Difference between revisions of "Toolbox"

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(Undo revision 13732 by 64.134.238.222 (talk))
(Undo revision 13733 by 64.134.238.222 (talk))
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'''texvc''' ('''TeX validator and converter''') is a program which renders mathematical formulae in LaTeX-syntax and outputs graphics that are embedded in wiki articles.  
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'''MathJax''' ('''TeX validator and converter''') is a program which renders mathematical formulae in LaTeX-syntax and outputs graphics that are embedded in wiki articles.  
  
WEBMASTER COMMENT - THE TeX MATH CAPABILITY IS UNDER REPAIR AS WE TRANSITION TO A NEW SERVER.
 
  
Click on ''edit'' to view the LaTeX-syntax in between the ''math''-tag. If texvc is not installed in your Mediawiki-Installation the graphics output is not visible.
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Click on ''edit'' to view the LaTeX-syntax in between the ''math''-tag.  
  
 
Here are some examples of LaTeX output produced in this manner:
 
Here are some examples of LaTeX output produced in this manner:
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<center><math>\Omega(z) = \frac{1}{2\pi i}\int_{\Gamma}{\frac{\lambda(\delta)}{z-\delta}d\delta}</math></center>
 
<center><math>\Omega(z) = \frac{1}{2\pi i}\int_{\Gamma}{\frac{\lambda(\delta)}{z-\delta}d\delta}</math></center>
 
==External links==
 
 
* [http://svn.wikimedia.org/viewvc/mediawiki/trunk/phase3/math/README?view=markup The texvc README file in SVN]
 

Revision as of 11:15, 2 December 2012

MathJax (TeX validator and converter) is a program which renders mathematical formulae in LaTeX-syntax and outputs graphics that are embedded in wiki articles.


Click on edit to view the LaTeX-syntax in between the math-tag.

Here are some examples of LaTeX output produced in this manner:

  • <math>\int_a^xf(\zeta\,z)\,dx</math>
  • <math>\int_1^\infty \frac{1}{k^2}\,dk</math>
  • <math>\sqrt{x^2+2x+1}=|x+1| - ((\frac{2x^2}{x})^2)^2</math>
  • <math>\ E = \sum_{i=1}^N e^{- J_{ij} \sigma_i \sigma_j} </math>
  • <math>\ \Phi = \frac{Q}{2\pi}\log(z-z_w) </math>


And here is a real case example, the Cauchy singular integral:

<math>\Omega(z) = \frac{1}{2\pi i}\int_{\Gamma}{\frac{\lambda(\delta)}{z-\delta}d\delta}</math>