12n

0076

(K12n

0076

)

A knot diagram

Linearized knot diagam

3 5 6 2 10 4 5 12 11 6 8 9

Solving Sequence

5,10

3,11

2 1 4 7 8 9 12

, c

Ideals for irreducible components

of X

par

= h−1.99559 × 10

+ 5.12786 × 10

+ ··· + 3.29400 × 10

b + 2.31961 × 10

− 6.21494 × 10

+ 1.10612 × 10

+ ··· + 3.29400 × 10

a + 8.86419 × 10

, u

− 2u

+ ··· − u + 1i

= hb + 1, 2u

− u

− 3u

+ 3u

+ 4u

− 3u

+ a − 2u + 4, u

− u

+ 2u

+ u

− 2u

+ 2u − 1i

* 2 irreducible components of dim

= 0, with total 42 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−2.00×10

+5.13×10

+· · ·+3.29×10

b+2.32×10

, −6.21×

+1.11×10

+· · ·+3.29×10

a+8.86×10

, u

−2u

+· · ·−u+1i

(i) Arc colorings















1.88675u

− 3.35800u

+ ··· − 0.414433u − 2.69102

0.605825u

− 1.55673u

+ ··· − 2.42216u − 0.0704193





−u

+ u





2.49257u

− 4.91473u

+ ··· − 2.83659u − 2.76144

0.605825u

− 1.55673u

+ ··· − 2.42216u − 0.0704193





0.684721u

− 1.85986u

+ ··· − 3.17571u + 0.213786

−0.0613225u

+ 0.190476u

+ ··· + 0.906554u − 0.351909





2.09274u

− 3.89228u

+ ··· − 1.36534u − 2.34594

0.572218u

− 1.57386u

+ ··· − 2.75044u + 0.0518727





0.684721u

− 1.85986u

+ ··· − 3.17571u + 0.213786

0.395472u

− 0.984131u

+ ··· − 2.08170u + 0.842330





0.289249u

− 0.875732u

+ ··· − 1.09401u − 0.628544

0.395472u

− 0.984131u

+ ··· − 2.08170u + 0.842330





− u

+ u





0.466506u

− 1.30241u

+ ··· − 2.66126u + 0.0407295

−0.269323u

+ 0.553369u

+ ··· + 1.71300u − 0.617147



(ii) Obstruction class = −1

(iii) Cusp Shapes

= −

7661808169491132

3293995579890413

6218879522456028

3293995579890413

+ ···+

25977556548692283

3293995579890413

u −

23126112688430199

3293995579890413

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

+ 3u

+ ··· + 71u + 1

, c

− 9u

+ ··· − 15u + 1

, c

+ 3u

+ ··· + 2176u + 256

, c

− 2u

+ ··· − u + 1

− 6u

+ ··· + 1795665u + 338425

, c

− 2u

+ ··· + 7u + 1

+ 6u

+ ··· + 11u + 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

+ 65y

+ ··· − 5331y + 1

, c

− 3y

+ ··· − 71y + 1

, c

− 51y

+ ··· − 1228800y + 65536

, c

− 6y

+ ··· − 11y + 1

+ 106y

+ ··· + 912331286925y + 114531480625

, c

− 26y

+ ··· − 11y + 1

+ 46y

+ ··· + y + 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.635489 + 0.765565I

a = 0.023523 + 0.819812I

b = 0.143823 − 0.811670I

3.05379 − 1.22135I −2.44643 + 1.78317I

u = 0.635489 − 0.765565I

a = 0.023523 − 0.819812I

b = 0.143823 + 0.811670I

3.05379 + 1.22135I −2.44643 − 1.78317I

u = −0.729595 + 0.661430I

a = 0.034703 − 1.094050I

b = −0.136834 + 1.060550I

−0.23851 + 4.87038I −8.16084 − 6.79059I

u = −0.729595 − 0.661430I

a = 0.034703 + 1.094050I

b = −0.136834 − 1.060550I

−0.23851 − 4.87038I −8.16084 + 6.79059I

u = −0.479562 + 0.911974I

a = 0.046982 − 0.468540I

b = 0.371651 + 0.493500I

−1.11923 − 1.98539I −6.62012 + 2.37959I

u = −0.479562 − 0.911974I

a = 0.046982 + 0.468540I

b = 0.371651 − 0.493500I

−1.11923 + 1.98539I −6.62012 − 2.37959I

u = −0.766682 + 0.495753I

a = 1.50878 + 0.43111I

b = 0.146629 − 0.533111I

−0.524122 − 0.409066I −7.28048 − 0.84766I

u = −0.766682 − 0.495753I

a = 1.50878 − 0.43111I

b = 0.146629 + 0.533111I

−0.524122 + 0.409066I −7.28048 + 0.84766I

u = 0.971312 + 0.567163I

a = 1.103300 − 0.703542I

b = 0.496724 + 0.591318I

1.85693 − 3.80699I −4.56903 + 5.73620I

u = 0.971312 − 0.567163I

a = 1.103300 + 0.703542I

b = 0.496724 − 0.591318I

1.85693 + 3.80699I −4.56903 − 5.73620I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.17100

