12n

0104

(K12n

0104

)

A knot diagram

Linearized knot diagam

3 5 6 2 10 3 11 12 6 1 8 9

Solving Sequence

5,10 3,6

7 2 1 11 4 9 12 8

, c

Ideals for irreducible components

of X

par

= h−3.59372 × 10

− 5.66142 × 10

+ ··· + 7.73697 × 10

b − 8.41893 × 10

1.32363 × 10

+ 2.48624 × 10

+ ··· + 7.73697 × 10

a + 6.53537 × 10

, u

+ 2u

+ ··· + u + 1i

= hb + 1, u

− 2u

+ 4u

− 5u

+ a + 4u − 3, u

− u

+ 3u

− 2u

+ 2u

− u − 1i

* 2 irreducible components of dim

= 0, with total 48 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.

= h−3.59×10

−5.66×10

+· · ·+7.74×10

b−8.42×10

, 1.32×

+2.49×10

+· · ·+7.74×10

a+6.54×10

, u

+2u

+· · ·+u+1i

(i) Arc colorings











−1.71079u

− 3.21345u

+ ··· + 10.5415u − 0.0844693

0.464486u

+ 0.731736u

+ ··· − 1.23542u + 0.0108814





−u





1.20935u

+ 1.90913u

+ ··· − 3.32862u + 1.65557

−0.182245u

− 0.291497u

+ ··· + 0.535851u − 0.403264





−1.24630u

− 2.48172u

+ ··· + 9.30604u − 0.0735879

0.464486u

+ 0.731736u

+ ··· − 1.23542u + 0.0108814





1.24139u

+ 1.95441u

+ ··· − 3.49255u + 1.76187

−0.0320409u

− 0.0452803u

+ ··· + 0.163934u − 0.106300





0.722940u

+ 1.09186u

+ ··· − 1.22903u + 1.55759

−0.0729864u

− 0.0536384u

+ ··· + 1.18829u − 0.138312





−1.79877u

− 3.35612u

+ ··· + 10.8087u − 0.281705

0.474629u

+ 0.743231u

+ ··· − 1.29010u + 0.0441881





−u

+ u





0.986423u

+ 1.55821u

+ ··· − 2.67406u + 1.14887

0.258550u

+ 0.408387u

+ ··· − 0.795796u + 0.620421





−0.549074u

− 0.889586u

+ ··· + 0.0457032u − 1.27204

−0.183879u

− 0.191517u

+ ··· + 1.29243u − 0.478058



(ii) Obstruction class = −1

(iii) Cusp Shapes = −7.55767u

− 15.9158u

+ ··· + 73.6479u + 19.0106

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

+ 13u

+ ··· + 804u + 1

, c

− 7u

+ ··· − 32u + 1

, c

+ 5u

+ ··· − 256u + 64

, c

− 2u

+ ··· − u + 1

, c

− 2u

+ ··· + u + 1

+ 14u

+ ··· + 5149u + 1583

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

+ 39y

+ ··· − 608644y + 1

, c

− 13y

+ ··· − 804y + 1

, c

− 39y

+ ··· − 253952y + 4096

, c

+ 10y

+ ··· − 7y + 1

, c

− 50y

+ ··· − 7y + 1

− 26y

+ ··· − 65134235y + 2505889

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.01452

a = 0.159707

b = 0.426201

7.18041 14.5060

u = 0.501113 + 0.767004I

a = 0.191771 − 1.283310I

b = −0.669285 + 1.060730I

7.44472 + 4.92121I 8.52470 − 6.69865I

u = 0.501113 − 0.767004I

a = 0.191771 + 1.283310I

b = −0.669285 − 1.060730I

7.44472 − 4.92121I 8.52470 + 6.69865I

u = −0.453853 + 0.695369I

a = 0.247010 + 1.284860I

b = −0.719295 − 0.792687I

−0.28964 − 3.57536I 6.37219 + 9.69003I

u = −0.453853 − 0.695369I

a = 0.247010 − 1.284860I

b = −0.719295 + 0.792687I

−0.28964 + 3.57536I 6.37219 − 9.69003I

u = −0.161979 + 0.776395I

a = 0.051090 + 0.752460I

b = −1.48780 − 0.42283I

4.30541 − 1.84849I 3.64107 + 3.02333I

u = −0.161979 − 0.776395I

a = 0.051090 − 0.752460I

b = −1.48780 + 0.42283I

4.30541 + 1.84849I 3.64107 − 3.02333I

u = 0.912511 + 0.794551I

a = −0.419329 − 0.751716I

b = 0.631065 + 1.077450I

6.12642 + 3.75190I 10.63580 − 4.55895I

u = 0.912511 − 0.794551I

a = −0.419329 + 0.751716I

b = 0.631065 − 1.077450I

6.12642 − 3.75190I 10.63580 + 4.55895I

u = −0.891381 + 0.841839I

a = −0.506949 + 0.850686I

b = 0.658034 − 1.240570I

14.7689 − 5.7297I 11.79655 + 3.54668I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.891381 − 0.841839I

