11a

185

(K11a

185

)

A knot diagram

Linearized knot diagam

7 1 11 10 9 2 3 4 5 8 6

Solving Sequence

2,6

7 1 3 8 11 4 9 5 10

, c

Ideals for irreducible components

of X

par

= hu

+ u

+ ··· + u + 1i

* 1 irreducible components of dim

= 0, with total 54 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

+ u





−u

− u

+ 1

+ 2u





+ u





−u

− 2u

− u

−u

− 3u

− 4u

− u

+ u





+ 7u

+ ··· − 2u

+ 1

+ 8u

+ ··· + 4u

− u





−u

− 12u

+ ··· − 20u

− 8u

+ 13u

+ ··· − 2u

+ u





−u

− 4u

− 7u

− 4u

+ 3u

+ 6u

+ 2u

− u

+ 5u

+ 12u

+ 15u

+ 9u

− u

− 4u

− 2u

+ u





−u

− 4u

− 7u

− 4u

+ 3u

+ 6u

+ 2u

− u

+ 5u

+ 12u

+ 15u

+ 9u

− u

− 4u

− 2u

+ 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

+ ··· + u + 1

+ 29u

+ ··· − u + 1

− 7u

+ ··· − 47u + 5

, c

− u

+ ··· − u + 1

, c

− u

+ ··· + u + 1

+ u

+ ··· + 11u + 1

+ 11u

+ ··· + 1951u + 187

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

+ 29y

+ ··· − y + 1

− 7y

+ ··· − 5y + 1

− 3y

+ ··· + 631y + 25

, c

+ 49y

+ ··· − y + 1

, c

− 43y

+ ··· − 97y + 1

+ 5y

+ ··· − 49y + 1

+ 21y

+ ··· + 184179y + 34969

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.526458 + 0.850149I

1.84506 − 5.20730I 6.07211 + 8.44255I

u = −0.526458 − 0.850149I

1.84506 + 5.20730I 6.07211 − 8.44255I

u = 0.063963 + 0.969473I

−2.01199 + 1.57241I −2.93647 − 4.70910I

u = 0.063963 − 0.969473I

−2.01199 − 1.57241I −2.93647 + 4.70910I

u = 0.542026 + 0.876210I

−3.38874 + 8.60756I 0.88746 − 8.62489I

u = 0.542026 − 0.876210I

−3.38874 − 8.60756I 0.88746 + 8.62489I

u = −0.068795 + 1.043570I

−7.55344 − 4.33327I −6.71453 + 3.78697I

u = −0.068795 − 1.043570I

−7.55344 + 4.33327I −6.71453 − 3.78697I

u = −0.404606 + 0.965250I

−5.19453 − 0.85164I −2.69916 + 2.79194I

u = −0.404606 − 0.965250I

−5.19453 + 0.85164I −2.69916 − 2.79194I

u = 0.459955 + 0.798537I

0.23556 + 1.92632I 2.54464 − 3.58852I

u = 0.459955 − 0.798537I

0.23556 − 1.92632I 2.54464 + 3.58852I

u = 0.514528 + 0.758613I

0.15792 + 2.10554I 4.75076 − 4.16265I

u = 0.514528 − 0.758613I

0.15792 − 2.10554I 4.75076 + 4.16265I

u = −0.521169 + 0.661679I

2.37968 + 0.93113I 8.32580 − 1.37232I

u = −0.521169 − 0.661679I

2.37968 − 0.93113I 8.32580 + 1.37232I

u = 0.555404 + 0.618983I

−2.66786 − 4.19841I 2.85328 + 2.26313I

u = 0.555404 − 0.618983I

−2.66786 + 4.19841I 2.85328 − 2.26313I

u = −0.812471 + 0.137850I

−6.92259 + 9.00910I −0.82614 − 5.72677I

u = −0.812471 − 0.137850I

