12n

0107

(K12n

0107

)

A knot diagram

1

Linearized knot diagam

3 5 7 2 10 4 11 12 6 7 8 10

Solving Sequence

7,10

11 8 12

1,4

3 6 5 2 9

c

10

c

7

c

11

c

12

c

3

c

6

c

5

c

2

c

9

c

1

, c

4

, c

8

Ideals for irreducible components

2

of X

par

I

u

1

= h47441368u

25

+ 57693789u

24

+ ··· + 104373924b + 18568285,

120201295u

25

+ 398061213u

24

+ ··· + 104373924a + 783424087, u

26

+ 5u

25

+ ··· + 14u − 1i

I

u

2

= h2a

2

u + a

2

− au + b − a + 2u, a

3

− a

2

u + a

2

− 2au + 4a − 2u + 3, u

2

− u − 1i

I

u

3

= hb + 1, a, u + 1i

* 3 irreducible components of dim

C

= 0, with total 33 representations.

1

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).

2

All coeﬃcients of polynomials are rational numbers. But the coeﬃcients are sometimes approximated

in decimal forms when there is not enough margin.

1

I. I

u

1

= h4.74 × 10

7

u

25

+ 5 .77 × 10

7

u

24

+ · · · + 1.04 × 10

8

b + 1.86 × 10

7

, 1.20 ×

10

8

u

25

+3.98×10

8

u

24

+· · ·+1.04×10

8

a+7.83×10

8

, u

26

+5u

25

+· · ·+14u−1i

(i) Arc colorings

a

7

=



0

u



a

10

=



1

0



a

11

=



1

u

2



a

8

=



−u

3

+ u



a

12

=



−u

2

+ 1

−u

4

+ 2u

2



a

1

=



u

4

− 3u

2

+ 1

−u

4

+ 2u

2



a

4

=



−1.15164u

25

− 3.81380u

24

+ ··· − 24.4464u − 7.50594

−0.454533u

25

− 0.552761u

24

+ ··· + 13.0629u − 0.177902



a

3

=



−1.15164u

25

− 3.81380u

24

+ ··· − 24.4464u − 7.50594

3.33329u

25

+ 11.3654u

24

+ ··· + 41.4363u − 2.12231



a

6

=



−0.633480u

25

− 1.36564u

24

+ ··· + 2.69053u + 4.69952

−1.23184u

25

− 3.55184u

24

+ ··· − 6.61306u + 0.205455



a

5

=



0.598359u

25

+ 2.18620u

24

+ ··· + 9.30359u + 4.49406

−1.23184u

25

− 3.55184u

24

+ ··· − 6.61306u + 0.205455



a

2

=



−0.598359u

25

− 2.18620u

24

+ ··· − 9.30359u − 4.49406

−0.203032u

25

+ 0.469119u

24

+ ··· + 15.6624u − 0.533217



a

9

=



u

3

− 2u

u

5

− 3u

3

+ u



(ii) Obstruction class = −1

(iii) Cusp Shapes = −

92088909

17395654

u

25

−

188693588

8697827

u

24

+ ··· −

885802456

8697827

u −

15795407

8697827

2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

u

26

+ 20u

25

+ ··· + 79u + 1

c

2

, c

4

u

26

− 4u

25

+ ··· − 11u − 1

c

3

, c

6

u

26

− 3u

25

+ ··· − 6u + 2

c

5

, c

9

u

26

− 2u

25

+ ··· − 96u + 64

c

7

, c

8

, c

10

c

11

u

26

+ 5u

25

+ ··· + 14u − 1

c

12

u

26

− 21u

25

+ ··· + 52120u + 337

3

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

y

26

− 24y

25

+ ··· − 6127y + 1

c

2

, c

4

y

26

− 20y

25

+ ··· − 79y + 1

c

3

, c

6

y

26

− 3y

25

+ ··· − 40y + 4

c

5

, c

9

y

26

+ 34y

25