a = −0.506949 − 0.850686I

b = 0.658034 + 1.240570I

14.7689 + 5.7297I 11.79655 − 3.54668I

u = −0.985080 + 0.753794I

a = −0.386102 + 0.573806I

b = 0.715924 − 0.874389I

3.30789 − 0.29459I 6.00000 + 0.I

u = −0.985080 − 0.753794I

a = −0.386102 − 0.573806I

b = 0.715924 + 0.874389I

3.30789 + 0.29459I 6.00000 + 0.I

u = −0.803175 + 1.000510I

a = 0.83087 − 1.30330I

b = 0.831506 + 0.932621I

14.2431 − 0.5975I 11.31138 + 0.I

u = −0.803175 − 1.000510I

a = 0.83087 + 1.30330I

b = 0.831506 − 0.932621I

14.2431 + 0.5975I 11.31138 + 0.I

u = 0.538055 + 0.454086I

a = 2.48988 − 0.58955I

b = −0.551064 − 0.378134I

8.24921 − 1.23307I 10.61321 − 2.35997I

u = 0.538055 − 0.454086I

a = 2.48988 + 0.58955I

b = −0.551064 + 0.378134I

8.24921 + 1.23307I 10.61321 + 2.35997I

u = 0.347293 + 0.590519I

a = 0.19395 − 1.58608I

b = −0.859706 + 0.416440I

−1.72808 + 1.17860I −0.84051 − 1.97476I

u = 0.347293 − 0.590519I

a = 0.19395 + 1.58608I

b = −0.859706 − 0.416440I

−1.72808 − 1.17860I −0.84051 + 1.97476I

u = 1.043690 + 0.800779I

a = −0.495482 − 0.469030I

b = 0.892411 + 0.841271I

5.39547 − 3.53826I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.043690 − 0.800779I

a = −0.495482 + 0.469030I

b = 0.892411 − 0.841271I

5.39547 + 3.53826I 0

u = 0.087517 + 0.669029I

a = −0.577668 − 0.564351I

b = −1.323170 + 0.163226I

−2.60028 + 1.10335I 0.72944 − 5.14975I

u = 0.087517 − 0.669029I

a = −0.577668 + 0.564351I

b = −1.323170 − 0.163226I

−2.60028 − 1.10335I 0.72944 + 5.14975I

u = 0.807134 + 1.059990I

a = 0.655895 + 1.196400I

b = 0.925887 − 0.815812I

5.27984 + 2.65601I 0

u = 0.807134 − 1.059990I

a = 0.655895 − 1.196400I

b = 0.925887 + 0.815812I

5.27984 − 2.65601I 0

u = −0.118669 + 1.352730I

a = 0.692604 − 0.095605I

b = 0.673600 + 0.068678I

−3.90139 − 2.12133I 0

u = −0.118669 − 1.352730I

a = 0.692604 + 0.095605I

b = 0.673600 − 0.068678I

−3.90139 + 2.12133I 0

u = −1.061870 + 0.848054I

a = −0.596141 + 0.421898I

b = 1.020730 − 0.858173I

13.6503 + 6.0084I 0

u = −1.061870 − 0.848054I

a = −0.596141 − 0.421898I

b = 1.020730 + 0.858173I

13.6503 − 6.0084I 0

u = −0.453110 + 0.434147I

a = 1.81325 + 1.42213I

b = −0.588284 + 0.063513I

0.308257 + 0.438585I 7.79318 − 0.39703I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.453110 − 0.434147I

