user preferences.^[b] On some browsers like Firefox 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.

See mw:Extension:Math for details on setting up math rendering on MediaWiki installations.

Basics[edit]

Math markup goes inside <math>...</math>. Chemistry markup goes inside <math chem>...</math chem> or <ce>...</ce>. 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 m:Template:Demo of attempt to use parameters within TeX (backlinks edit) for more information.

LaTeX commands[edit]

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}...

Special characters[edit]

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

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

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 ${\displaystyle \backslash }$.

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 tilda character ~, use \tilde{} which gives ${\displaystyle {\tilde {}}}$, 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 ${\displaystyle ^{\wedge }}$ the best equivalent to the ascii caret ^ character.

Spaces[edit]

"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.

LaTeX environments[edit]

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.

Rendering[edit]

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

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

${\displaystyle \definecolor {olive}{rgb}{0.5019607843137255,0.5019607843137255,0}\pagecolor {olive}e^{i\pi }+1=0\,\!}$

By default, the PNG images are rendered black on white, with a transparent background. On darker backgrounds, the characters may show white edges. To remove these, match the PNG background color with the background color of the page using \pagecolor. However, black text on a dark background is hard to read and should be avoided altogether where possible.

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, \mbox, 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 ${\displaystyle a\operatorname {sn} b}$ (with space to the left and right of "sn") and a\operatorname{\sn}(b+c) as ${\displaystyle a\operatorname {sn} (b+c)}$ (with space to the left and not to the right).

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} or \mbox{ð}, and \text{þ} or \mbox{þ} (used in Icelandic) will give errors.

Force-rerendering of formulas[edit]

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 rerendering 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.

TeX vs HTML[edit]

Before using TeX markup for producing special characters, it should be noted that, as this comparison table shows, sometimes similar results can be achieved in HTML using Template:Math. See also Help:Special characters.

TeX syntax	TeX rendering	HTML syntax	HTML rendering
\alpha	${\displaystyle \alpha }$	{{math|''α''}}	α
f(x) = x^2	${\displaystyle f(x)=x^{2}}$	{{math|''f''(''x'') {{=}} ''x''<sup>2</sup>}}	f(x) = x2
\sqrt{2}	${\displaystyle {\sqrt {2}}}$	{{math|{{radical|2}}}}	√2
\sqrt{1-e^2}	${\displaystyle {\sqrt {1-e^{2}}}\!}$	{{math|{{radical|1 &minus; ''e''<sup>2</sup>}}}}	√1 − e2

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 settled on using both HTML and TeX because each has advantages in some situations.

Pros of HTML[edit]

1. Formulas in HTML behave more like regular text. In-line HTML formulae always align properly with the rest of the HTML text and, to some degree, can be copied-and-pasted (this is not a problem if TeX is rendered using MathJax, and the alignment should not be a problem for PNG rendering once bug 32694 is fixed).
2. The formula’s background and font size match the rest of HTML contents (this can be fixed on TeX formulas by using the commands \pagecolor and \definecolor) and the appearance respects CSS and browser settings while the typeface is conveniently altered to help you identify formulae.
3. Pages using HTML code for formulae will load faster and they will create less clutter on your hard disk.
4. Formulae typeset with HTML code will be accessible to client-side script links (a.k.a. scriptlets).
5. The display of a formula entered using mathematical templates can be conveniently altered by modifying the templates involved; this modification will affect all relevant formulae without any manual intervention.
6. The HTML code, if entered diligently, will contain all semantic information to transform the equation back to TeX or any other code as needed. It can even contain differences TeX does not normally catch, e.g. {{math|''i''}} for the imaginary unit and {{math|<var>i</var>}} for an arbitrary index variable.
7. Unlike generated bitmaps, HTML is not sensitive to dots per inch variances between viewing platforms.

Pros of TeX[edit]

1. TeX is semantically more precise than HTML.
   1. In TeX, "x" means "mathematical variable "${\displaystyle x}$", whereas in HTML "x" is generic and somewhat ambiguous.
   2. On the other hand, if you encode the same formula as "{{math|<var>x</var>}}", you get the same visual result x and no information is lost. This requires diligence and more typing that could make the formula harder to understand as you type it. However, since there are far more readers than editors, this effort is worth considering if no other rendering options are available (such as MathJax, which is available to logged-in users as a preferences opt-in).
2. One consequence of point 1 is that TeX code can be transformed into HTML, but not vice versa.^[1] This means that on the server side we can always transform a formula, based on its complexity and location within the text, user preferences, type of browser, etc. Therefore, where possible, all the benefits of HTML can be retained, together with the benefits of TeX. It is true that the current situation is not ideal, but that is not a good reason to drop information or contents. It is more a reason to help improve the situation.
3. Another consequence of point 1 is that TeX can be converted to MathML (e.g. by MathJax) for browsers which support it, thus keeping its semantics and allowing the rendering to be better suited for the reader’s graphic device.
4. TeX is the preferred text formatting language of most professional mathematicians, scientists, and engineers. It is easier to persuade them to contribute if they can write in TeX.
5. TeX has been specifically designed for typesetting formulae, so input is easier and more natural if you are accustomed to it, and output is more aesthetically pleasing if you focus on a single formula rather than on the whole containing page.
6. Once a formula is done correctly in TeX, it will render reliably, whereas the success of HTML formulae is somewhat dependent on browsers or versions of browsers. Another aspect of this dependency is fonts: the serif font used for rendering formulae is browser-dependent and it may be missing some important glyphs. While the browser is generally capable to substitute a matching glyph from a different font family, it need not be the case for combined glyphs (compare "a̅" and " a̅").
7. When writing in TeX, editors need not worry about whether this or that version of this or that browser supports this or that HTML entity. The burden of these decisions is put on the software. This does not hold for HTML formulae, which can easily end up being rendered wrongly or differently from the editor’s intentions on a different browser.^[2]
8. TeX formulae, by default, render larger and are usually more readable than HTML formulae and are not dependent on client-side browser resources, such as fonts, and so the results are more reliably WYSIWYG.
9. While TeX does not assist you in finding HTML codes or Unicode values (which you can obtain by viewing the HTML source in your browser), copying and pasting from a TeX PNG image in Wikipedia into simple text will return the LaTeX source.

^ Unless your wikitext follows the style of point 1.2

^ The entity support problem is not limited to mathematical formulae though; it can be easily solved by using the corresponding characters instead of entities, as the character repertoire links do, except for cases where the corresponding glyphs are visually indiscernible (e.g. – for ‘–’ and − for ‘−’).

In some cases it may be the best choice to use neither TeX nor the HTML substitutes, but instead the simple ASCII symbols of a standard keyboard (see hereafter, for an example).