+ ··· − 95232y + 4096

c

7

, c

8

, c

10

c

11

y

26

− 39y

25

+ ··· − 304y + 1

c

12

y

26

− 123y

25

+ ··· − 2285596764y + 113569

4

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = −0.476607 + 0.919429I

a = −0.688440 − 0.733293I

b = 0.227587 + 1.287750I

−5.18299 + 2.95142I −14.7696 − 4.0162I

u = −0.476607 − 0.919429I

a = −0.688440 + 0.733293I

b = 0.227587 − 1.287750I

−5.18299 − 2.95142I −14.7696 + 4.0162I

u = −0.757036

a = −0.441343

b = 0.637723

−1.34161 −6.51520

u = 1.223650 + 0.232594I

a = −0.924838 − 0.484695I

b = 0.280314 − 1.358420I

−5.77000 − 3.25214I −11.73752 + 3.41900I

u = 1.223650 − 0.232594I

a = −0.924838 + 0.484695I

b = 0.280314 + 1.358420I

−5.77000 + 3.25214I −11.73752 − 3.41900I

u = −1.329480 + 0.241157I

a = 0.277950 + 0.611388I

b = 0.308061 + 0.000558I

−3.29395 − 1.34186I −11.30499 + 4.69401I

u = −1.329480 − 0.241157I

a = 0.277950 − 0.611388I

b = 0.308061 − 0.000558I

−3.29395 + 1.34186I −11.30499 − 4.69401I

u = 1.369250 + 0.095489I

a = 0.500507 − 0.680570I

b = 0.10931 − 1.70719I

−9.37037 − 1.40410I −14.8448 + 0.4920I

u = 1.369250 − 0.095489I

a = 0.500507 + 0.680570I

b = 0.10931 + 1.70719I

−9.37037 + 1.40410I −14.8448 − 0.4920I

u = 1.273730 + 0.536724I

a = 0.988931 + 0.204426I

b = −0.48656 + 1.60886I

−10.60190 − 7.95034I −14.2939 + 5.5201I

5

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = 1.273730 − 0.536724I

a = 0.988931 − 0.204426I

b = −0.48656 − 1.60886I

−10.60190 + 7.95034I −14.2939 − 5.5201I

u = −0.586682 + 0.167108I

a = −0.045237 − 0.711969I

b = −0.71246 − 2.34576I

−2.72200 + 0.36882I −3.94523 + 10.24837I

u = −0.586682 − 0.167108I

a = −0.045237 + 0.711969I

b = −0.71246 + 2.34576I

−2.72200 − 0.36882I −3.94523 − 10.24837I

u = −0.348677 + 0.367916I

a = 1.247060 + 0.371784I

b = −0.209352 − 0.864493I

−0.636376 + 1.127340I −7.20662 − 6.11077I

u = −0.348677 − 0.367916I

a = 1.247060 − 0.371784I

b = −0.209352 + 0.864493I

−0.636376 − 1.127340I −7.20662 + 6.11077I

u = 0.424219 + 0.095685I

a = 0.07818 + 2.89428I

b = −0.1185550 − 0.0289313I

2.35620 + 2.67700I 3.89989 + 1.35809I

u = 0.424219 − 0.095685I

a = 0.07818 − 2.89428I

b = −0.1185550 + 0.0289313I

2.35620 − 2.67700I 3.89989 − 1.35809I

u = 1.63681

a = 0.377195

b = −1.87474

−9.79249 1.55260

u = −1.80599 + 0.06787I

a = 0.735548 − 0.651435I

b = −0.23521 − 1.59914I

−16.9214 + 4.6752I 0

u = −1.80599 − 0.06787I

a = 0.735548 + 0.651435I

b = −0.23521 + 1.59914I

−16.9214 − 4.6752I 0

6

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = −1.81333 + 0.15530I

a = −0.732203 + 0.586510I

b = 0.50599 + 1.87679I

17.8851 + 11.1272I 0

u = −1.81333 − 0.15530I

a = −0.732203 − 0.586510I

b = 0.50599 − 1.87679I

17.8851 − 11.1272I 0

