The Coloured Jones Polynomials: Difference between revisions
No edit summary |
DrorsRobot (talk | contribs) No edit summary |
||
| Line 6: | Line 6: | ||
{{Startup Note}} |
{{Startup Note}} |
||
<!--$$?ColouredJones$$--> |
<!--$$?ColouredJones$$--> |
||
<!--The lines to END were generated by WikiSplice: do not edit; see manual.--> |
|||
{{HelpAndAbout1|n=2|s=ColouredJones}} |
|||
ColouredJones[br, n][q] computes the coloured Jones polynomial of the closure of the braid br in colour n (i.e., in the (n+1)-dimensional representation) and with respect to the variable q. ColouredJones[K, n][q] does the same for knots for which a braid representative is known to this program. |
|||
{{HelpAndAbout2|n=3|s=ColouredJones}} |
|||
The ColouredJones program was written jointly with Stavros Garoufalidis, based on formulas provided to us by Thang Le. |
|||
{{HelpAndAbout3}} |
|||
<!--END--> |
<!--END--> |
||
| Line 12: | Line 18: | ||
<!--$$ColouredJones[Knot[4, 1], 3][q]$$--> |
<!--$$ColouredJones[Knot[4, 1], 3][q]$$--> |
||
<!--The lines to END were generated by WikiSplice: do not edit; see manual.--> |
|||
{{InOut1|n=4}} |
|||
<pre style="color: red; border: 0px; padding: 0em"><nowiki>ColouredJones[Knot[4, 1], 3][q]</nowiki></pre> |
|||
{{InOut2|n=4}}<pre style="border: 0px; padding: 0em"><nowiki> -12 -11 -10 2 2 3 3 2 4 6 8 10 11 12 |
|||
3 + q - q - q + -- - -- + -- - -- - 3 q + 3 q - 2 q + 2 q - q - q + q |
|||
8 6 4 2 |
|||
q q q q</nowiki></pre> |
|||
{{InOut3}} |
|||
<!--END--> |
<!--END--> |
||
| Line 19: | Line 33: | ||
<!--$$ColouredJones[Knot[4, 1], 1][q]$$--> |
<!--$$ColouredJones[Knot[4, 1], 1][q]$$--> |
||
<!--The lines to END were generated by WikiSplice: do not edit; see manual.--> |
|||
{{InOut1|n=5}} |
|||
<pre style="color: red; border: 0px; padding: 0em"><nowiki>ColouredJones[Knot[4, 1], 1][q]</nowiki></pre> |
|||
{{InOut2|n=5}}<pre style="border: 0px; padding: 0em"><nowiki> -2 1 2 |
|||
1 + q - - - q + q |
|||
q</nowiki></pre> |
|||
{{InOut3}} |
|||
<!--END--> |
<!--END--> |
||
<!--$$Jones[Knot[4, 1]][q]$$--> |
<!--$$Jones[Knot[4, 1]][q]$$--> |
||
<!--The lines to END were generated by WikiSplice: do not edit; see manual.--> |
|||
{{InOut1|n=6}} |
|||
<pre style="color: red; border: 0px; padding: 0em"><nowiki>Jones[Knot[4, 1]][q]</nowiki></pre> |
|||
{{InOut2|n=6}}<pre style="border: 0px; padding: 0em"><nowiki> -2 1 2 |
|||
1 + q - - - q + q |
|||
q</nowiki></pre> |
|||
{{InOut3}} |
|||
<!--END--> |
<!--END--> |
||
<!--$$?CJ`Summand$$--> |
<!--$$?CJ`Summand$$--> |
||
<!--The lines to END were generated by WikiSplice: do not edit; see manual.--> |
|||
{{Help1|n=7|s=CJ`Summand}} |
|||
CJ`Summand[br, n] returned a pair {s, vars} where s is the summand in the the big sum that makes up ColouredJones[br, n][q] and where vars is the list of variables that need to be summed over (from 0 to n) to get ColouredJones[br, n][q]. CJ`Summand[K, n] is the same for knots for which a braid representative is known to this program. |