Using MathML[edit]

The default MathML/SVG renderer option, selectable through My Preferences - Appearance - Math generate hidden MathML code. This code can be used by screen readers and other assistive technology. To actually display the MathML in Firefox the Native MathML extension and the MathML fonts must be installed. Details on using MathML in other systems can be found at mw:Extension:Math.

Formatting using TeX[edit]

Functions, symbols, special characters[edit]

Accents/diacritics[edit]
\dot{a}, \ddot{a}, \acute{a}, \grave{a}	${\displaystyle {\dot {a}},{\ddot {a}},{\acute {a}},{\grave {a}}\!}$
\check{a}, \breve{a}, \tilde{a}, \bar{a}	${\displaystyle {\check {a}},{\breve {a}},{\tilde {a}},{\bar {a}}\!}$
\hat{a}, \widehat{a}, \vec{a}	${\displaystyle {\hat {a}},{\widehat {a}},{\vec {a}}\!}$
Standard numerical functions[edit]
\exp_a b = a^b, \exp b = e^b, 10^m	${\displaystyle \exp _{a}b=a^{b},\exp b=e^{b},10^{m}\!}$
\ln c, \lg d = \log e, \log_{10} f	${\displaystyle \ln c,\lg d=\log e,\log _{10}f\!}$
\sin a, \cos b, \tan c, \cot d, \sec e, \csc f	${\displaystyle \sin a,\cos b,\tan c,\cot d,\sec e,\csc f\!}$
\arcsin h, \arccos i, \arctan j	${\displaystyle \arcsin h,\arccos i,\arctan j\!}$
\sinh k, \cosh l, \tanh m, \coth n	${\displaystyle \sinh k,\cosh l,\tanh m,\coth n\!}$
\operatorname{sh}\,k, \operatorname{ch}\,l, \operatorname{th}\,m, \operatorname{coth}\,n	${\displaystyle \operatorname {sh} \,k,\operatorname {ch} \,l,\operatorname {th} \,m,\operatorname {coth} \,n\!}$
\operatorname{argsh}\,o, \operatorname{argch}\,p, \operatorname{argth}\,q	${\displaystyle \operatorname {argsh} \,o,\operatorname {argch} \,p,\operatorname {argth} \,q\!}$
\sgn r, \left\vert s \right\vert	${\displaystyle \operatorname {sgn} r,\left\vert s\right\vert \!}$
\min(x,y), \max(x,y)	${\displaystyle \min(x,y),\max(x,y)\!}$
Bounds[edit]
\min x, \max y, \inf s, \sup t	${\displaystyle \min x,\max y,\inf s,\sup t\!}$
\lim u, \liminf v, \limsup w	${\displaystyle \lim u,\liminf v,\limsup w\!}$
\dim p, \deg q, \det m, \ker\phi	${\displaystyle \dim p,\deg q,\det m,\ker \phi \!}$
Projections[edit]
\Pr j, \hom l, \lVert z \rVert, \arg z	${\displaystyle \Pr j,\hom l,\lVert z\rVert ,\arg z\!}$
Differentials and derivatives[edit]
dt, \operatorname{d}\!t, \partial t, \nabla\psi	${\displaystyle dt,\operatorname {d} \!t,\partial t,\nabla \psi \!}$
dy/dx, \operatorname{d}\!y/\operatorname{d}\!x, {dy \over dx}, {\operatorname{d}\!y\over\operatorname{d}\!x}, {\partial^2\over\partial x_1\partial x_2}y	${\displaystyle dy/dx,\operatorname {d} \!y/\operatorname {d} \!x,{dy \over dx},{\operatorname {d} \!y \over \operatorname {d} \!x},{\partial ^{2} \over \partial x_{1}\partial x_{2}}y\!}$
\prime, \backprime, f^\prime, f', f'', f^{(3)}, \dot y, \ddot y	${\displaystyle \prime ,\backprime ,f^{\prime },f',f'',f^{(3)}\!,{\dot {y}},{\ddot {y}}}$
Letter-like symbols or constants[edit]
\infty, \aleph, \complement, \backepsilon, \eth, \Finv, \hbar	${\displaystyle \infty ,\aleph ,\complement ,\backepsilon ,\eth ,\Finv ,\hbar \!}$
\Im, \imath, \jmath, \Bbbk, \ell, \mho, \wp, \Re, \circledS	${\displaystyle \Im ,\imath ,\jmath ,\Bbbk ,\ell ,\mho ,\wp ,\Re ,\circledS \!}$
Modular arithmetic[edit]
s_k \equiv 0 \pmod{m}	${\displaystyle s_{k}\equiv 0{\pmod {m}}\!}$
a\,\bmod\,b	${\displaystyle a\,{\bmod {\,}}b\!}$
\gcd(m, n), \operatorname{lcm}(m, n)	${\displaystyle \gcd(m,n),\operatorname {lcm} (m,n)}$
\mid, \nmid, \shortmid, \nshortmid	${\displaystyle \mid ,\nmid ,\shortmid ,\nshortmid \!}$
Radicals[edit]
\surd, \sqrt{2}, \sqrt[n]{}, \sqrt[3]{x^3+y^3 \over 2}	${\displaystyle \surd ,{\sqrt {2}},{\sqrt[{n}]{}},{\sqrt[{3}]{x^{3}+y^{3} \over 2}}\!}$
Operators[edit]
+, -, \pm, \mp, \dotplus	${\displaystyle +,-,\pm ,\mp ,\dotplus \!}$
\times, \div, \divideontimes, /, \backslash	${\displaystyle \times ,\div ,\divideontimes ,/,\backslash \!}$
\cdot, * \ast, \star, \circ, \bullet	${\displaystyle \cdot ,*\ast ,\star ,\circ ,\bullet \!}$
\boxplus, \boxminus, \boxtimes, \boxdot	${\displaystyle \boxplus ,\boxminus ,\boxtimes ,\boxdot \!}$
\oplus, \ominus, \otimes, \oslash, \odot	${\displaystyle \oplus ,\ominus ,\otimes ,\oslash ,\odot \!}$
\circleddash, \circledcirc, \circledast	${\displaystyle \circleddash ,\circledcirc ,\circledast \!}$
\bigoplus, \bigotimes, \bigodot	${\displaystyle \bigoplus ,\bigotimes ,\bigodot \!}$
Sets[edit]
