Jean-François Mertens: Difference between revisions

Revision as of 01:45, 1 February 2014

In mathematics, Viennot's geometric construction (named after Xavier Gérard Viennot) gives a diagrammatic interpretation of the Robinson–Schensted correspondence in terms of shadow lines.

The construction

Starting with a permutation $\sigma \in S_{n}$ , written in two-line notation, say:

\sigma ={\begin{pmatrix}1&2&\cdots &n\\\sigma _{1}&\sigma _{2}&\cdots &\sigma _{n}\end{pmatrix}},

one can apply the Robinson–Schensted correspondence to this permutation, yielding two standard Young tableaux of the same shape, P and Q. P is obtained by performing a sequence of insertions, and Q is the recording tableau, indicating in which order the boxes were filled.

Viennot's construction starts by plotting the points $(i,\sigma _{i})$ in the plane, and imagining there is a light that shines from the origin, casting shadows straight up and to the right. This allows consideration of the points which are not shadowed by any other point; the boundary of their shadows then forms the first shadow line. Removing these points and repeating the procedure, one obtains all the shadow lines for this permutation. Viennot's insight is then that these shadow lines read off the first rows of P and Q (in fact, even more than that; these shadow lines form a "timeline", indicating which elements formed the first rows of P and Q after the successive insertions). One can then repeat the construction, using as new points the previous unlabelled corners, which allows to read off the other rows of P and Q.

Animation

For example consider the permutation

\sigma ={\begin{pmatrix}1&2&3&4&5&6&7&8\\3&8&1&2&4&7&5&6\end{pmatrix}}.

Then Viennot's construction goes as follows:

Applications

One can use Viennot's geometric construction to prove that if $\sigma$ corresponds to the pair of tableaux P,Q under the Robinson–Schensted correspondence, then $\sigma ^{-1}$ corresponds to the switched pair Q,P. Indeed, taking $\sigma$ to $\sigma ^{-1}$ reflects Viennot's construction in the $y=x$ -axis, and this precisely switches the roles of P and Q.

References

Bruce E. Sagan. The Symmetric Group. Springer, 2001.

