K11a30

(Knotscape image)	See the full Hoste-Thistlethwaite Table of 11 Crossing Knots. Visit K11a30 at Knotilus!
	[edit K11a30 Quick Notes]

[edit K11a30 Further Notes and Views]

Knot presentations

Planar diagram presentation	X₄₂₅₁ X₈₃₉₄ X_12,6,13,5 X_18,8,19,7 X_2,9,3,10 X_16,12,17,11 X_20,13,21,14 X_6,16,7,15 X_10,18,11,17 X_22,19,1,20 X_14,21,15,22
Gauss code	1, -5, 2, -1, 3, -8, 4, -2, 5, -9, 6, -3, 7, -11, 8, -6, 9, -4, 10, -7, 11, -10
Dowker-Thistlethwaite code	4 8 12 18 2 16 20 6 10 22 14

A Braid Representative

A Morse Link Presentation

Three dimensional invariants

Symmetry type	Chiral
Unknotting number	$\{1,2\}$
3-genus	3
Bridge index	3
Super bridge index	Missing
Nakanishi index	Missing
Maximal Thurston-Bennequin number	Data:K11a30/ThurstonBennequinNumber
Hyperbolic Volume	17.3478
A-Polynomial	See Data:K11a30/A-polynomial

[edit Notes for K11a30's three dimensional invariants]

Four dimensional invariants

Smooth 4 genus	Missing
Topological 4 genus	Missing
Concordance genus	$3$
Rasmussen s-Invariant	0

[edit Notes for K11a30's four dimensional invariants]

Polynomial invariants

Alexander polynomial	$-2t^{3}+13t^{2}-35t+49-35t^{-1}+13t^{-2}-2t^{-3}$
Conway polynomial	$-2z^{6}+z^{4}-z^{2}+1$
2nd Alexander ideal (db, data sources)	$\{1\}$
Determinant and Signature	{ 149, 0 }
Jones polynomial	$q^{6}-4q^{5}+9q^{4}-15q^{3}+21q^{2}-24q+24-21q^{-1}+16q^{-2}-9q^{-3}+4q^{-4}-q^{-5}$
HOMFLY-PT polynomial (db, data sources)	$-z^{6}a^{-2}-z^{6}+2a^{2}z^{4}-2z^{4}a^{-2}+z^{4}a^{-4}-a^{4}z^{2}+a^{2}z^{2}-4z^{2}a^{-2}+z^{2}a^{-4}+2z^{2}-2a^{-2}+a^{-4}+2$
Kauffman polynomial (db, data sources)	$2z^{10}a^{-2}+2z^{10}+7az^{9}+13z^{9}a^{-1}+6z^{9}a^{-3}+10a^{2}z^{8}+15z^{8}a^{-2}+7z^{8}a^{-4}+18z^{8}+8a^{3}z^{7}+az^{7}-15z^{7}a^{-1}-4z^{7}a^{-3}+4z^{7}a^{-5}+4a^{4}z^{6}-13a^{2}z^{6}-42z^{6}a^{-2}-15z^{6}a^{-4}+z^{6}a^{-6}-43z^{6}+a^{5}z^{5}-11a^{3}z^{5}-17az^{5}-8z^{5}a^{-1}-12z^{5}a^{-3}-9z^{5}a^{-5}-5a^{4}z^{4}+6a^{2}z^{4}+34z^{4}a^{-2}+10z^{4}a^{-4}-2z^{4}a^{-6}+33z^{4}-a^{5}z^{3}+6a^{3}z^{3}+13az^{3}+11z^{3}a^{-1}+11z^{3}a^{-3}+6z^{3}a^{-5}+2a^{4}z^{2}-a^{2}z^{2}-13z^{2}a^{-2}-3z^{2}a^{-4}+z^{2}a^{-6}-12z^{2}-a^{3}z-3az-3za^{-1}-2za^{-3}-za^{-5}+2a^{-2}+a^{-4}+2$
The A2 invariant	Data:K11a30/QuantumInvariant/A2/1,0
The G2 invariant	Data:K11a30/QuantumInvariant/G2/1,0

Further Quantum Invariants

K11a30 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["K11a30"];

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

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

Out[4]= $-2t^{3}+13t^{2}-35t+49-35t^{-1}+13t^{-2}-2t^{-3}$

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

Out[5]= $-2z^{6}+z^{4}-z^{2}+1$

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]= { 149, 0 }

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

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

Out[8]= $q^{6}-4q^{5}+9q^{4}-15q^{3}+21q^{2}-24q+24-21q^{-1}+16q^{-2}-9q^{-3}+4q^{-4}-q^{-5}$

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

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

Out[9]= $-z^{6}a^{-2}-z^{6}+2a^{2}z^{4}-2z^{4}a^{-2}+z^{4}a^{-4}-a^{4}z^{2}+a^{2}z^{2}-4z^{2}a^{-2}+z^{2}a^{-4}+2z^{2}-2a^{-2}+a^{-4}+2$

