11a

(K11a

)

A knot diagram

Linearized knot diagam

6 1 11 9 2 3 10 4 8 7 5

Solving Sequence

4,8

9 5 10 7 11 1 3 2 6

, c

Ideals for irreducible components

of X

par

= hu

− u

+ ··· − u + 1i

* 1 irreducible components of dim

= 0, with total 46 representations.

The image of knot diagram is generated by the software “Draw programme” developed by An-

drew Bartholomew(http://www.layer8.co.uk/maths/draw/index.htm#Running-draw), where we modi-

ﬁed some parts for our purpose(https://github.com/CATsTAILs/LinksPainter).

All coeﬃcients of polynomials are rational numbers. But the coeﬃcients are sometimes approximated

in decimal forms when there is not enough margin.

I. I

= hu

− u

+ · · · − u + 1i

(i) Arc colorings











−u





−u

+ u





−u

+ 1

−u





− u

+ 1





−u

+ u

− 2u

+ 1

−u

− u





− u

+ 2u

− u

+ 1

−u

+ 2u

− 4u

+ 4u

− 3u





− 2u

+ 5u

− 6u

+ 6u

− 4u

+ u

− u

+ 3u

− 2u

+ 2u

− u

+ u





− 4u

+ ··· − 7u

+ 2u

−u

+ 5u

+ ··· − u

+ u





−u

+ 3u

+ ··· − 2u

+ 1

−u

+ 2u

+ ··· + 4u

− u





−u

+ 3u

+ ··· − 2u

+ 1

−u

+ 2u

+ ··· + 4u

− u



(ii) Obstruction class = −1

(iii) Cusp Shapes = −4u

+ 4u

+ ··· − 4u + 2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

− u

+ ··· − 3u + 1

+ 25u

+ ··· − u + 1

− 7u

+ ··· + 25u + 101

, c

+ u

+ ··· + u + 1

, c

+ u

+ ··· + 11u + 2

, c

− 11u

+ ··· − u + 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

+ 25y

+ ··· − y + 1

− 7y

+ ··· − 17y + 1

− 19y

+ ··· + 139967y + 10201

, c

− 11y

+ ··· − y + 1

, c

− 39y

+ ··· + 239y + 4

, c

+ 49y

+ ··· − 9y + 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.926616 + 0.410566I