@@ Line 1: / Line 1: @@
+In mathematics, '''Viennot's geometric construction''' (named after Xavier Gérard Viennot) gives a diagrammatic interpretation of the [[Robinson–Schensted correspondence]] in terms of '''shadow lines'''.
+==The construction==
+Starting with a permutation <math> \sigma \in S_n </math>, written in two-line notation, say:
-One technique of examining for incoming links is to utilize link popularity services such as http://LinkPopularity.com and http://Marketleap.com. <br><br>Bear in mind that unlike MSN and Yahoo, Google doesn&quot;t always display all of your backlinks. <br><br>Technorati -Another way for finding what sites are linking to you would be to examine Technorati. To check yo... <br><br>Having backlinks is essential for your website, because it helps increase its popularity. There are many means open to check always your incoming links. <br><br>One method of checking for incoming links is to use link acceptance services such as http://LinkPopularity.com and http://Marketleap.com. <br><br>Remember that unlike MSN and Yahoo, Google doesn&quot;t always show your entire backlinks. <br><br>Technorati -Another method for finding what blogs are linking to you is to examine Technorati. Discover additional info on this affiliated website by clicking [http://m.bizcommunity.com/View.aspx?ct=5&cst=0&i=190833&eh=4UMG9&msg=y&us=1 linklicious vs backlinks indexer]. To check your links on Technorati use the following method http://www.technorati.com/search/ http://yourblogtitle.com. <br><br>Technorati states which they make an effort to catalog complete content from blogs. If they can&quot;t find a complete information, they index the HTML o-n the front page. For supplementary information, you may check out: [http://about.me/rentlinkliciousssh linklicious]. Any information that will not be present in either of the sites does not get found currently. So if your blogs RSS isn&quot;t set to full, then it is probable that not all backlinks will show in Technorati. <br><br>Google Blogsearch- http://blogsearch.google.com is yet another spot to look for new incoming links to your blog. Google blog search lets you search via a particular timeframe, including sites linking in within the last hour, 12 hours, 1 week or weeks. Google Blogsearch allows you to subscribe to the outcomes via FEED therefore youll be updated whenever a new site links to your weblog. <br><br>Ask.com Website Search - http://Ask.com special algorithm includes http://Ask.com research and Bloglines membership information. Searches may be performed by posts, feeds or media. High level search functions are available. http://www.ask.com/?tool=bls <br><br>Icerocket Blog Search- http://icerocket.com is a blog search engine like Google Blog Search. Icerocket Website Search enables you to track links from other blogs for your articles. [http://scriptogr.am/linkliciousprobmq Linklicious Wordpress Plugin] includes further concerning the inner workings of it. To check on your links at Icerocket typ-e this query to the research area link: http://yourblogtitle.com. <br><br>Backlinkwatch- http://backlinkwatch.com provides an all-in-one service to check on your backlinks. The company reports backlinks along with their PR, point text and if its a nofollow or follow backlink. <br><br>PopUri - http://popuri.us is an o-nline software which checks the link popularity of any site depending on its rating. <br><br>Google offers Google Webmaster Tools, which also shows how many incoming links for your site and Blog Pulse Search reports everyday incoming links to your website too. <br><br>Always check your incoming links through these different methods to acquire a wider range of just who is relating to your website.<br><br>If you have any type of inquiries concerning where and ways to use [http://ovalranch1562.soup.io current events health], you could contact us at the internet site.
+: <math> \sigma = \begin{pmatrix}
+& 2 & \cdots & n \\
+\sigma_1 & \sigma_2 & \cdots & \sigma_n
+  \end{pmatrix},</math>
+one can apply the Robinson–Schensted correspondence to this permutation, yielding two [[Young tableau|standard Young tableaux]] of the same shape, ''P'' and ''Q''. ''P'' is obtained by performing a sequence of insertions, and ''Q'' is the recording tableau, indicating in which order the boxes were filled.
+Viennot's construction starts by plotting the points <math> (i, \sigma_i) </math> in the plane, and imagining there is a light that shines from the origin, casting shadows straight up and to the right. This allows consideration of the points which are not shadowed by any other point; the boundary of their shadows then forms the first shadow line. Removing these points and repeating the procedure, one obtains all the shadow lines for this permutation. Viennot's insight is then that these shadow lines read off the first rows of ''P'' and ''Q'' (in fact, even more than that; these shadow lines form a "timeline", indicating which elements formed the first rows of ''P'' and ''Q'' after the successive insertions). One can then repeat the construction, using as new points the previous unlabelled corners, which allows to read off the other rows of ''P'' and ''Q''.
+==Animation==
+For example consider the permutation
+: <math> \sigma = \begin{pmatrix}
+& 2 & 3 & 4 & 5 & 6 & 7 & 8 \\
+& 8 & 1 & 2 & 4 & 7 & 5 & 6
+  \end{pmatrix}.
+</math>
+Then Viennot's construction goes as follows:
+[[Image:ViennotAnimation.gif]]
+==Applications==
+One can use Viennot's geometric construction to prove that if <math>\sigma</math> corresponds to the pair of tableaux ''P'',''Q'' under the Robinson–Schensted correspondence, then <math>\sigma^{-1}</math> corresponds to the switched pair ''Q'',''P''. Indeed, taking <math>\sigma</math> to <math>\sigma^{-1}</math> reflects Viennot's construction in the <math>y=x</math>-axis, and this precisely switches the roles of ''P'' and ''Q''.
+==See also==
+* [[Plactic monoid]]
+* [[Jeu de taquin]]
+==References==
+* [[Bruce Sagan|Bruce E. Sagan]]. ''The Symmetric Group''. Springer, 2001.
+[[Category:Algebraic combinatorics]]

Jean-François Mertens: Difference between revisions

Revision as of 01:45, 1 February 2014

Contents

The construction

Animation

Applications

See also

References

Navigation menu