12n

0291

(K12n

0291

)

A knot diagram

Linearized knot diagam

3 6 7 8 2 5 11 5 12 1 8 10

Solving Sequence

2,6

3 1 5

7,11

8 4 10 12 9

, c

Ideals for irreducible components

of X

par

= h2.93542 × 10

− 6.67587 × 10

+ ··· + 2.93396 × 10

b − 4.34022 × 10

2.00229 × 10

− 6.17396 × 10

+ ··· + 2.93396 × 10

a − 3.02275 × 10

, u

− 4u

+ ··· + 2u + 1i

= h−u

a + u

+ b, 2u

a + a

+ au − 2u

− a − 2u − 1, u

+ u

− 1i

= hb, a − 1, u − 1i

* 3 irreducible components of dim

= 0, with total 63 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.

= h2.94 × 10

− 6.68 × 10

+ · · · + 2.93 × 10

b − 4.34 × 10

, 2.00 ×

−6.17×10

+· · ·+2.93×10

a−3.02×10

, u

−4u

+· · ·+2u+1i

(i) Arc colorings















−u

+ 1

−u









−u

+ u





−6.82450u

+ 21.0431u

+ ··· + 1.50746u + 10.3026

−1.00050u

+ 2.27537u

+ ··· − 2.44477u + 0.147930





3.65406u

− 10.3520u

+ ··· + 5.15325u − 4.23694

4.10204u

− 12.0354u

+ ··· − 2.31411u − 2.32151





−u

+ u

− u

+ 1

−u

+ 2u

− 2u

+ 2u





−6.34999u

+ 19.7941u

+ ··· − 0.691497u + 9.35095

−0.586914u

+ 1.14134u

+ ··· − 2.44719u + 0.0395175





−2.57455u

+ 8.57238u

+ ··· − 0.0350557u + 6.04787

3.43407u

− 10.9313u

+ ··· − 6.20880u − 2.54966





−3.42363u

+ 10.3054u

+ ··· − 4.48816u + 4.34550

−3.87161u

+ 11.9888u

+ ··· + 2.97921u + 2.43006



(ii) Obstruction class = −1

(iii) Cusp Shapes = −

6957411366946544141

146698213939434107

43997122065882996801

293396427878868214

+ ··· +

49895915246887856523

293396427878868214

u +

19684211583463159307

293396427878868214

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

+ 20u

+ ··· + 94u + 1

, c

+ 4u

+ ··· − 2u + 1

− 2u

+ ··· − 37222u + 7489

, c

+ 4u

+ ··· + 416u − 64

, c

− 4u

+ ··· − 2u − 2

, c

+ 5u

+ ··· + 3u + 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

+ 36y

+ ··· − 6302y + 1

, c

− 20y

+ ··· − 94y + 1

− 24y

+ ··· − 5793307970y + 56085121

, c

+ 34y

+ ··· − 21504y + 4096

, c

− 18y

+ ··· − 80y + 4

, c

− 47y

+ ··· − 71y + 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.555632 + 0.820839I