\{ \}, \O \empty \emptyset, \varnothing	${\displaystyle \{\},\emptyset \emptyset \emptyset ,\varnothing \!}$
\in, \notin \not\in, \ni, \not\ni	${\displaystyle \in ,\notin \not \in ,\ni ,\not \ni \!}$
\cap, \Cap, \sqcap, \bigcap	${\displaystyle \cap ,\Cap ,\sqcap ,\bigcap \!}$
\cup, \Cup, \sqcup, \bigcup, \bigsqcup, \uplus, \biguplus	${\displaystyle \cup ,\Cup ,\sqcup ,\bigcup ,\bigsqcup ,\uplus ,\biguplus \!}$
\setminus, \smallsetminus, \times	${\displaystyle \setminus ,\smallsetminus ,\times \!}$
\subset, \Subset, \sqsubset	${\displaystyle \subset ,\Subset ,\sqsubset \!}$
\supset, \Supset, \sqsupset	${\displaystyle \supset ,\Supset ,\sqsupset \!}$
\subseteq, \nsubseteq, \subsetneq, \varsubsetneq, \sqsubseteq	${\displaystyle \subseteq ,\nsubseteq ,\subsetneq ,\varsubsetneq ,\sqsubseteq \!}$
\supseteq, \nsupseteq, \supsetneq, \varsupsetneq, \sqsupseteq	${\displaystyle \supseteq ,\nsupseteq ,\supsetneq ,\varsupsetneq ,\sqsupseteq \!}$
\subseteqq, \nsubseteqq, \subsetneqq, \varsubsetneqq	${\displaystyle \subseteqq ,\nsubseteqq ,\subsetneqq ,\varsubsetneqq \!}$
\supseteqq, \nsupseteqq, \supsetneqq, \varsupsetneqq	${\displaystyle \supseteqq ,\nsupseteqq ,\supsetneqq ,\varsupsetneqq \!}$
Relations[edit]
=, \ne, \neq, \equiv, \not\equiv	${\displaystyle =,\neq ,\neq ,\equiv ,\not \equiv \!}$
\doteq, \doteqdot, \overset{\underset{\mathrm{def}}{}}{=}, :=	${\displaystyle \doteq ,\doteqdot ,{\overset {\underset {\mathrm {def} }{}}{=}},:=\!}$
\sim, \nsim, \backsim, \thicksim, \simeq, \backsimeq, \eqsim, \cong, \ncong	${\displaystyle \sim ,\nsim ,\backsim ,\thicksim ,\simeq ,\backsimeq ,\eqsim ,\cong ,\ncong \!}$
\approx, \thickapprox, \approxeq, \asymp, \propto, \varpropto	${\displaystyle \approx ,\thickapprox ,\approxeq ,\asymp ,\propto ,\varpropto \!}$
<, \nless, \ll, \not\ll, \lll, \not\lll, \lessdot	${\displaystyle <,\nless ,\ll ,\not \ll ,\lll ,\not \lll ,\lessdot \!}$
>, \ngtr, \gg, \not\gg, \ggg, \not\ggg, \gtrdot	${\displaystyle >,\ngtr ,\gg ,\not \gg ,\ggg ,\not \ggg ,\gtrdot \!}$
\le, \leq, \lneq, \leqq, \nleq, \nleqq, \lneqq, \lvertneqq	${\displaystyle \leq ,\leq ,\lneq ,\leqq ,\nleq ,\nleqq ,\lneqq ,\lvertneqq \!}$
\ge, \geq, \gneq, \geqq, \ngeq, \ngeqq, \gneqq, \gvertneqq	${\displaystyle \geq ,\geq ,\gneq ,\geqq ,\ngeq ,\ngeqq ,\gneqq ,\gvertneqq \!}$
\lessgtr, \lesseqgtr, \lesseqqgtr, \gtrless, \gtreqless, \gtreqqless	${\displaystyle \lessgtr ,\lesseqgtr ,\lesseqqgtr ,\gtrless ,\gtreqless ,\gtreqqless \!}$
\leqslant, \nleqslant, \eqslantless	${\displaystyle \leqslant ,\nleqslant ,\eqslantless \!}$
\geqslant, \ngeqslant, \eqslantgtr	${\displaystyle \geqslant ,\ngeqslant ,\eqslantgtr \!}$
\lesssim, \lnsim, \lessapprox, \lnapprox	${\displaystyle \lesssim ,\lnsim ,\lessapprox ,\lnapprox \!}$
\gtrsim, \gnsim, \gtrapprox, \gnapprox	${\displaystyle \gtrsim ,\gnsim ,\gtrapprox ,\gnapprox \,}$
\prec, \nprec, \preceq, \npreceq, \precneqq	${\displaystyle \prec ,\nprec ,\preceq ,\npreceq ,\precneqq \!}$
\succ, \nsucc, \succeq, \nsucceq, \succneqq	${\displaystyle \succ ,\nsucc ,\succeq ,\nsucceq ,\succneqq \!}$
\preccurlyeq, \curlyeqprec	${\displaystyle \preccurlyeq ,\curlyeqprec \,}$
\succcurlyeq, \curlyeqsucc	${\displaystyle \succcurlyeq ,\curlyeqsucc \,}$
\precsim, \precnsim, \precapprox, \precnapprox	${\displaystyle \precsim ,\precnsim ,\precapprox ,\precnapprox \,}$
\succsim, \succnsim, \succapprox, \succnapprox	${\displaystyle \succsim ,\succnsim ,\succapprox ,\succnapprox \,}$
Geometric[edit]
\parallel, \nparallel, \shortparallel, \nshortparallel	${\displaystyle \parallel ,\nparallel ,\shortparallel ,\nshortparallel \!}$
\perp, \angle, \sphericalangle, \measuredangle, 45^\circ	${\displaystyle \perp ,\angle ,\sphericalangle ,\measuredangle ,45^{\circ }\!}$
\Box, \blacksquare, \diamond, \Diamond \lozenge, \blacklozenge, \bigstar	${\displaystyle \Box ,\blacksquare ,\diamond ,\Diamond \lozenge ,\blacklozenge ,\bigstar \!}$
\bigcirc, \triangle, \bigtriangleup, \bigtriangledown	${\displaystyle \bigcirc ,\triangle ,\bigtriangleup ,\bigtriangledown \!}$
\vartriangle, \triangledown	${\displaystyle \vartriangle ,\triangledown \!}$
\blacktriangle, \blacktriangledown, \blacktriangleleft, \blacktriangleright	${\displaystyle \blacktriangle ,\blacktriangledown ,\blacktriangleleft ,\blacktriangleright \!}$
Logic[edit]
\forall, \exists, \nexists	${\displaystyle \forall ,\exists ,\nexists \!}$