a = 0.851526

b = 0.548404

−7.23479 −9.88000

u = 0.718624 + 0.314023I

a = 0.116591 + 1.245780I

b = −1.100530 − 0.643963I

−4.65847 − 3.05078I −14.9930 + 6.5224I

u = 0.718624 − 0.314023I

a = 0.116591 − 1.245780I

b = −1.100530 + 0.643963I

−4.65847 + 3.05078I −14.9930 − 6.5224I

u = −1.123410 + 0.599536I

a = 0.797874 + 0.695393I

b = 0.704883 − 0.508995I

−3.27432 + 7.58793I −9.23689 − 7.74257I

u = −1.123410 − 0.599536I

a = 0.797874 − 0.695393I

b = 0.704883 + 0.508995I

−3.27432 − 7.58793I −9.23689 + 7.74257I

u = −0.721712

a = −0.340670

b = −1.45745

−6.03886 −17.6920

u = 0.900311 + 0.952119I

a = −0.732531 + 0.736305I

b = 0.96904 − 1.25880I

9.10120 − 4.37771I −7.49633 + 3.28771I

u = 0.900311 − 0.952119I

a = −0.732531 − 0.736305I

b = 0.96904 + 1.25880I

9.10120 + 4.37771I −7.49633 − 3.28771I

u = −0.905172 + 0.980418I

a = −0.763195 − 0.646287I

b = 1.05364 + 1.18320I

12.90170 − 0.67521I −4.51148 − 0.04928I

u = −0.905172 − 0.980418I

a = −0.763195 + 0.646287I

b = 1.05364 − 1.18320I

12.90170 + 0.67521I −4.51148 + 0.04928I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.995190 + 0.896687I

a = 0.62305 − 1.64005I

b = 1.05804 + 1.11835I

8.78395 − 2.42502I −7.89113 + 1.48359I

u = 0.995190 − 0.896687I

a = 0.62305 + 1.64005I

b = 1.05804 − 1.11835I

8.78395 + 2.42502I −7.89113 − 1.48359I

u = 0.901655 + 1.007390I

a = −0.755401 + 0.558173I

b = 1.09702 − 1.08890I

8.64740 + 5.63592I −8.00000 − 2.80908I

u = 0.901655 − 1.007390I

a = −0.755401 − 0.558173I

b = 1.09702 + 1.08890I

8.64740 − 5.63592I −8.00000 + 2.80908I

u = −0.530883 + 0.364299I

a = 0.43019 − 1.79437I

b = −0.779658 + 0.298976I

−1.01260 + 1.22984I −7.99935 − 4.73307I

u = −0.530883 − 0.364299I

a = 0.43019 + 1.79437I

b = −0.779658 − 0.298976I

−1.01260 − 1.22984I −7.99935 + 4.73307I

u = −1.012560 + 0.914952I

a = 0.49655 + 1.65048I

b = 1.15087 − 1.09510I

12.5409 + 7.6268I −5.13159 − 4.40800I

u = −1.012560 − 0.914952I

a = 0.49655 − 1.65048I

b = 1.15087 + 1.09510I

12.5409 − 7.6268I −5.13159 + 4.40800I

u = −0.620369

a = 1.18712

b = 0.117070

−0.969949 −9.86690

u = 1.031790 + 0.924118I

a = 0.39495 − 1.60999I

b = 1.21367 + 1.04076I

8.2072 − 12.7003I −8.60420 + 6.93082I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.031790 − 0.924118I

a = 0.39495 + 1.60999I

b = 1.21367 − 1.04076I

8.2072 + 12.7003I −8.60420 − 6.93082I

u = 0.246676 + 0.443752I

a = 4.30323 + 2.74241I

b = −0.948262 + 0.125356I

−3.28757 + 0.51694I −12.3807 + 13.4722I

u = 0.246676 − 0.443752I

a = 4.30323 − 2.74241I

b = −0.948262 − 0.125356I

−3.28757 − 0.51694I −12.3807 − 13.4722I

u = 0.464719

a = −2.95516

b = −1.08945

−2.17611 3.01310

II. I

= hb + 1, 2u

− u

− 3u

+ 3u

+ 4u

− 3u

+ a − 2u + 4, u

− u

−

+ 2u

+ u

− 2u

+ 2u − 1i

(i) Arc colorings















−2u

+ u

+ 3u

− 3u

− 4u

+ 3u

+ 2u − 4

−1





−u

+ u





−2u

+ u

+ 3u

− 3u

− 4u

+ 3u

+ 2u − 5

−1





−1





−2u

+ u

+ 3u

− 3u

− 4u

+ 3u

+ 2u − 4

−1









−u

+ 1





− u

+ u





− 2u

+ 2u

− 2u

−u

+ u

− 2u

+ u



(ii) Obstruction class = 1

(iii) Cusp Shapes = −10u

+ 2u

+ 16u

− 12u

− 19u

+ 9u

+ 8u − 27

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

(u − 1)

