12n

0114

(K12n

0114

)

A knot diagram

Linearized knot diagam

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

Solving Sequence

3,6 7,11

8 12 10 5 2 1 4 9

, c

Ideals for irreducible components

of X

par

= h−9.14531 × 10

− 4.14356 × 10

+ ··· + 1.76003 × 10

b − 1.59371 × 10

1.28899 × 10

+ 5.88274 × 10

+ ··· + 1.76003 × 10

a + 2.33162 × 10

, u

+ 5u

+ ··· + 100u + 8i

= ha, −2v

+ b − 11v −5, v

+ 6v

+ 5v + 1i

* 2 irreducible components of dim

= 0, with total 39 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

= h−9.15 × 10

− 4.14 × 10

+ · · · + 1.76 × 10

b − 1.59 ×

, 1.29 × 10

+ 5.88 × 10

+ · · · + 1.76 × 10

a + 2.33 ×

, u

+ 5u

+ · · · + 100u + 8i

(i) Arc colorings











−u





−7.32365u

− 33.4240u

+ ··· − 1373.93u − 132.476

5.19610u

+ 23.5425u

+ ··· + 929.199u + 90.5501





−2.85572u

− 13.0958u

+ ··· − 534.587u − 49.9748

6.43037u

+ 29.3531u

+ ··· + 1194.14u + 116.627





−8.36579u

− 38.2406u

+ ··· − 1566.57u − 152.043

−7.62009u

− 34.5272u

+ ··· − 1350.03u − 129.988





−2.12755u

− 9.88152u

+ ··· − 444.735u − 41.9259

5.19610u

+ 23.5425u

+ ··· + 929.199u + 90.5501





−7.87506u

− 36.0437u

+ ··· − 1496.97u − 147.313

−6.09885u

− 27.8847u

+ ··· − 1136.15u − 110.850





1.77621u

+ 8.15902u

+ ··· + 360.821u + 36.4622

−6.09885u

− 27.8847u

+ ··· − 1136.15u − 110.850





1.77621u

+ 8.15902u

+ ··· + 360.821u + 36.4622

−6.43037u

− 29.3531u

+ ··· − 1194.14u − 116.627









−7.53767u

− 34.2907u

+ ··· − 1382.29u − 132.035

−7.62009u

− 34.5272u

+ ··· − 1350.03u − 129.988



(ii) Obstruction class = −1

(iii) Cusp Shapes = −6.83261u

− 31.8751u

+ ··· − 1561.72u − 175.808

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

+ 16u

+ ··· + 1288u + 1

, c

− 4u

+ ··· + 40u − 1

, c

+ 5u

+ ··· + 100u + 8

, c

− 2u

+ ··· + u − 1

, c

+ 2u

+ ··· + 7u + 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

+ 12y

+ ··· − 1626228y + 1

, c

− 16y

+ ··· − 1288y + 1

, c

− 21y

+ ··· − 2896y + 64

, c

− 10y

+ ··· − 15y + 1

, c

− 46y

+ ··· − 15y + 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.951665 + 0.111092I

a = −0.431237 − 0.863781I

b = −1.016850 + 0.561715I

−7.17502 − 0.39945I −11.42530 − 2.21050I

u = −0.951665 − 0.111092I

a = −0.431237 + 0.863781I

b = −1.016850 − 0.561715I

−7.17502 + 0.39945I −11.42530 + 2.21050I

u = −1.135690 + 0.254702I

a = 0.146387 − 0.970130I

b = 1.133020 + 0.740784I

0.62483 − 2.04170I −10.35918 + 1.70065I

u = −1.135690 − 0.254702I

a = 0.146387 + 0.970130I

b = 1.133020 − 0.740784I

0.62483 + 2.04170I −10.35918 − 1.70065I

u = 1.170730 + 0.165186I

a = −0.146630 − 1.072540I

b = 0.723486 + 1.096980I

0.80642 + 2.95434I −10.23945 − 4.42135I

u = 1.170730 − 0.165186I

a = −0.146630 + 1.072540I

b = 0.723486 − 1.096980I

0.80642 − 2.95434I −10.23945 + 4.42135I

u = 1.093820 + 0.450940I

a = 0.198422 + 1.111360I

b = −0.80338 − 1.18468I

−8.47527 + 5.02113I −12.68797 − 4.01507I

u = 1.093820 − 0.450940I

a = 0.198422 − 1.111360I

b = −0.80338 + 1.18468I

−8.47527 − 5.02113I −12.68797 + 4.01507I

u = −0.124199 + 0.801257I

a = 0.665075 − 0.293846I

b = 0.553901 − 0.383757I

−0.98172 + 1.29447I −8.27671 − 4.94353I

u = −0.124199 − 0.801257I

a = 0.665075 + 0.293846I

b = 0.553901 + 0.383757I

−0.98172 − 1.29447I −8.27671 + 4.94353I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.362629 + 0.610597I