a = −1.310140 + 0.452763I

b = −0.50995 + 1.32573I

6.89840 − 1.70687I 11.04654 + 2.11039I

u = −0.555632 − 0.820839I

a = −1.310140 − 0.452763I

b = −0.50995 − 1.32573I

6.89840 + 1.70687I 11.04654 − 2.11039I

u = −0.746093 + 0.643224I

a = 1.79687 − 0.81232I

b = 0.61922 − 1.61203I

2.14654 + 0.63049I 4.81685 + 0.I

u = −0.746093 − 0.643224I

a = 1.79687 + 0.81232I

b = 0.61922 + 1.61203I

2.14654 − 0.63049I 4.81685 + 0.I

u = 0.611315 + 0.811190I

a = 0.82986 + 1.25644I

b = −0.84573 + 1.32108I

−1.11438 + 4.39097I 2.00000 − 3.05982I

u = 0.611315 − 0.811190I

a = 0.82986 − 1.25644I

b = −0.84573 − 1.32108I

−1.11438 − 4.39097I 2.00000 + 3.05982I

u = 0.639496 + 0.745500I

a = 0.21432 + 1.59797I

b = −0.18371 + 1.40658I

2.28095 + 2.17813I 5.60335 − 1.04644I

u = 0.639496 − 0.745500I

a = 0.21432 − 1.59797I

b = −0.18371 − 1.40658I

2.28095 − 2.17813I 5.60335 + 1.04644I

u = −1.057330 + 0.031394I

a = 1.059980 + 0.396752I

b = 1.037210 − 0.754122I

−3.27157 + 1.64123I 0

u = −1.057330 − 0.031394I

a = 1.059980 − 0.396752I

b = 1.037210 + 0.754122I

−3.27157 − 1.64123I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.815754 + 0.715389I

a = 2.13178 − 1.95768I

b = 0.80101 − 3.45506I

4.64235 + 1.91730I 0

u = −0.815754 − 0.715389I

a = 2.13178 + 1.95768I

b = 0.80101 + 3.45506I

4.64235 − 1.91730I 0

u = 0.646892 + 0.638776I

a = −0.850743 − 0.918967I

b = 0.826318 − 0.495030I

1.49600 − 0.77880I 5.52001 + 0.97967I

u = 0.646892 − 0.638776I

a = −0.850743 + 0.918967I

b = 0.826318 + 0.495030I

1.49600 + 0.77880I 5.52001 − 0.97967I

u = 0.655547 + 0.884678I

a = −1.01004 − 1.55997I

b = 0.57473 − 1.83740I

3.85590 + 9.25734I 0

u = 0.655547 − 0.884678I

a = −1.01004 + 1.55997I

b = 0.57473 + 1.83740I

3.85590 − 9.25734I 0

u = 0.859653 + 0.688129I

a = 0.664066 − 0.017009I

b = −0.054388 − 0.658388I

11.29430 − 2.64795I 0

u = 0.859653 − 0.688129I

a = 0.664066 + 0.017009I

b = −0.054388 + 0.658388I

11.29430 + 2.64795I 0

u = 0.876983 + 0.151494I

a = 0.1160180 + 0.0212256I

b = −0.393762 − 0.405166I

−1.49543 − 0.33054I −5.58521 + 0.41922I

u = 0.876983 − 0.151494I

a = 0.1160180 − 0.0212256I

b = −0.393762 + 0.405166I

−1.49543 + 0.33054I −5.58521 − 0.41922I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −1.115310 + 0.073858I

a = −0.302761 + 0.507491I

b = −0.541213 − 0.678094I

−7.34462 + 3.52834I 0

u = −1.115310 − 0.073858I

a = −0.302761 − 0.507491I

b = −0.541213 + 0.678094I

−7.34462 − 3.52834I 0

u = −0.947166 + 0.640358I

a = −1.40216 + 1.01867I

b = −0.74124 + 2.06542I

1.51907 + 4.39807I 0

u = −0.947166 − 0.640358I

a = −1.40216 − 1.01867I

b = −0.74124 − 2.06542I

1.51907 − 4.39807I 0

u = −0.904546 + 0.704031I

a = −2.66914 + 2.18937I

b = −0.75000 + 3.34742I

4.37132 + 3.51272I 0

u = −0.904546 − 0.704031I

a = −2.66914 − 2.18937I

b = −0.75000 − 3.34742I

4.37132 − 3.51272I 0

u = 0.199557 + 0.823827I

a = −0.188450 + 0.800184I

b = −0.896805 − 0.162123I

1.27100 − 5.53243I 6.88478 + 5.95128I

u = 0.199557 − 0.823827I

a = −0.188450 − 0.800184I

b = −0.896805 + 0.162123I

1.27100 + 5.53243I 6.88478 − 5.95128I

u = −1.149520 + 0.171385I

a = −0.352409 − 0.425484I

b = 0.086994 + 0.749495I

−3.37562 + 8.61142I 0

u = −1.149520 − 0.171385I

a = −0.352409 + 0.425484I

b = 0.086994 − 0.749495I

−3.37562 − 8.61142I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.877750 + 0.767459I