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

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

Out[10]= $2z^{10}a^{-2}+2z^{10}+7az^{9}+13z^{9}a^{-1}+6z^{9}a^{-3}+10a^{2}z^{8}+15z^{8}a^{-2}+7z^{8}a^{-4}+18z^{8}+8a^{3}z^{7}+az^{7}-15z^{7}a^{-1}-4z^{7}a^{-3}+4z^{7}a^{-5}+4a^{4}z^{6}-13a^{2}z^{6}-42z^{6}a^{-2}-15z^{6}a^{-4}+z^{6}a^{-6}-43z^{6}+a^{5}z^{5}-11a^{3}z^{5}-17az^{5}-8z^{5}a^{-1}-12z^{5}a^{-3}-9z^{5}a^{-5}-5a^{4}z^{4}+6a^{2}z^{4}+34z^{4}a^{-2}+10z^{4}a^{-4}-2z^{4}a^{-6}+33z^{4}-a^{5}z^{3}+6a^{3}z^{3}+13az^{3}+11z^{3}a^{-1}+11z^{3}a^{-3}+6z^{3}a^{-5}+2a^{4}z^{2}-a^{2}z^{2}-13z^{2}a^{-2}-3z^{2}a^{-4}+z^{2}a^{-6}-12z^{2}-a^{3}z-3az-3za^{-1}-2za^{-3}-za^{-5}+2a^{-2}+a^{-4}+2$

"Similar" Knots (within the Atlas)

Same Alexander/Conway Polynomial: {K11a272,}

Same Jones Polynomial (up to mirroring, $q\leftrightarrow q^{-1}$ ): {K11a189, K11a272,}

Computer Talk

The above data is available with the Mathematica package KnotTheory`. Your input (in red) is realistic; all else should have the same content as in a real mathematica session, but with different formatting.

(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 May 31, 2006, 14:15:20.091.

In[3]:= K = Knot["K11a30"];

In[4]:= {A = Alexander[K][t], J = Jones[K][q]}

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

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

Out[4]= { $-2t^{3}+13t^{2}-35t+49-35t^{-1}+13t^{-2}-2t^{-3}$ , $q^{6}-4q^{5}+9q^{4}-15q^{3}+21q^{2}-24q+24-21q^{-1}+16q^{-2}-9q^{-3}+4q^{-4}-q^{-5}$ }

In[5]:= DeleteCases[Select[AllKnots[], (A === Alexander[#][t]) &], K]

KnotTheory::loading: Loading precomputed data in DTCode4KnotsTo11`.

KnotTheory::credits: The GaussCode to PD conversion was written by Siddarth Sankaran at the University of Toronto in the summer of 2005.

Out[5]= {K11a272,}

In[6]:= DeleteCases[ Select[ AllKnots[], (J === Jones[#][q] || (J /. q -> 1/q) === Jones[#][q]) & ], K ]

KnotTheory::loading: Loading precomputed data in Jones4Knots11`.

Out[6]= {K11a189, K11a272,}

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

-4

-8

8

-{\frac {14}{3}}

-{\frac {10}{3}}

32

{\frac {208}{3}}

{\frac {160}{3}}

-8

-{\frac {32}{3}}

32

{\frac {56}{3}}

{\frac {40}{3}}

{\frac {3809}{30}}

{\frac {1462}{15}}

-{\frac {902}{45}}

{\frac {127}{18}}

-{\frac {991}{30}}

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=

0 is the signature of K11a30. Nonzero entries off the critical diagonals (if any exist) are highlighted in red.

\		r
	\
j		\

-5

-4

-3

-2

-1

0

1

2

3

4

5

6

χ

13

1

11

3

-3

9

6

1

5

7

9

3

-6

5

12

6

3

12

9

-3

1

12

0

-1

10

13

3

-3

6

11

-5

3

10

7

-7

1

6

-5

-9

3

-11

1

-1

Integral Khovanov Homology

(db, data source)

$\dim {\mathcal {G}}_{2r+i}\operatorname {KH} _{\mathbb {Z} }^{r}$	$i=-1$	$i=1$
$r=-5$	${\mathbb {Z} }$
$r=-4$	${\mathbb {Z} }^{3}\oplus {\mathbb {Z} }_{2}$	${\mathbb {Z} }$
$r=-3$	${\mathbb {Z} }^{6}\oplus {\mathbb {Z} }_{2}^{3}$	${\mathbb {Z} }^{3}$
$r=-2$	${\mathbb {Z} }^{10}\oplus {\mathbb {Z} }_{2}^{6}$	${\mathbb {Z} }^{6}$
$r=-1$	${\mathbb {Z} }^{11}\oplus {\mathbb {Z} }_{2}^{10}$	${\mathbb {Z} }^{10}$
$r=0$	${\mathbb {Z} }^{13}\oplus {\mathbb {Z} }_{2}^{11}$	${\mathbb {Z} }^{12}$
$r=1$	${\mathbb {Z} }^{12}\oplus {\mathbb {Z} }_{2}^{12}$	${\mathbb {Z} }^{12}$
$r=2$	${\mathbb {Z} }^{9}\oplus {\mathbb {Z} }_{2}^{12}$	${\mathbb {Z} }^{12}$
$r=3$	${\mathbb {Z} }^{6}\oplus {\mathbb {Z} }_{2}^{9}$	${\mathbb {Z} }^{9}$
$r=4$	${\mathbb {Z} }^{3}\oplus {\mathbb {Z} }_{2}^{6}$	${\mathbb {Z} }^{6}$
$r=5$	${\mathbb {Z} }\oplus {\mathbb {Z} }_{2}^{3}$	${\mathbb {Z} }^{3}$
$r=6$	${\mathbb {Z} }_{2}$	${\mathbb {Z} }$