, c

(u + 1)

− u

+ 2u

+ u

− 2u

+ 2u − 1

+ 3u

+ 7u

+ 10u

+ 11u

+ 10u

+ 6u

+ 4u + 1

+ u

− 3u

− 2u

+ 3u

+ 2u − 1

− 3u

+ 7u

− 10u

+ 11u

− 10u

+ 6u

− 4u + 1

+ u

− u

− 2u

+ u

+ 2u

− 2u − 1

, c

− u

− 3u

+ 2u

+ 3u

− 2u − 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

(y −1)

, c

− 3y

+ 7y

− 10y

+ 11y

− 10y

+ 6y

− 4y + 1

, c

+ 5y

+ 11y

+ 6y

− 17y

− 34y

− 22y

− 4y + 1

, c

− 7y

+ 19y

− 22y

+ 3y

+ 14y

− 6y

− 4y + 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.570868 + 0.730671I

a = 0.281371 + 1.128550I

b = −1.00000

−2.68559 + 1.13123I −9.56807 − 0.79885I

u = 0.570868 − 0.730671I

a = 0.281371 − 1.128550I

b = −1.00000

−2.68559 − 1.13123I −9.56807 + 0.79885I

u = −0.855237 + 0.665892I

a = −0.208670 − 0.825203I

b = −1.00000

0.51448 + 2.57849I −6.42531 − 3.25625I

u = −0.855237 − 0.665892I

a = −0.208670 + 0.825203I

b = −1.00000

0.51448 − 2.57849I −6.42531 + 3.25625I

u = −1.09818

a = −0.829189

b = −1.00000

−8.14766 −20.0060

u = 1.031810 + 0.655470I

a = −0.284386 + 0.605794I

b = −1.00000

−4.02461 − 6.44354I −11.71592 + 3.92092I

u = 1.031810 − 0.655470I

a = −0.284386 − 0.605794I

b = −1.00000

−4.02461 + 6.44354I −11.71592 − 3.92092I

u = 0.603304

a = −2.74744

b = −1.00000

−2.48997 −23.5750

III. u-Polynomials

Crossings u-Polynomials at each crossing

((u − 1)

)(u

+ 3u

+ ··· + 71u + 1)

((u − 1)

)(u

− 9u

+ ··· − 15u + 1)

, c

+ 3u

+ ··· + 2176u + 256)

((u + 1)

)(u

− 9u

+ ··· − 15u + 1)

− u

+ ··· + 2u − 1)(u

− 2u

+ ··· − u + 1)

+ 3u

+ 7u

+ 10u

+ 11u

+ 10u

+ 6u

+ 4u + 1)

· (u

− 6u

+ ··· + 1795665u + 338425)

+ u

− 3u

− 2u

+ 3u

+ 2u − 1)(u

− 2u

+ ··· + 7u + 1)

− 3u

+ 7u

− 10u

+ 11u

− 10u

+ 6u

− 4u + 1)

· (u

+ 6u

+ ··· + 11u + 1)

+ u

+ ··· − 2u − 1)(u

− 2u

+ ··· − u + 1)

, c

− u

− 3u

+ 2u

+ 3u

− 2u − 1)(u

− 2u

+ ··· + 7u + 1)

IV. Riley Polynomials

Crossings Riley Polynomials at each crossing

((y −1)

)(y

+ 65y

+ ··· − 5331y + 1)

, c

((y −1)

)(y

− 3y

+ ··· − 71y + 1)

, c

− 51y

+ ··· − 1228800y + 65536)

, c

− 3y

+ 7y

− 10y

+ 11y

− 10y

+ 6y

− 4y + 1)

· (y

− 6y

+ ··· − 11y + 1)

+ 5y

+ 11y

+ 6y

− 17y

− 34y

− 22y

− 4y + 1)

· (y

+ 106y

+ ··· + 912331286925y + 114531480625)

, c

− 7y

+ 19y

− 22y

+ 3y

+ 14y

− 6y

− 4y + 1)

· (y

− 26y

+ ··· − 11y + 1)

+ 5y

+ 11y

+ 6y

− 17y

− 34y

− 22y

− 4y + 1)

· (y

+ 46y

+ ··· + y + 1)