a = 0.61912 + 1.30040I

b = 1.71436 + 0.44120I

3.73144 + 2.89531I 0

u = −0.877750 − 0.767459I

a = 0.61912 − 1.30040I

b = 1.71436 − 0.44120I

3.73144 − 2.89531I 0

u = 0.996417 + 0.644457I

a = 1.098620 − 0.312059I

b = 1.46572 + 1.16153I

0.45076 − 4.30103I 0

u = 0.996417 − 0.644457I

a = 1.098620 + 0.312059I

b = 1.46572 − 1.16153I

0.45076 + 4.30103I 0

u = 0.807123

a = 3.25049

b = −1.20792

0.339779 61.8040

u = 1.041510 + 0.583028I

a = 1.391730 − 0.045593I

b = 1.52856 + 0.47260I

−4.20570 − 3.27627I 0

u = 1.041510 − 0.583028I

a = 1.391730 + 0.045593I

b = 1.52856 − 0.47260I

−4.20570 + 3.27627I 0

u = 0.386849 + 0.703387I

a = 0.080082 − 1.229030I

b = 0.502755 − 0.488230I

−2.39037 − 1.55268I 1.61575 + 2.61232I

u = 0.386849 − 0.703387I

a = 0.080082 + 1.229030I

b = 0.502755 + 0.488230I

−2.39037 + 1.55268I 1.61575 − 2.61232I

u = 1.115730 + 0.439932I

a = −0.739493 + 0.517959I

b = −1.131660 + 0.027778I

−1.67584 + 0.98983I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.115730 − 0.439932I

a = −0.739493 − 0.517959I

b = −1.131660 − 0.027778I

−1.67584 − 0.98983I 0

u = 1.21660

a = −0.482061

b = 0.154807

0.661022 0

u = 1.013820 + 0.677594I

a = −1.87407 − 0.28208I

b = −1.80895 − 0.83661I

1.16708 − 7.61471I 0

u = 1.013820 − 0.677594I

a = −1.87407 + 0.28208I

b = −1.80895 + 0.83661I

1.16708 + 7.61471I 0

u = 1.043410 + 0.693114I

a = −1.80141 − 0.10454I

b = −1.81609 − 1.65261I

−2.41199 − 10.04440I 0

u = 1.043410 − 0.693114I

a = −1.80141 + 0.10454I

b = −1.81609 + 1.65261I

−2.41199 + 10.04440I 0

u = −1.063310 + 0.686319I

a = 1.20482 − 1.11113I

b = 0.57272 − 1.88306I

5.39990 + 7.34868I 0

u = −1.063310 − 0.686319I

a = 1.20482 + 1.11113I

b = 0.57272 + 1.88306I

5.39990 − 7.34868I 0

u = −0.906500 + 0.883744I

a = 0.426122 + 0.260836I

b = 0.259723 + 0.288378I

8.38533 + 3.24583I 0

u = −0.906500 − 0.883744I

a = 0.426122 − 0.260836I

b = 0.259723 − 0.288378I

8.38533 − 3.24583I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.055930 + 0.737690I