|||
{{Help2}} |
|||
<!--END--> |
<!--END--> |
||
Revision as of 17:42, 26 August 2005
KnotTheory` can compute the coloured Jones polynomial of braid
closures, using the same formulas as in [Garoufalidis Le]:
(For In[1] see Setup)
In[2]:= ?ColouredJones
ColouredJones[br, n][q] computes the coloured Jones polynomial of the closure of the braid br in colour n (i.e., in the (n+1)-dimensional representation) and with respect to the variable q. ColouredJones[K, n][q] does the same for knots for which a braid representative is known to this program. |
In[3]:= ColouredJones::about
The ColouredJones program was written jointly with Stavros Garoufalidis, based on formulas provided to us by Thang Le. |
Thus, for example, here's the coloured Jones polynomial of the knot 4_1 in the 4-dimensional representation of :
| In[4]:= |
ColouredJones[Knot[4, 1], 3][q] |
| Out[4]= | -12 -11 -10 2 2 3 3 2 4 6 8 10 11 12
3 + q - q - q + -- - -- + -- - -- - 3 q + 3 q - 2 q + 2 q - q - q + q
8 6 4 2
q q q q
|
And here's the coloured Jones polynomial of the same knot in the two dimensional representation of ; this better be equal to the ordinary Jones polynomial of 4_1!
| In[5]:= |
ColouredJones[Knot[4, 1], 1][q] |
| Out[5]= | -2 1 2
1 + q - - - q + q
q
|
| In[6]:= |
Jones[Knot[4, 1]][q] |
| Out[6]= | -2 1 2
1 + q - - - q + q
q
|
In[7]:= ?CJ`Summand
CJ`Summand[br, n] returned a pair {s, vars} where s is the summand in the the big sum that makes up ColouredJones[br, n][q] and where vars is the list of variables that need to be summed over (from 0 to n) to get ColouredJones[br, n][q]. CJ`Summand[K, n] is the same for knots for which a braid representative is known to this program. |
The coloured Jones polynomial of \hlink{../Knots/3.1.html}{$3_1$} is computed via a single summation. Indeed,
<*InOut@"s = CJ`Summand[Mirror[Knot[3, 1]], n]"*> \vskip 6pt
The symbols in the above formula require a definition:
\index{Riese, Axel} \index{Weisstein, Eric} <* HelpBox[{qPochhammer, qBinomial}] *>
More precisely, {\tt qPochhammer[a, q, k]} is \[
(a;q)_k=\begin{cases}
(1-a)(1-aq)\dots(1-aq^{k-1}) & k>0 \\
1 & k=0 \\
\left((1-aq^{-1})(1-aq^{-2})\dots(1-aq^{k})\right)^{-1} & k<0
\end{cases}
\] and {\tt qBinomial[n, k, q]} is \[
\binom{n}{k}_q = \begin{cases}
\frac
{\displaystyle (q^{n-k+1};q)_k}
{\displaystyle (q;q)_k
} & k\geq 0 \\
0 & k<0.
\end{cases}
\]
The function {\tt qExpand} replaces every occurence of a {\tt qPochhammer} symbol or a {\tt qBinomial} symbol by its definition:
<* HelpBox[qExpand] *>
Hence,
<*InOut@"qPochhammer[a, q, 6] // qExpand"*> <*InOut@"First[s] /. {n -> 3, CJ`k[1] -> 2} // qExpand"*> \vskip 6pt
Finally,
<* ColoredJones=.; HelpBox[ColoredJones] *>
[Garoufalidis Le] ^ S. Garoufalidis and T. Q. T. Le, The Colored Jones Function is -Holonomic, Georgia Institute of Technology preprint, September 2003, arXiv:math.GT/0309214.