\therefore, \because, \And	${\displaystyle \therefore ,\because ,\And \!}$
\or \lor \vee, \curlyvee, \bigvee	${\displaystyle \lor \lor \vee ,\curlyvee ,\bigvee \!}$
\and \land \wedge, \curlywedge, \bigwedge	${\displaystyle \land \land \wedge ,\curlywedge ,\bigwedge \!}$
\bar{q}, \bar{abc}, \overline{q}, \overline{abc}, \lnot \neg, \not\operatorname{R}, \bot, \top	${\displaystyle {\bar {q}},{\bar {abc}},{\overline {q}},{\overline {abc}},\!}$ ${\displaystyle \lnot \neg ,\not \operatorname {R} ,\bot ,\top \!}$
\vdash \dashv, \vDash, \Vdash, \models	${\displaystyle \vdash \dashv ,\vDash ,\Vdash ,\models \!}$
\Vvdash \nvdash \nVdash \nvDash \nVDash	${\displaystyle \Vvdash \nvdash \nVdash \nvDash \nVDash \!}$
\ulcorner \urcorner \llcorner \lrcorner	${\displaystyle \ulcorner \urcorner \llcorner \lrcorner \,}$
Arrows[edit]
\Rrightarrow, \Lleftarrow	${\displaystyle \Rrightarrow ,\Lleftarrow \!}$
\Rightarrow, \nRightarrow, \Longrightarrow \implies	${\displaystyle \Rightarrow ,\nRightarrow ,\Longrightarrow \implies \!}$
\Leftarrow, \nLeftarrow, \Longleftarrow	${\displaystyle \Leftarrow ,\nLeftarrow ,\Longleftarrow \!}$
\Leftrightarrow, \nLeftrightarrow, \Longleftrightarrow \iff	${\displaystyle \Leftrightarrow ,\nLeftrightarrow ,\Longleftrightarrow \iff \!}$
\Uparrow, \Downarrow, \Updownarrow	${\displaystyle \Uparrow ,\Downarrow ,\Updownarrow \!}$
\rightarrow \to, \nrightarrow, \longrightarrow	${\displaystyle \rightarrow \to ,\nrightarrow ,\longrightarrow \!}$
\leftarrow \gets, \nleftarrow, \longleftarrow	${\displaystyle \leftarrow \gets ,\nleftarrow ,\longleftarrow \!}$
\leftrightarrow, \nleftrightarrow, \longleftrightarrow	${\displaystyle \leftrightarrow ,\nleftrightarrow ,\longleftrightarrow \!}$
\uparrow, \downarrow, \updownarrow	${\displaystyle \uparrow ,\downarrow ,\updownarrow \!}$
\nearrow, \swarrow, \nwarrow, \searrow	${\displaystyle \nearrow ,\swarrow ,\nwarrow ,\searrow \!}$
\mapsto, \longmapsto	${\displaystyle \mapsto ,\longmapsto \!}$
\rightharpoonup \rightharpoondown \leftharpoonup \leftharpoondown \upharpoonleft \upharpoonright \downharpoonleft \downharpoonright \rightleftharpoons \leftrightharpoons	${\displaystyle \rightharpoonup \rightharpoondown \leftharpoonup \leftharpoondown \upharpoonleft \upharpoonright \downharpoonleft \downharpoonright \rightleftharpoons \leftrightharpoons \,\!}$
\curvearrowleft \circlearrowleft \Lsh \upuparrows \rightrightarrows \rightleftarrows \rightarrowtail \looparrowright	${\displaystyle \curvearrowleft \circlearrowleft \Lsh \upuparrows \rightrightarrows \rightleftarrows \rightarrowtail \looparrowright \,\!}$
\curvearrowright \circlearrowright \Rsh \downdownarrows \leftleftarrows \leftrightarrows \leftarrowtail \looparrowleft	${\displaystyle \curvearrowright \circlearrowright \Rsh \downdownarrows \leftleftarrows \leftrightarrows \leftarrowtail \looparrowleft \,\!}$
\hookrightarrow \hookleftarrow \multimap \leftrightsquigarrow \rightsquigarrow \twoheadrightarrow \twoheadleftarrow	${\displaystyle \hookrightarrow \hookleftarrow \multimap \leftrightsquigarrow \rightsquigarrow \twoheadrightarrow \twoheadleftarrow \!}$
Special[edit]
\amalg \P \S \% \dagger \ddagger \ldots \cdots	${\displaystyle \amalg \P \S \%\dagger \ddagger \ldots \cdots \!}$
\smile \frown \wr \triangleleft \triangleright	${\displaystyle \smile \frown \wr \triangleleft \triangleright \!}$
\diamondsuit, \heartsuit, \clubsuit, \spadesuit, \Game, \flat, \natural, \sharp	${\displaystyle \diamondsuit ,\heartsuit ,\clubsuit ,\spadesuit ,\Game ,\flat ,\natural ,\sharp \!}$
Unsorted (new stuff)[edit]
\diagup \diagdown \centerdot \ltimes \rtimes \leftthreetimes \rightthreetimes	${\displaystyle \diagup \diagdown \centerdot \ltimes \rtimes \leftthreetimes \rightthreetimes \!}$
\eqcirc \circeq \triangleq \bumpeq \Bumpeq \doteqdot \risingdotseq \fallingdotseq	${\displaystyle \eqcirc \circeq \triangleq \bumpeq \Bumpeq \doteqdot \risingdotseq \fallingdotseq \!}$
\intercal \barwedge \veebar \doublebarwedge \between \pitchfork	${\displaystyle \intercal \barwedge \veebar \doublebarwedge \between \pitchfork \!}$
\vartriangleleft \ntriangleleft \vartriangleright \ntriangleright	${\displaystyle \vartriangleleft \ntriangleleft \vartriangleright \ntriangleright \!}$
\trianglelefteq \ntrianglelefteq \trianglerighteq \ntrianglerighteq	${\displaystyle \trianglelefteq \ntrianglelefteq \trianglerighteq \ntrianglerighteq \!}$