−0.61712 + 4.64033I 3.90866 − 6.37467I

u = 0.926616 − 0.410566I

−0.61712 − 4.64033I 3.90866 + 6.37467I

u = −0.914147 + 0.454246I

−4.39692 − 0.74190I −1.01050 + 2.76153I

u = −0.914147 − 0.454246I

−4.39692 + 0.74190I −1.01050 − 2.76153I

u = 0.911781 + 0.304147I

2.15395 + 4.51135I 7.09548 − 8.74151I

u = 0.911781 − 0.304147I

2.15395 − 4.51135I 7.09548 + 8.74151I

u = −0.954952 + 0.418436I

−3.69312 − 9.28862I 0.73867 + 9.25644I

u = −0.954952 − 0.418436I

−3.69312 + 9.28862I 0.73867 − 9.25644I

u = 0.930509 + 0.048833I

−1.66163 − 4.02262I 4.31758 + 3.30145I

u = 0.930509 − 0.048833I

−1.66163 + 4.02262I 4.31758 − 3.30145I

u = −0.890449 + 0.239219I

2.52825 − 0.40745I 9.12909 + 0.87770I

u = −0.890449 − 0.239219I

2.52825 + 0.40745I 9.12909 − 0.87770I

u = −0.814350 + 0.077554I

1.220450 − 0.051921I 8.69452 + 0.37904I

u = −0.814350 − 0.077554I

1.220450 + 0.051921I 8.69452 − 0.37904I

u = −0.845736 + 0.830186I

−4.84996 + 2.01035I 0. − 3.31970I

u = −0.845736 − 0.830186I

−4.84996 − 2.01035I 0. + 3.31970I

u = 0.871966 + 0.808985I

−3.65550 + 2.31659I 2.70777 − 2.80879I

u = 0.871966 − 0.808985I

−3.65550 − 2.31659I 2.70777 + 2.80879I

u = 0.918456 + 0.798302I

−3.51223 + 3.71082I 3.02524 − 2.42011I

u = 0.918456 − 0.798302I

−3.51223 − 3.71082I 3.02524 + 2.42011I

u = −0.851134 + 0.882685I

−8.86024 + 1.86315I −6 − 1.106545 + 0.10I

u = −0.851134 − 0.882685I

−8.86024 − 1.86315I −6 − 1.106545 + 0.10I

u = 0.845372 + 0.890503I

−12.13790 − 6.72244I −4.11786 + 3.49282I

u = 0.845372 − 0.890503I

−12.13790 + 6.72244I −4.11786 − 3.49282I

u = 0.862272 + 0.887980I

−12.90310 + 2.35522I −5.23797 − 2.80998I

u = 0.862272 − 0.887980I

−12.90310 − 2.35522I −5.23797 + 2.80998I

u = −0.943172 + 0.803061I

−4.55090 − 8.11388I 0. + 8.45293I

u = −0.943172 − 0.803061I

−4.55090 + 8.11388I 0. − 8.45293I

u = 0.640742 + 0.410350I

−1.44816 + 1.63407I −3.46961 − 5.26360I

u = 0.640742 − 0.410350I

−1.44816 − 1.63407I −3.46961 + 5.26360I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.907049 + 0.844230I

−8.35989 − 3.13875I −5.65909 + 2.64059I

u = −0.907049 − 0.844230I

−8.35989 + 3.13875I −5.65909 − 2.64059I

u = −0.391409 + 0.635070I

−6.04130 − 3.27213I −5.13047 + 3.47488I

u = −0.391409 − 0.635070I

−6.04130 + 3.27213I −5.13047 − 3.47488I

u = −0.966860 + 0.834394I

−8.49402 − 8.22551I 0. + 5.24210I

u = −0.966860 − 0.834394I

−8.49402 + 8.22551I 0. − 5.24210I

u = 0.963540 + 0.844204I

−12.58150 + 4.05580I −4.67518 + 0.I

u = 0.963540 − 0.844204I

−12.58150 − 4.05580I −4.67518 + 0.I

u = −0.313493 + 0.645402I

−5.71816 + 5.39161I −4.52962 − 3.70458I

u = −0.313493 − 0.645402I

−5.71816 − 5.39161I −4.52962 + 3.70458I

u = 0.974549 + 0.835372I

−11.7284 + 13.1112I 0. − 8.32350I

u = 0.974549 − 0.835372I

−11.7284 − 13.1112I 0. + 8.32350I

u = 0.339399 + 0.599164I

−2.45150 − 0.89325I −1.50590 + 0.29908I

u = 0.339399 − 0.599164I

−2.45150 + 0.89325I −1.50590 − 0.29908I

u = 0.107548 + 0.462569I

−0.09670 − 1.71368I −0.09766 + 4.16841I

u = 0.107548 − 0.462569I

−0.09670 + 1.71368I −0.09766 − 4.16841I

II. u-Polynomials

Crossings u-Polynomials at each crossing

, c

− u

+ ··· − 3u + 1

+ 25u

+ ··· − u + 1

− 7u

+ ··· + 25u + 101

, c

+ u

+ ··· + u + 1

, c

+ u

+ ··· + 11u + 2

, c

− 11u

+ ··· − u + 1

III. Riley Polynomials

Crossings Riley Polynomials at each crossing

, c

+ 25y

+ ··· − y + 1

− 7y

+ ··· − 17y + 1

− 19y

+ ··· + 139967y + 10201

, c

− 11y

+ ··· − y + 1

, c

− 39y

+ ··· + 239y + 4

, c

+ 49y

+ ··· − 9y + 1