a = 2.69945 + 2.81797I

b = 0.262208 − 0.537409I

−10.67130 − 0.80920I −11.8725 − 7.9012I

u = 0.362629 − 0.610597I

a = 2.69945 − 2.81797I

b = 0.262208 + 0.537409I

−10.67130 + 0.80920I −11.8725 + 7.9012I

u = 1.299370 + 0.175302I

a = 0.109102 − 0.984674I

b = −0.711387 + 0.963106I

3.93613 + 0.48813I −8.00000 + 0.I

u = 1.299370 − 0.175302I

a = 0.109102 + 0.984674I

b = −0.711387 − 0.963106I

3.93613 − 0.48813I −8.00000 + 0.I

u = −1.33664

a = −0.884238

b = 0.733489

−5.20604 −20.5790

u = −1.274050 + 0.484036I

a = −0.061622 + 1.057230I

b = −1.131720 − 0.834492I

2.62931 − 6.16336I 0

u = −1.274050 − 0.484036I

a = −0.061622 − 1.057230I

b = −1.131720 + 0.834492I

2.62931 + 6.16336I 0

u = −0.620095

a = −0.352428

b = −1.23303

−7.22329 −9.44110

u = −0.368042 + 1.337050I

a = 0.0916710 + 0.0573874I

b = −0.721465 + 0.368329I

−3.57709 + 3.06628I 0

u = −0.368042 − 1.337050I

a = 0.0916710 − 0.0573874I

b = −0.721465 − 0.368329I

−3.57709 − 3.06628I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.38770 + 0.55268I

a = −0.100698 + 0.877700I

b = 0.738741 − 0.854400I

1.86604 + 3.97837I 0

u = 1.38770 − 0.55268I

a = −0.100698 − 0.877700I

b = 0.738741 + 0.854400I

1.86604 − 3.97837I 0

u = −1.32289 + 0.71008I

a = −0.001088 − 1.100240I

b = 1.13619 + 0.89382I

−0.47169 − 10.13360I 0

u = −1.32289 − 0.71008I

a = −0.001088 + 1.100240I

b = 1.13619 − 0.89382I

−0.47169 + 10.13360I 0

u = 0.109684 + 0.468653I

a = −4.34383 − 0.78050I

b = −0.305755 + 0.402075I

−2.47816 − 0.36322I −22.4241 − 7.2894I

u = 0.109684 − 0.468653I

a = −4.34383 + 0.78050I

b = −0.305755 − 0.402075I

−2.47816 + 0.36322I −22.4241 + 7.2894I

u = −0.457715

a = −0.349404

b = 1.88779

−18.9939 0.748010

u = −0.419542

a = 3.94537

b = −0.449274

−2.16435 6.04220

u = −1.35964 + 0.90324I

a = 0.041014 + 1.132360I

b = −1.13264 − 0.93383I

−9.5740 − 12.5541I 0

u = −1.35964 − 0.90324I

a = 0.041014 − 1.132360I

b = −1.13264 + 0.93383I

−9.5740 + 12.5541I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.55670 + 0.88459I

a = 0.149365 − 0.795837I

b = −0.795627 + 0.795592I

−6.45728 + 5.83835I 0

u = 1.55670 − 0.88459I

a = 0.149365 + 0.795837I

b = −0.795627 − 0.795592I

−6.45728 − 5.83835I 0

u = −1.82632

a = 0.746253

b = −0.820048

−14.0797 0

u = −0.53066 + 1.74778I

a = −0.267774 + 0.061830I

b = 0.804398 − 0.366712I

−12.28810 + 3.87987I 0

u = −0.53066 − 1.74778I

a = −0.267774 − 0.061830I

b = 0.804398 + 0.366712I

−12.28810 − 3.87987I 0

u = −0.167275

a = 2.39925

b = 0.414843

−0.738035 −13.3280

II. I

= ha, −2v

+ b − 11v − 5, v

+ 6v

+ 5v + 1i

(i) Arc colorings















+ 11v + 5





+ 6v + 5





−2v

− 11v − 5

−3v

− 17v − 9





+ 11v + 5





−v

− 6v − 4

−v

− 6v − 5





+ 7v + 4

+ 6v + 5





+ 6v + 4

+ 6v + 5









−v

− 6v − 4

−3v

− 17v − 9



(ii) Obstruction class = 1

(iii) Cusp Shapes = −6v

− 29v − 37

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

(u − 1)

, c

(u + 1)

, c

− u

− 2u + 1

, c

+ u

− 2u − 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

(y − 1)

, c

− 5y

+ 6y − 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

v = −0.643104

a = 0

b = −1.24698

−7.98968 −20.8310

v = −0.307979

a = 0

b = 1.80194

−19.2692 −28.6380

v = −5.04892

a = 0

b = 0.445042

−2.34991 −43.5310

III. u-Polynomials

Crossings u-Polynomials at each crossing

((u − 1)

)(u

+ 16u

+ ··· + 1288u + 1)

((u − 1)

)(u

− 4u

+ ··· + 40u − 1)

, c

+ 5u

+ ··· + 100u + 8)

((u + 1)

)(u

− 4u

+ ··· + 40u − 1)

− u

− 2u + 1)(u

− 2u

+ ··· + u − 1)

, c

− u

− 2u + 1)(u

+ 2u

+ ··· + 7u + 1)

+ u

− 2u − 1)(u

− 2u

+ ··· + u − 1)

, c

+ u

− 2u − 1)(u

+ 2u

+ ··· + 7u + 1)

IV. Riley Polynomials

Crossings Riley Polynomials at each crossing

((y − 1)

)(y

+ 12y

+ ··· − 1626228y + 1)

, c

((y − 1)

)(y

− 16y

+ ··· − 1288y + 1)

, c

− 21y

+ ··· − 2896y + 64)

, c

− 5y

+ 6y − 1)(y

− 10y

+ ··· − 15y + 1)

, c

− 5y

+ 6y − 1)(y

− 46y

+ ··· − 15y + 1)