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

Larger expressions[edit]

Subscripts, superscripts, integrals[edit]

Feature	Syntax	How it looks rendered
Superscript	a^2	${\displaystyle a^{2}}$
Subscript	a_2	${\displaystyle a_{2}}$
Grouping	10^{30} a^{2+2}	${\displaystyle 10^{30}a^{2+2}}$
	a_{i,j} b_{f'}	${\displaystyle a_{i,j}b_{f'}}$
Combining sub & super without and with horizontal separation	x_2^3	${\displaystyle x_{2}^{3}}$
	{x_2}^3	${\displaystyle {x_{2}}^{3}\,\!}$
Super super	10^{10^{8}}	${\displaystyle 10^{10^{8}}}$
Preceding and/or additional sub & super	\sideset{_1^2}{_3^4}\prod_a^b	${\displaystyle \sideset {_{1}^{2}}{_{3}^{4}}\prod _{a}^{b}}$
	{}_1^2\!\Omega_3^4	${\displaystyle {}_{1}^{2}\!\Omega _{3}^{4}}$
Stacking	\overset{\alpha}{\omega}	${\displaystyle {\overset {\alpha }{\omega }}}$
	\underset{\alpha}{\omega}	${\displaystyle {\underset {\alpha }{\omega }}}$
	\overset{\alpha}{\underset{\gamma}{\omega}}	${\displaystyle {\overset {\alpha }{\underset {\gamma }{\omega }}}}$
	\stackrel{\alpha}{\omega}	${\displaystyle {\stackrel {\alpha }{\omega }}}$
Derivatives	x', y'', f', f''	${\displaystyle x',y'',f',f''}$
	x^\prime, y^{\prime\prime}	${\displaystyle x^{\prime },y^{\prime \prime }}$
Derivative dots	\dot{x}, \ddot{x}	${\displaystyle {\dot {x}},{\ddot {x}}}$
Underlines, overlines, vectors	\hat a \ \bar b \ \vec c	${\displaystyle {\hat {a}}\ {\bar {b}}\ {\vec {c}}}$
	\overrightarrow{a b} \ \overleftarrow{c d} \ \widehat{d e f}	${\displaystyle {\overrightarrow {ab}}\ {\overleftarrow {cd}}\ {\widehat {def}}}$
	\overline{g h i} \ \underline{j k l}	${\displaystyle {\overline {ghi}}\ {\underline {jkl}}}$
Arc (workaround)	\overset{\frown} {AB}	${\displaystyle {\overset {\frown }{AB}}}$
Arrows	A \xleftarrow{n+\mu-1} B \xrightarrow[T]{n\pm i-1} C	${\displaystyle A{\xleftarrow {n+\mu -1}}B{\xrightarrow[{T}]{n\pm i-1}}C}$
Overbraces	\overbrace{ 1+2+\cdots+100 }^{5050}	${\displaystyle \overbrace {1+2+\cdots +100} ^{5050}}$
Underbraces	\underbrace{ a+b+\cdots+z }_{26}	${\displaystyle \underbrace {a+b+\cdots +z} _{26}}$
Sum	\sum_{k=1}^N k^2	${\displaystyle \sum _{k=1}^{N}k^{2}}$
Sum (force \textstyle)	\textstyle \sum_{k=1}^N k^2	${\displaystyle \textstyle \sum _{k=1}^{N}k^{2}}$
Sum in a fraction (default \textstyle)	\frac{\sum_{k=1}^N k^2}{a}	${\displaystyle {\frac {\sum _{k=1}^{N}k^{2}}{a}}}$
Sum in a fraction (force \displaystyle)	\frac{\displaystyle \sum_{k=1}^N k^2}{a}	${\displaystyle {\frac {\displaystyle \sum _{k=1}^{N}k^{2}}{a}}}$
Sum in a fraction (alternative limits style)	\frac{\sum\limits^{^N}_{k=1} k^2}{a}	${\displaystyle {\frac {\sum \limits _{k=1}^{^{N}}k^{2}}{a}}}$
Product	\prod_{i=1}^N x_i	${\displaystyle \prod _{i=1}^{N}x_{i}}$
Product (force \textstyle)	\textstyle \prod_{i=1}^N x_i	${\displaystyle \textstyle \prod _{i=1}^{N}x_{i}}$
Coproduct	\coprod_{i=1}^N x_i	${\displaystyle \coprod _{i=1}^{N}x_{i}}$
Coproduct (force \textstyle)	\textstyle \coprod_{i=1}^N x_i	${\displaystyle \textstyle \coprod _{i=1}^{N}x_{i}}$
Limit	\lim_{n \to \infty}x_n	${\displaystyle \lim _{n\to \infty }x_{n}}$
Limit (force \textstyle)	\textstyle \lim_{n \to \infty}x_n	${\displaystyle \textstyle \lim _{n\to \infty }x_{n}}$
Integral	\int\limits_{1}^{3}\frac{e^3/x}{x^2}\, dx	${\displaystyle \int \limits _{1}^{3}{\frac {e^{3}/x}{x^{2}}}\,dx}$
Integral (alternative limits style)	\int_{1}^{3}\frac{e^3/x}{x^2}\, dx	${\displaystyle \int _{1}^{3}{\frac {e^{3}/x}{x^{2}}}\,dx}$
Integral (force \textstyle)	\textstyle \int\limits_{-N}^{N} e^x\, dx	${\displaystyle \textstyle \int \limits _{-N}^{N}e^{x}\,dx}$
Integral (force \textstyle, alternative limits style)	\textstyle \int_{-N}^{N} e^x\, dx	${\displaystyle \textstyle \int _{-N}^{N}e^{x}\,dx}$
Double integral	\iint\limits_D \, dx\,dy	${\displaystyle \iint \limits _{D}\,dx\,dy}$
Triple integral	\iiint\limits_E \, dx\,dy\,dz	${\displaystyle \iiint \limits _{E}\,dx\,dy\,dz}$
Quadruple integral	\iiiint\limits_F \, dx\,dy\,dz\,dt	${\displaystyle \iiiint \limits _{F}\,dx\,dy\,dz\,dt}$
Line or path integral	\int_{(x,y)\in C} x^3\, dx + 4y^2\, dy	${\displaystyle \int _{(x,y)\in C}x^{3}\,dx+4y^{2}\,dy}$
Closed line or path integral	\oint_{(x,y)\in C} x^3\, dx + 4y^2\, dy	${\displaystyle \oint _{(x,y)\in C}x^{3}\,dx+4y^{2}\,dy}$
Intersections	\bigcap_{i=_1}^n E_i	${\displaystyle \bigcap _{i=_{1}}^{n}E_{i}}$
Unions	\bigcup_{i=_1}^n E_i	${\displaystyle \bigcup _{i=_{1}}^{n}E_{i}}$

Display attribute[edit]

This screenshot shows the formula E = mc² being edited using VisualEditor. The visual editor shows a button that allows to choose one of three offered modes to display a formula.

The <math> tag can take a display attribute with possible values of inline and block.

Inline[edit]

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.

Example[edit]

The sum ${\textstyle \sum _{i=0}^{\infty }2^{-i}}$ 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>

Technical implementation[edit]

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.