−6.92259 − 9.00910I −0.82614 + 5.72677I

u = −0.409939 + 1.110810I

−5.37080 − 0.77260I 0

u = −0.409939 − 1.110810I

−5.37080 + 0.77260I 0

u = 0.803336 + 0.074667I

−8.69949 + 0.21899I −3.12382 − 0.07866I

u = 0.803336 − 0.074667I

−8.69949 − 0.21899I −3.12382 + 0.07866I

u = 0.793006 + 0.135744I

−1.35714 − 5.52569I 3.45218 + 5.82582I

u = 0.793006 − 0.135744I

−1.35714 + 5.52569I 3.45218 − 5.82582I

u = 0.465718 + 1.132140I

−1.40488 + 3.87836I 0

u = 0.465718 − 1.132140I

−1.40488 − 3.87836I 0

u = −0.768273 + 0.105402I

−2.42732 + 1.73641I 0.699777 + 0.008860I

u = −0.768273 − 0.105402I

−2.42732 − 1.73641I 0.699777 − 0.008860I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.492150 + 1.152340I

−4.72150 − 7.14315I 0

u = −0.492150 − 1.152340I

−4.72150 + 7.14315I 0

u = −0.403427 + 1.196670I

−6.22025 − 2.29095I 0

u = −0.403427 − 1.196670I

−6.22025 + 2.29095I 0

u = 0.382721 + 1.204180I

−5.34368 − 1.56137I 0

u = 0.382721 − 1.204180I

−5.34368 + 1.56137I 0

u = −0.378306 + 1.216650I

−11.00630 + 4.98743I 0

u = −0.378306 − 1.216650I

−11.00630 − 4.98743I 0

u = 0.415619 + 1.215680I

−12.53210 + 4.46314I 0

u = 0.415619 − 1.215680I

−12.53210 − 4.46314I 0

u = −0.494467 + 1.187320I

−5.57287 − 6.38943I 0

u = −0.494467 − 1.187320I

−5.57287 + 6.38943I 0

u = −0.688011 + 0.172752I

−1.90661 + 2.65629I 2.99397 − 3.57576I

u = −0.688011 − 0.172752I

−1.90661 − 2.65629I 2.99397 + 3.57576I

u = 0.508429 + 1.190650I

−4.45647 + 10.31740I 0

u = 0.508429 − 1.190650I

−4.45647 − 10.31740I 0

u = 0.486868 + 1.204310I

−12.02490 + 4.47153I 0

u = 0.486868 − 1.204310I

−12.02490 − 4.47153I 0

u = −0.513281 + 1.197090I

−10.0524 − 13.8722I 0

u = −0.513281 − 1.197090I

−10.0524 + 13.8722I 0

u = −0.553091 + 0.375407I

−3.44062 − 3.02821I 2.33743 + 2.90410I

u = −0.553091 − 0.375407I

−3.44062 + 3.02821I 2.33743 − 2.90410I

u = 0.542871 + 0.222612I

1.223040 + 0.207996I 8.65252 − 1.10768I

u = 0.542871 − 0.222612I

1.223040 − 0.207996I 8.65252 + 1.10768I

II. u-Polynomials

Crossings u-Polynomials at each crossing

, c

+ u

+ ··· + u + 1

+ 29u

+ ··· − u + 1

− 7u

+ ··· − 47u + 5

, c

− u

+ ··· − u + 1

, c

− u

+ ··· + u + 1

+ u

+ ··· + 11u + 1

+ 11u

+ ··· + 1951u + 187

III. Riley Polynomials

Crossings Riley Polynomials at each crossing

, c

+ 29y

+ ··· − y + 1

− 7y

+ ··· − 5y + 1

− 3y

+ ··· + 631y + 25

, c

+ 49y

+ ··· − y + 1

, c

− 43y

+ ··· − 97y + 1

+ 5y

+ ··· − 49y + 1

+ 21y

+ ··· + 184179y + 34969