a = 2.11012 + 0.58896I

b = 1.89812 + 2.08623I

2.6209 − 15.2730I 0

u = 1.055930 − 0.737690I

a = 2.11012 − 0.58896I

b = 1.89812 − 2.08623I

2.6209 + 15.2730I 0

u = −0.665378

a = −2.70313

b = −1.90693

7.93809 29.4940

u = 0.372658 + 0.279589I

a = −1.53134 − 0.64420I

b = 1.017650 − 0.002132I

1.155810 − 0.800051I 6.92184 − 0.19721I

u = 0.372658 − 0.279589I

a = −1.53134 + 0.64420I

b = 1.017650 + 0.002132I

1.155810 + 0.800051I 6.92184 + 0.19721I

u = −0.112048

a = 5.51199

b = 0.496888

0.859867 11.9670

II. I

= h−u

a + u

+ b, 2u

a + a

+ au − 2u

− a − 2u − 1, u

+ u

− 1i

(i) Arc colorings















−u

+ 1

−u

− u + 1









− 1

+ u − 1





a − u





−au + 2u

+ 2u − 1

−au + 2u

+ 2u − 1









au − 2u

− u + 2

au − 2u

− 2u + 2





−2au + 3u

+ a + 3u − 2

a − 2au + 2u

+ 3u − 2





−au + 2u

+ 2u − 1

−au + 2u

+ 2u − 1



(ii) Obstruction class = 1

(iii) Cusp Shapes = 3u

a − 4u

+ 3a − 10u + 3

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

− u

+ 2u − 1)

+ u

− 1)

, c

− u

+ 1)

+ u

+ 2u + 1)

, c

− u − 1)

, c

+ u − 1)

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

+ 3y

+ 2y −1)

, c

− y

+ 2y −1)

, c

− 3y + 1)

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.877439 + 0.744862I

a = 0.586612 + 0.101930I

b = 0.044325 + 0.562280I

11.90680 + 2.82812I 13.45212 − 4.14885I

u = −0.877439 + 0.744862I

a = 0.86067 + 1.76749I

b = 2.28039 + 0.56228I

4.01109 + 2.82812I 20.9825 + 0.8478I

u = −0.877439 − 0.744862I

a = 0.586612 − 0.101930I

b = 0.044325 − 0.562280I

11.90680 − 2.82812I 13.45212 + 4.14885I

u = −0.877439 − 0.744862I

a = 0.86067 − 1.76749I

b = 2.28039 − 0.56228I

4.01109 − 2.82812I 20.9825 − 0.8478I

u = 0.754878

a = 1.51473

b = 0.293316

−0.126494 0.305530

u = 0.754878

a = −2.40929

b = −1.94275

7.76919 −18.1750

III. I

= hb, a − 1, u − 1i

(i) Arc colorings















−1









−1









−1



















(ii) Obstruction class = 1

(iii) Cusp Shapes = 0

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

u − 1

, c

u + 1

, c

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

y −1

, c

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.00000

a = 1.00000

b = 0

0 0

IV. u-Polynomials

Crossings u-Polynomials at each crossing

(u − 1)(u

− u

+ 2u − 1)

+ 20u

+ ··· + 94u + 1)

(u − 1)(u

+ u

− 1)

+ 4u

+ ··· − 2u + 1)

(u − 1)(u

− u

+ 2u − 1)

− 2u

+ ··· − 37222u + 7489)

(u − 1)(u

+ 4u

+ ··· + 416u − 64)

(u + 1)(u

− u

+ 1)

+ 4u

+ ··· − 2u + 1)

(u + 1)(u

+ u

+ 2u + 1)

+ 20u

+ ··· + 94u + 1)

u(u

− u − 1)

− 4u

+ ··· − 2u − 2)

(u + 1)(u

+ 4u

+ ··· + 416u − 64)

, c

(u + 1)(u

− u − 1)

+ 5u

+ ··· + 3u + 1)

u(u

+ u − 1)

− 4u

+ ··· − 2u − 2)

(u − 1)(u

+ u − 1)

+ 5u

+ ··· + 3u + 1)

V. Riley Polynomials

Crossings Riley Polynomials at each crossing

, c

(y −1)(y

+ 3y

+ 2y −1)

+ 36y

+ ··· − 6302y + 1)

, c

(y −1)(y

− y

+ 2y −1)

− 20y

+ ··· − 94y + 1)

(y −1)(y

+ 3y

+ 2y −1)

· (y

− 24y

+ ··· − 5793307970y + 56085121)

, c

(y −1)(y

+ 34y

+ ··· − 21504y + 4096)

, c

y(y

− 3y + 1)

− 18y

+ ··· − 80y + 4)

, c

(y −1)(y

− 3y + 1)

− 47y

+ ··· − 71y + 1)