KnotTheory` can compute the coloured Jones polynomial of braid
closures, using the same formulas as in [Garoufalidis Le]:
(For In[1] see Setup)
| In[1]:=
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?ColouredJones
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| 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.
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| In[2]:=
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ColouredJones::about
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| The ColouredJones program was written jointly with Stavros Garoufalidis, based on formulas provided to us by Thang Le.
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Thus, for example, here's the coloured Jones polynomial of the knot
4_1 in the 4-dimensional representation of 
:
In[3]:=
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ColouredJones[Knot[4, 1], 3][q]
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Out[3]=
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-12 -11 -10 2 2 3 3 2 4 6
3 + q - q - q + -- - -- + -- - -- - 3 q + 3 q - 2 q +
8 6 4 2
q q q q
8 10 11 12
2 q - q - q + q
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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[4]:=
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ColouredJones[Knot[4, 1], 1][q]
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Out[4]=
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-2 1 2
1 + q - - - q + q
q
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In[5]:=
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Jones[Knot[4, 1]][q]
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Out[5]=
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-2 1 2
1 + q - - - q + q
q
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| In[6]:=
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?CJ`Summand
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| 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.
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The coloured Jones polynomial of 3_1 is computed via a single summation. Indeed,
In[7]:=
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s = CJ`Summand[Mirror[Knot[3, 1]], n]
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Out[7]=
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(3 n)/2 + n CJ`k[1] + (-n + 2 CJ`k[1])/2 1
{CJ`q qBinomial[0, 0, ----]
CJ`q
1 1
qBinomial[CJ`k[1], 0, ----] qBinomial[CJ`k[1], CJ`k[1], ----]
CJ`q CJ`q
n 1 n 1
qPochhammer[CJ`q , ----, 0] qPochhammer[CJ`q , ----, CJ`k[1]]
CJ`q CJ`q
n - CJ`k[1] 1
qPochhammer[CJ`q , ----, 0], {CJ`k[1]}}
CJ`q
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The symbols in the above formula require a definition:
| In[8]:=
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?qPochhammer
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| qPochhammer[a, q, k] represents the q-shifted factorial of a in base q with index k. See Eric Weisstein's
http://mathworld.wolfram.com/q-PochhammerSymbol.html and Axel Riese's
www.risc.uni-linz.ac.at/research/combinat/risc/software/qMultiSum/
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| In[9]:=
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?qBinomial
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| qBinomial[n, k, q] represents the q-binomial coefficient of n and k in base q. For k<0 it is 0; otherwise it is
qPochhammer[q^(n-k+1), q, k] / qPochhammer[q, q, k].
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More precisely, qPochhammer[a, q, k] is
and qBinomial[n, k, q] is
The function qExpand replaces every occurence of a qPochhammer[a, q, k]
symbol or a qBinomial[n, k, q] symbol by its definition:
| In[10]:=
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?qExpand
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| qExpand[expr_] replaces all occurences of qPochhammer and qBinomial in expr by their definitions as products. See the documentation for qPochhammer and for qBinomial for details.
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Hence,
In[11]:=
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qPochhammer[a, q, 6] // qExpand
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Out[11]=
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2 3 4 5
(-1 + a) (-1 + a q) (-1 + a q ) (-1 + a q ) (-1 + a q ) (-1 + a q )
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In[12]:=
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First[s] /. {n -> 3, CJ`k[1] -> 2} // qExpand
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Out[12]=
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11 2 3
CJ`q (-1 + CJ`q ) (-1 + CJ`q )
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Finally,
| In[13]:=
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?ColoredJones
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| Type ColoredJones and see for yourself.
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[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.