a = 1.81325 − 1.42213I

b = −0.588284 − 0.063513I

0.308257 − 0.438585I 7.79318 + 0.39703I

u = −0.851980 + 1.097830I

a = 0.462368 − 1.207420I

b = 1.062440 + 0.773956I

2.23629 − 6.46162I 0

u = −0.851980 − 1.097830I

a = 0.462368 + 1.207420I

b = 1.062440 − 0.773956I

2.23629 + 6.46162I 0

u = 0.890810 + 1.092080I

a = 0.358382 + 1.303470I

b = 1.16024 − 0.81354I

4.46235 + 10.57810I 0

u = 0.890810 − 1.092080I

a = 0.358382 − 1.303470I

b = 1.16024 + 0.81354I

4.46235 − 10.57810I 0

u = 0.369530 + 1.364470I

a = 0.633928 + 0.303473I

b = 0.736491 − 0.206857I

2.62006 + 5.04142I 0

u = 0.369530 − 1.364470I

a = 0.633928 − 0.303473I

b = 0.736491 + 0.206857I

2.62006 − 5.04142I 0

u = −0.91555 + 1.08098I

a = 0.29416 − 1.39483I

b = 1.22988 + 0.86093I

12.8768 − 13.1889I 0

u = −0.91555 − 1.08098I

a = 0.29416 + 1.39483I

b = 1.22988 − 0.86093I

12.8768 + 13.1889I 0

u = −0.500346

a = 6.58730

b = −1.11870

6.69758 29.8650

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.442850

a = 0.781638

b = 0.0358028

0.706374 14.0900

u = 0.326673

a = 11.6043

b = −1.02253

−0.833901 102.450

II.

= hb+1, u

−2u

+4u

−5u

+a+4u −3, u

−u

+3u

−2u

+2u

−u−1i

(i) Arc colorings











−u

+ 2u

− 4u

+ 5u

− 4u + 3

−1





−u





−u





−u

+ 2u

− 4u

+ 5u

− 4u + 2

−1





−1









−u

+ 2u

− 4u

+ 5u

− 4u + 3

−1





−u

+ u





+ u

− 1

−u

+ u

− 2u

+ u

− u − 1





−u

− u

+ 1

−u

− 2u



(ii) Obstruction class = 1

(iii) Cusp Shapes = 7u

− 7u

+ 21u

− 17u

+ 20u − 12

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

(u − 1)

, c

(u + 1)

, c

− u

+ 3u

− 2u

+ 2u

− u − 1

, c

+ u

− 3u

− 2u

+ 2u

− u − 1

+ u

+ 3u

+ 2u

+ u − 1

, c

− u

− 3u

+ 2u

+ u − 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

(y −1)

, c

+ 5y

+ 9y

+ 4y

− 6y

− 5y + 1

, c

− 7y

+ 17y

− 16y

+ 6y

− 5y + 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.873214

a = 1.31147

b = −1.00000

6.01515 5.96810

u = −0.138835 + 1.234450I

a = −0.631845 + 0.143944I

b = −1.00000

−4.60518 − 1.97241I −1.94905 + 2.83524I

u = −0.138835 − 1.234450I

a = −0.631845 − 0.143944I

b = −1.00000

−4.60518 + 1.97241I −1.94905 − 2.83524I

u = 0.408802 + 1.276380I

a = −0.453123 − 0.323434I

b = −1.00000

2.05064 + 4.59213I 3.43197 − 0.44648I

u = 0.408802 − 1.276380I

a = −0.453123 + 0.323434I

b = −1.00000

2.05064 − 4.59213I 3.43197 + 0.44648I

u = −0.413150

a = 5.85846

b = −1.00000

−0.906083 −24.9340

III. u-Polynomials

Crossings u-Polynomials at each crossing

((u − 1)

)(u

+ 13u

+ ··· + 804u + 1)

((u − 1)

)(u

− 7u

+ ··· − 32u + 1)

, c

+ 5u

+ ··· − 256u + 64)

((u + 1)

)(u

− 7u

+ ··· − 32u + 1)

− u

+ 3u

− 2u

+ 2u

− u − 1)(u

− 2u

+ ··· − u + 1)

, c

+ u

− 3u

− 2u

+ 2u

− u − 1)(u

− 2u

+ ··· + u + 1)

+ u

+ 3u

+ 2u

+ u − 1)(u

− 2u

+ ··· − u + 1)

− u

+ 3u

− 2u

+ 2u

− u − 1)(u

+ 14u

+ ··· + 5149u + 1583)

, c

− u

− 3u

+ 2u

+ u − 1)(u

− 2u

+ ··· + u + 1)

IV. Riley Polynomials

Crossings Riley Polynomials at each crossing

((y −1)

)(y

+ 39y

+ ··· − 608644y + 1)

, c

((y −1)

)(y

− 13y

+ ··· − 804y + 1)

, c

− 39y

+ ··· − 253952y + 4096)

, c

+ 5y

+ ··· − 5y + 1)(y

+ 10y

+ ··· − 7y + 1)

, c

− 7y

+ ··· − 5y + 1)(y

− 50y

+ ··· − 7y + 1)

+ 5y

+ 9y

+ 4y

− 6y

− 5y + 1)

· (y

− 26y

+ ··· − 65134235y + 2505889)