Block[edit]

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

Example[edit]

The equation

$${\displaystyle {\text{geometric series:}}\quad {\begin{aligned}\sum _{i=0}^{\infty }2^{-i}=2\end{aligned}}}$$

It was entered as

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

Technical implementation[edit]

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

Not specified[edit]

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

Example[edit]

The sum ${\displaystyle \sum _{i=0}^{\infty }2^{-i}}$ 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

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

It was entered as

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

Fractions, matrices, multilines[edit]

Feature	Syntax	How it looks rendered
Fractions	\frac{2}{4}=0.5 or {2 \over 4}=0.5	${\displaystyle {\frac {2}{4}}=0.5}$
Small fractions (force \textstyle)	\tfrac{2}{4} = 0.5	${\displaystyle {\tfrac {2}{4}}=0.5}$
Large (normal) fractions (force \displaystyle)	\dfrac{2}{4} = 0.5 \qquad \dfrac{2}{c + \dfrac{2}{d + \dfrac{2}{4}}} = a	${\displaystyle {\dfrac {2}{4}}=0.5\qquad {\dfrac {2}{c+{\dfrac {2}{d+{\dfrac {2}{4}}}}}}=a}$
Large (nested) fractions	\cfrac{2}{c + \cfrac{2}{d + \cfrac{2}{4}}} = a	${\displaystyle {\cfrac {2}{c+{\cfrac {2}{d+{\cfrac {2}{4}}}}}}=a}$
Cancellations in fractions	\cfrac{x}{1 + \cfrac{\cancel{y}}{\cancel{y}}} = \cfrac{x}{2}	${\displaystyle {\cfrac {x}{1+{\cfrac {\cancel {y}}{\cancel {y}}}}}={\cfrac {x}{2}}}$
Binomial coefficients	\binom{n}{k}	${\displaystyle {\binom {n}{k}}}$
Small binomial coefficients (force \textstyle)	\tbinom{n}{k}	${\displaystyle {\tbinom {n}{k}}}$
Large (normal) binomial coefficients (force \displaystyle)	\dbinom{n}{k}	${\displaystyle {\dbinom {n}{k}}}$
Matrices	\begin{matrix} x & y \\ z & v \end{matrix}	${\displaystyle {\begin{matrix}x&y\\z&v\end{matrix}}}$
	\begin{vmatrix} x & y \\ z & v \end{vmatrix}	${\displaystyle {\begin{vmatrix}x&y\\z&v\end{vmatrix}}}$
	\begin{Vmatrix} x & y \\ z & v \end{Vmatrix}	${\displaystyle {\begin{Vmatrix}x&y\\z&v\end{Vmatrix}}}$
	\begin{bmatrix} 0 & \cdots & 0 \\ \vdots & \ddots & \vdots \\ 0 & \cdots & 0 \end{bmatrix}	${\displaystyle {\begin{bmatrix}0&\cdots &0\\\vdots &\ddots &\vdots \\0&\cdots &0\end{bmatrix}}}$
	\begin{Bmatrix} x & y \\ z & v \end{Bmatrix}	${\displaystyle {\begin{Bmatrix}x&y\\z&v\end{Bmatrix}}}$
	\begin{pmatrix} x & y \\ z & v \end{pmatrix}	${\displaystyle {\begin{pmatrix}x&y\\z&v\end{pmatrix}}}$
	\bigl( \begin{smallmatrix} a&b\\ c&d \end{smallmatrix} \bigr)	${\displaystyle {\bigl (}{\begin{smallmatrix}a&b\\c&d\end{smallmatrix}}{\bigr )}}$
Case distinctions	f(n) = \begin{cases} n/2, & \text{if }n\text{ is even} \\ 3n+1, & \text{if }n\text{ is odd} \end{cases}	${\displaystyle f(n)={\begin{cases}n/2,&{\text{if }}n{\text{ is even}}\\3n+1,&{\text{if }}n{\text{ is odd}}\end{cases}}}$
Multiline equations	\begin{align} f(x) & = (a+b)^2 \\ & = a^2+2ab+b^2 \\ \end{align}	${\displaystyle {\begin{aligned}f(x)&=(a+b)^{2}\\&=a^{2}+2ab+b^{2}\\\end{aligned}}}$
	\begin{alignat}{2} f(x) & = (a-b)^2 \\ & = a^2-2ab+b^2 \\ \end{alignat}	${\displaystyle {\begin{alignedat}{2}f(x)&=(a-b)^{2}\\&=a^{2}-2ab+b^{2}\\\end{alignedat}}}$
Multiline equations (must define number of columns used ({lcl})) (should not be used unless needed)	\begin{array}{lcl} z & = & a \\ f(x,y,z) & = & x + y + z \end{array}	${\displaystyle {\begin{array}{lcl}z&=&a\\f(x,y,z)&=&x+y+z\end{array}}}$
Multiline equations (more)	\begin{array}{lcr} z & = & a \\ f(x,y,z) & = & x + y + z \end{array}	${\displaystyle {\begin{array}{lcr}z&=&a\\f(x,y,z)&=&x+y+z\end{array}}}$
Breaking up a long expression so that it wraps when necessary, at the expense of destroying correct spacing	f(x) = \sum_{n=0}^\infty a_n x^n = a_0+a_1x+a_2x^2+\cdots	${\displaystyle f(x)=\sum _{n=0}^{\infty }a_{n}x^{n}=a_{0}+a_{1}x+a_{2}x^{2}+\cdots }$
Simultaneous equations	\begin{cases} 3x + 5y + z \\ 7x - 2y + 4z \\ -6x + 3y + 2z \end{cases}	${\displaystyle {\begin{cases}3x+5y+z\\7x-2y+4z\\-6x+3y+2z\end{cases}}}$
Arrays	\begin{array}{|c|c|c|} a & b & S \\ \hline 0&0&1\\ 0&1&1\\ 1&0&1\\ 1&1&0\\ \end{array}	${\displaystyle {\begin{array}{|c|c|c|}a&b&S\\\hline 0&0&1\\0&1&1\\1&0&1\\1&1&0\\\end{array}}}$

Parenthesizing big expressions, brackets, bars[edit]

Feature	Syntax	How it looks rendered
NBad	( \frac{1}{2} )	${\displaystyle ({\frac {1}{2}})}$
GoodY	\left ( \frac{1}{2} \right )	${\displaystyle \left({\frac {1}{2}}\right)}$

