T(3,2)

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	See 3_1.

T(3,2) Further Notes and Views

Knot presentations

Planar diagram presentation	X₃₁₄₆ X₁₅₂₄ X₅₃₆₂
Gauss code	-2, 3, -1, 2, -3, 1
Dowker-Thistlethwaite code	4 6 2
Conway Notation	Data:T(3,2)/Conway Notation

Polynomial invariants

Alexander polynomial	$t-1+t^{-1}$
Conway polynomial	$z^{2}+1$
2nd Alexander ideal (db, data sources)	$\{1\}$
Determinant and Signature	{ 3, 2 }
Jones polynomial	$-q^{4}+q^{3}+q$
HOMFLY-PT polynomial (db, data sources)	$z^{2}a^{-2}+2a^{-2}-a^{-4}$
Kauffman polynomial (db, data sources)	$z^{2}a^{-2}+z^{2}a^{-4}+za^{-3}+za^{-5}-2a^{-2}-a^{-4}$
The A2 invariant	Data:T(3,2)/QuantumInvariant/A2/1,0
The G2 invariant	Data:T(3,2)/QuantumInvariant/G2/1,0

Further Quantum Invariants

T(3,2) Quantum Invariants.

Computer Talk

The above data is available with the Mathematica package KnotTheory`, as shown in the (simulated) Mathematica session below. Your input (in red) is realistic; all else should have the same content as in a real mathematica session, but with different formatting. This Mathematica session is also available (albeit only for the knot 5_2) as the notebook PolynomialInvariantsSession.nb.

(The path below may be different on your system, and possibly also the KnotTheory` date)

In[1]:= AppendTo[$Path, "C:/drorbn/projects/KAtlas/"]; << KnotTheory`

Loading KnotTheory` version of August 31, 2006, 11:25:27.5625.

In[3]:= K = Knot["T(3,2)"];

In[4]:= Alexander[K][t]

KnotTheory::loading: Loading precomputed data in PD4Knots`.

Out[4]= $t-1+t^{-1}$

In[5]:= Conway[K][z]

Out[5]= $z^{2}+1$

In[6]:= Alexander[K, 2][t]

KnotTheory::credits: The program Alexander[K, r] to compute Alexander ideals was written by Jana Archibald at the University of Toronto in the summer of 2005.

Out[6]= $\{1\}$

In[7]:= {KnotDet[K], KnotSignature[K]}

Out[7]= { 3, 2 }

In[8]:= Jones[K][q]

KnotTheory::loading: Loading precomputed data in Jones4Knots`.

Out[8]= $-q^{4}+q^{3}+q$

In[9]:= HOMFLYPT[K][a, z]

KnotTheory::credits: The HOMFLYPT program was written by Scott Morrison.

Out[9]= $z^{2}a^{-2}+2a^{-2}-a^{-4}$

In[10]:= Kauffman[K][a, z]

KnotTheory::loading: Loading precomputed data in Kauffman4Knots`.

Out[10]= $z^{2}a^{-2}+z^{2}a^{-4}+za^{-3}+za^{-5}-2a^{-2}-a^{-4}$

Vassiliev invariants

V₂ and V₃:

(1, 1)

V_2,1 through V_6,9:

V_2,1

V_3,1

V_4,1

V_4,2

V_4,3

V_5,1

V_5,2

V_5,3

V_5,4

V_6,1

V_6,2

V_6,3

V_6,4

V_6,5

V_6,6

V_6,7

V_6,8

V_6,9

V_2,1 through V_6,9 were provided by Petr Dunin-Barkowski <barkovs@itep.ru>, Andrey Smirnov <asmirnov@itep.ru>, and Alexei Sleptsov <sleptsov@itep.ru> and uploaded on October 2010 by User:Drorbn. Note that they are normalized differently than V₂ and V₃.

Khovanov Homology

The coefficients of the monomials

t^{r}q^{j}

are shown, along with their alternating sums

\chi

(fixed

j

, alternation over

r

). The squares with yellow highlighting are those on the "critical diagonals", where

j-2r=s+1

or

j-2r=s-1

, where

s=

2 is the signature of T(3,2). Nonzero entries off the critical diagonals (if any exist) are highlighted in red.

\		r
	\
j		\

0

1

2

3

χ

9

1

-1

7

0

5

1

3

1

Integral Khovanov Homology

(db, data source)

$\dim {\mathcal {G}}_{2r+i}\operatorname {KH} _{\mathbb {Z} }^{r}$	$i=1$	$i=3$
$r=0$	${\mathbb {Z} }$	${\mathbb {Z} }$
$r=1$
$r=2$	${\mathbb {Z} }$
$r=3$	${\mathbb {Z} }_{2}$	${\mathbb {Z} }$

Computer Talk

Much of the above data can be recomputed by Mathematica using the package KnotTheory`. See A Sample KnotTheory` Session.

${\textrm {Include}}({\textrm {ColouredJonesM.mhtml}})$

In[1]:=	<< KnotTheory`
Loading KnotTheory` (version of August 17, 2005, 14:44:34)...
In[2]:=	Crossings[TorusKnot[3, 2]]
Out[2]=	3
In[3]:=	PD[TorusKnot[3, 2]]
Out[3]=	PD[X[3, 1, 4, 6], X[1, 5, 2, 4], X[5, 3, 6, 2]]
In[4]:=	GaussCode[TorusKnot[3, 2]]
Out[4]=	GaussCode[-2, 3, -1, 2, -3, 1]
In[5]:=	BR[TorusKnot[3, 2]]
Out[5]=	BR[2, {1, 1, 1}]
In[6]:=	alex = Alexander[TorusKnot[3, 2]][t]
Out[6]=	1 -1 + ----------- + Alternating Alternating
In[7]:=	Conway[TorusKnot[3, 2]][z]
Out[7]=	2 1 + z
In[8]:=	Select[AllKnots[], (alex === Alexander[#][t])&]
Out[8]=	{Knot[3, 1]}
In[9]:=	{KnotDet[TorusKnot[3, 2]], KnotSignature[TorusKnot[3, 2]]}
Out[9]=	{3, 2}
In[10]:=	J=Jones[TorusKnot[3, 2]][q]
Out[10]=	3 4 q + q - q
In[11]:=	Select[AllKnots[], (J === Jones[#][q] \|\| (J /. q-> 1/q) === Jones[#][q])&]
Out[11]=	{Knot[3, 1]}
In[12]:=	A2Invariant[TorusKnot[3, 2]][q]
Out[12]=	2 4 6 8 12 14 q + q + 2 q + q - q - q
In[13]:=	Kauffman[TorusKnot[3, 2]][a, z]
Out[13]=	2 2 -4 2 z z z z -a - -- + -- + -- + -- + -- 2 5 3 4 2 a a a a a
In[14]:=	{Vassiliev[2][TorusKnot[3, 2]], Vassiliev[3][TorusKnot[3, 2]]}
Out[14]=	{0, 1}
In[15]:=	Kh[TorusKnot[3, 2]][q, t]
Out[15]=	3 2 5 3 9 q + q + Alternating q + Alternating q

T(3,2)

Contents

Knot presentations

Polynomial invariants

Vassiliev invariants

Khovanov Homology

Computer Talk

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