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

Feature	Syntax	How it looks rendered
Parentheses	\left ( \frac{a}{b} \right )	${\displaystyle \left({\frac {a}{b}}\right)}$
Brackets	\left [ \frac{a}{b} \right ] \quad \left \lbrack \frac{a}{b} \right \rbrack	${\displaystyle \left[{\frac {a}{b}}\right]\quad \left\lbrack {\frac {a}{b}}\right\rbrack }$
Braces	\left \{ \frac{a}{b} \right \} \quad \left \lbrace \frac{a}{b} \right \rbrace	${\displaystyle \left\{{\frac {a}{b}}\right\}\quad \left\lbrace {\frac {a}{b}}\right\rbrace }$
Angle brackets	\left \langle \frac{a}{b} \right \rangle	${\displaystyle \left\langle {\frac {a}{b}}\right\rangle }$
Bars and double bars	\left | \frac{a}{b} \right \vert \quad \left \Vert \frac{c}{d} \right \|	${\displaystyle \left|{\frac {a}{b}}\right\vert \quad \left\Vert {\frac {c}{d}}\right\|}$
Floor and ceiling functions:	\left \lfloor \frac{a}{b} \right \rfloor \quad \left \lceil \frac{c}{d} \right \rceil	${\displaystyle \left\lfloor {\frac {a}{b}}\right\rfloor \quad \left\lceil {\frac {c}{d}}\right\rceil }$
Slashes and backslashes	\left / \frac{a}{b} \right \backslash	${\displaystyle \left/{\frac {a}{b}}\right\backslash }$
Up, down, and up-down arrows	\left \uparrow \frac{a}{b} \right \downarrow \quad \left \Uparrow \frac{a}{b} \right \Downarrow \quad \left \updownarrow \frac{a}{b} \right \Updownarrow	${\displaystyle \left\uparrow {\frac {a}{b}}\right\downarrow \quad \left\Uparrow {\frac {a}{b}}\right\Downarrow \quad \left\updownarrow {\frac {a}{b}}\right\Updownarrow }$
Delimiters can be mixed, as long as \left and \right match	\left [ 0,1 \right ) \left \langle \psi \right |	${\displaystyle \left[0,1\right)}$ ${\displaystyle \left\langle \psi \right|}$
Use \left. and \right. if you do not want a delimiter to appear	\left . \frac{A}{B} \right \} \to X	${\displaystyle \left.{\frac {A}{B}}\right\}\to X}$
Size of the delimiters (add "l" or "r" to indicate the side for proper spacing)	( \bigl( \Bigl( \biggl( \Biggl( \dots \Biggr] \biggr] \Bigr] \bigr] ]	${\displaystyle ({\bigl (}{\Bigl (}{\biggl (}{\Biggl (}\dots {\Biggr ]}{\biggr ]}{\Bigr ]}{\bigr ]}]}$
	\{ \bigl\{ \Bigl\{ \biggl\{ \Biggl\{ \dots \Biggr\rangle \biggr\rangle \Bigr\rangle \bigr\rangle \rangle	${\displaystyle \{{\bigl \{}{\Bigl \{}{\biggl \{}{\Biggl \{}\dots {\Biggr \rangle }{\biggr \rangle }{\Bigr \rangle }{\bigr \rangle }\rangle }$
	\| \big\| \Big\| \bigg\| \Bigg\| \dots \Bigg| \bigg| \Big| \big| |	${\displaystyle \|{\big \|}{\Big \|}{\bigg \|}{\Bigg \|}\dots {\Bigg |}{\bigg |}{\Big |}{\big |}|}$
	\lfloor \bigl\lfloor \Bigl\lfloor \biggl\lfloor \Biggl\lfloor \dots \Biggr\rceil \biggr\rceil \Bigr\rceil \bigr\rceil \ceil	${\displaystyle \lfloor {\bigl \lfloor }{\Bigl \lfloor }{\biggl \lfloor }{\Biggl \lfloor }\dots {\Biggr \rceil }{\biggr \rceil }{\Bigr \rceil }{\bigr \rceil }\rceil }$
	\uparrow \big\uparrow \Big\uparrow \bigg\uparrow \Bigg\uparrow \dots \Bigg\Downarrow \bigg\Downarrow \Big\Downarrow \big\Downarrow \Downarrow	${\displaystyle \uparrow {\big \uparrow }{\Big \uparrow }{\bigg \uparrow }{\Bigg \uparrow }\dots {\Bigg \Downarrow }{\bigg \Downarrow }{\Big \Downarrow }{\big \Downarrow }\Downarrow }$
	\updownarrow \big\updownarrow \Big\updownarrow \bigg\updownarrow \Bigg\updownarrow \dots \Bigg\Updownarrow \bigg\Updownarrow \Big\Updownarrow \big\Updownarrow \Updownarrow	${\displaystyle \updownarrow {\big \updownarrow }{\Big \updownarrow }{\bigg \updownarrow }{\Bigg \updownarrow }\dots {\Bigg \Updownarrow }{\bigg \Updownarrow }{\Big \Updownarrow }{\big \Updownarrow }\Updownarrow }$
	/ \big/ \Big/ \bigg/ \Bigg/ \dots \Bigg\backslash \bigg\backslash \Big\backslash \big\backslash \backslash	${\displaystyle /{\big /}{\Big /}{\bigg /}{\Bigg /}\dots {\Bigg \backslash }{\bigg \backslash }{\Big \backslash }{\big \backslash }\backslash }$

Equation numbering[edit]

The templates {{NumBlk}} and {{EquationRef}} can be used to number equations. The template {{EquationNote}} 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):

${\displaystyle x^{2}+y^{2}+z^{2}=1}$

(1)

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 (1), blah blah blah...

Note that the equation number produced by {{EquationNote}} is a link that the user can click to go immediately to the cited equation.

Alphabets and typefaces[edit]

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.

Greek alphabet
\Alpha \Beta \Gamma \Delta \Epsilon \Zeta \Eta \Theta	${\displaystyle \mathrm {A} \mathrm {B} \Gamma \Delta \mathrm {E} \mathrm {Z} \mathrm {H} \Theta \!}$
\Iota \Kappa \Lambda \Mu \Nu \Xi \Pi \Rho	${\displaystyle \mathrm {I} \mathrm {K} \Lambda \mathrm {M} \mathrm {N} \Xi \Pi \mathrm {P} \!}$
\Sigma \Tau \Upsilon \Phi \Chi \Psi \Omega	${\displaystyle \Sigma \mathrm {T} \Upsilon \Phi \mathrm {X} \Psi \Omega \!}$
\alpha \beta \gamma \delta \epsilon \zeta \eta \theta	${\displaystyle \alpha \beta \gamma \delta \epsilon \zeta \eta \theta \!}$
\iota \kappa \lambda \mu \nu \xi \pi \rho	${\displaystyle \iota \kappa \lambda \mu \nu \xi \pi \rho \!}$
\sigma \tau \upsilon \phi \chi \psi \omega	${\displaystyle \sigma \tau \upsilon \phi \chi \psi \omega \!}$
\varepsilon \digamma \varkappa \varpi	${\displaystyle \varepsilon \digamma \varkappa \varpi \!}$
\varrho \varsigma \vartheta \varphi	${\displaystyle \varrho \varsigma \vartheta \varphi \!}$
Hebrew symbols
\aleph \beth \gimel \daleth	${\displaystyle \aleph \beth \gimel \daleth \!}$
Blackboard bold/scripts
\mathbb{ABCDEFGHI}	${\displaystyle \mathbb {ABCDEFGHI} \!}$
\mathbb{JKLMNOPQR}	${\displaystyle \mathbb {JKLMNOPQR} \!}$
\mathbb{STUVWXYZ}	${\displaystyle \mathbb {STUVWXYZ} \!}$
Boldface
\mathbf{ABCDEFGHI}	${\displaystyle \mathbf {ABCDEFGHI} \!}$
\mathbf{JKLMNOPQR}	${\displaystyle \mathbf {JKLMNOPQR} \!}$
\mathbf{STUVWXYZ}	${\displaystyle \mathbf {STUVWXYZ} \!}$
\mathbf{abcdefghijklm}	${\displaystyle \mathbf {abcdefghijklm} \!}$
\mathbf{nopqrstuvwxyz}	${\displaystyle \mathbf {nopqrstuvwxyz} \!}$
\mathbf{0123456789}	${\displaystyle \mathbf {0123456789} \!}$
Boldface (Greek)
\boldsymbol{\Alpha\Beta\Gamma\Delta\Epsilon\Zeta\Eta\Theta}	${\displaystyle {\boldsymbol {\mathrm {A} \mathrm {B} \Gamma \Delta \mathrm {E} \mathrm {Z} \mathrm {H} \Theta }}\!}$
\boldsymbol{\Iota\Kappa\Lambda\Mu\Nu\Xi\Pi\Rho}	${\displaystyle {\boldsymbol {\mathrm {I} \mathrm {K} \Lambda \mathrm {M} \mathrm {N} \Xi \Pi \mathrm {P} }}\!}$
\boldsymbol{\Sigma\Tau\Upsilon\Phi\Chi\Psi\Omega}	${\displaystyle {\boldsymbol {\Sigma \mathrm {T} \Upsilon \Phi \mathrm {X} \Psi \Omega }}\!}$
\boldsymbol{\alpha\beta\gamma\delta\epsilon\zeta\eta\theta}	${\displaystyle {\boldsymbol {\alpha \beta \gamma \delta \epsilon \zeta \eta \theta }}\!}$
\boldsymbol{\iota\kappa\lambda\mu\nu\xi\pi\rho}	${\displaystyle {\boldsymbol {\iota \kappa \lambda \mu \nu \xi \pi \rho }}\!}$
\boldsymbol{\sigma\tau\upsilon\phi\chi\psi\omega}	${\displaystyle {\boldsymbol {\sigma \tau \upsilon \phi \chi \psi \omega }}\!}$
\boldsymbol{\varepsilon\digamma\varkappa\varpi}	${\displaystyle {\boldsymbol {\varepsilon \digamma \varkappa \varpi }}\!}$
\boldsymbol{\varrho\varsigma\vartheta\varphi}	${\displaystyle {\boldsymbol {\varrho \varsigma \vartheta \varphi }}\!}$
Italics (default for Latin alphabet)
\mathit{0123456789}	${\displaystyle {\mathit {0123456789}}\!}$
Greek italics (default for lowercase Greek)
\mathit{\Alpha\Beta\Gamma\Delta\Epsilon\Zeta\Eta\Theta}	${\displaystyle {\mathit {\mathrm {A} \mathrm {B} \Gamma \Delta \mathrm {E} \mathrm {Z} \mathrm {H} \Theta }}\!}$
\mathit{\Iota\Kappa\Lambda\Mu\Nu\Xi\Pi\Rho}	${\displaystyle {\mathit {\mathrm {I} \mathrm {K} \Lambda \mathrm {M} \mathrm {N} \Xi \Pi \mathrm {P} }}\!}$
\mathit{\Sigma\Tau\Upsilon\Phi\Chi\Psi\Omega}	${\displaystyle {\mathit {\Sigma \mathrm {T} \Upsilon \Phi \mathrm {X} \Psi \Omega }}\!}$
Roman typeface
\mathrm{ABCDEFGHI}	${\displaystyle \mathrm {ABCDEFGHI} \!}$
\mathrm{JKLMNOPQR}	${\displaystyle \mathrm {JKLMNOPQR} \!}$
\mathrm{STUVWXYZ}	${\displaystyle \mathrm {STUVWXYZ} \!}$
\mathrm{abcdefghijklm}	${\displaystyle \mathrm {abcdefghijklm} \!}$
\mathrm{nopqrstuvwxyz}	${\displaystyle \mathrm {nopqrstuvwxyz} \!}$
\mathrm{0123456789}	${\displaystyle \mathrm {0123456789} \!}$
Sans serif
\mathsf{ABCDEFGHI}	${\displaystyle {\mathsf {ABCDEFGHI}}\!}$
\mathsf{JKLMNOPQR}	${\displaystyle {\mathsf {JKLMNOPQR}}\!}$
\mathsf{STUVWXYZ}	${\displaystyle {\mathsf {STUVWXYZ}}\!}$
\mathsf{abcdefghijklm}	${\displaystyle {\mathsf {abcdefghijklm}}\!}$
\mathsf{nopqrstuvwxyz}	${\displaystyle {\mathsf {nopqrstuvwxyz}}\!}$
\mathsf{0123456789}	${\displaystyle {\mathsf {0123456789}}\!}$
Sans serif Greek (capital only)
\mathsf{\Alpha \Beta \Gamma \Delta \Epsilon \Zeta \Eta \Theta}	${\displaystyle {\mathsf {\mathrm {A} \mathrm {B} \Gamma \Delta \mathrm {E} \mathrm {Z} \mathrm {H} \Theta }}\!}$
\mathsf{\Iota \Kappa \Lambda \Mu \Nu \Xi \Pi \Rho}	${\displaystyle {\mathsf {\mathrm {I} \mathrm {K} \Lambda \mathrm {M} \mathrm {N} \Xi \Pi \mathrm {P} }}\!}$
\mathsf{\Sigma \Tau \Upsilon \Phi \Chi \Psi \Omega}	${\displaystyle {\mathsf {\Sigma \mathrm {T} \Upsilon \Phi \mathrm {X} \Psi \Omega }}\!}$
Calligraphy/script
\mathcal{ABCDEFGHI}	${\displaystyle {\mathcal {ABCDEFGHI}}\!}$
\mathcal{JKLMNOPQR}	${\displaystyle {\mathcal {JKLMNOPQR}}\!}$
\mathcal{STUVWXYZ}	${\displaystyle {\mathcal {STUVWXYZ}}\!}$
Fraktur typeface
\mathfrak{ABCDEFGHI}	${\displaystyle {\mathfrak {ABCDEFGHI}}\!}$
\mathfrak{JKLMNOPQR}	${\displaystyle {\mathfrak {JKLMNOPQR}}\!}$
\mathfrak{STUVWXYZ}	${\displaystyle {\mathfrak {STUVWXYZ}}\!}$
\mathfrak{abcdefghijklm}	${\displaystyle {\mathfrak {abcdefghijklm}}\!}$
\mathfrak{nopqrstuvwxyz}	${\displaystyle {\mathfrak {nopqrstuvwxyz}}\!}$
\mathfrak{0123456789}	${\displaystyle {\mathfrak {0123456789}}\!}$
Small scriptstyle text
{\scriptstyle\text{abcdefghijklm}}	${\displaystyle {\scriptstyle {\text{abcdefghijklm}}}}$