u = −1.83864 + 0.02244I

a = −0.672414 − 0.695929I

b = −0.16075 − 1.49337I

18.0411 + 1.9797I 0

u = −1.83864 − 0.02244I

a = −0.672414 + 0.695929I

b = −0.16075 + 1.49337I

18.0411 − 1.9797I 0

u = 1.87792

a = −0.655106

b = −0.356336

−16.1049 −16.4270

u = 0.0594263

a = −8.81083

b = 0.576606

−1.19028 −8.21100

7

II.

I

u

2

= h2a

2

u+a

2

−au+b −a + 2u, a

3

−a

2

u+a

2

−2au+4a −2u + 3, u

2

−u−1i

(i) Arc colorings

a

7

=



0

u



a

10

=



1

0



a

11

=



1

u + 1



a

8

=



−u

−u − 1



a

12

=



−u



a

1

=



0

−u



a

4

=



a

−2a

2

u − a

2

+ au + a − 2u



a

3

=



a

−2a

2

u − a

2

− 2u



a

6

=



a

2

u

0



a

5

=



a

2

u

0



a

2

=



a

2

u

−2a

2

u − a

2

− 2u



a

9

=



1

0



(ii) Obstruction class = 1

(iii) Cusp Shapes = −19a

2

u − 13a

2

+ 9au + a − 8u − 29

8

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

, c

3

(u

3

− u

2

+ 2u − 1)

2

c

2

(u

3

+ u

2

− 1)

2

c

4

(u

3

− u

2

+ 1)

2

c

5

, c

9

u

6

c

6

(u

3

+ u

2

+ 2u + 1)

2

c

7

, c

8

(u

2

+ u − 1)

3

c

10

, c

11

, c

12

(u

2

− u − 1)

3

9

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

, c

3

, c

6

(y

3

+ 3y

2

+ 2y −1)

2

c

2

, c

4

(y

3

− y

2

+ 2y −1)

2

c

5

, c

9

y

6

c

7

, c

8

, c

10

c

11

, c

12

(y

2

− 3y + 1)

3

10

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

2

√

−1(vol +

√

−1CS) Cusp shape

u = −0.618034

a = −0.922021

b = 1.08457

−2.10041 −20.9180

u = −0.618034

a = −0.34801 + 2.11500I

b = 0.075747 + 0.460350I

2.03717 + 2.82812I −16.9959 − 7.7984I

u = −0.618034

a = −0.34801 − 2.11500I

b = 0.075747 − 0.460350I

2.03717 − 2.82812I −16.9959 + 7.7984I

u = 1.61803

a = 0.132927 + 0.807858I

b = −0.198308 + 1.205210I

−5.85852 − 2.82812I −12.10059 + 3.17745I

u = 1.61803

a = 0.132927 − 0.807858I

b = −0.198308 − 1.205210I

−5.85852 + 2.82812I −12.10059 − 3.17745I

u = 1.61803

a = 0.352181

b = −2.83945

−9.99610 −41.8890

11

III. I

u

3

= hb + 1, a, u + 1i

(i) Arc colorings

a

7

=



0

−1



a

10

=



1

0



a

11

=



1



a

8

=



1

0



a

12

=



0

1



a

1

=



−1

1



a

4

=



0

−1



a

3

=



0

−1



a

6

=



0

−1



a

5

=



1

−1



a

2

=



−1

0



a

9

=



1



(ii) Obstruction class = 1

(iii) Cusp Shapes = −12

12

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

, c

2

, c

5

c

7

, c

8

u − 1

c

3

, c

6

u

c

4

, c

9

, c

10

c

11

, c

12

u + 1

13

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

, c

2

, c

4

c

5

, c

7

, c

8

c

9

, c

10

, c

11

c

12

y −1

c

3

, c

6

y

14

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

3

√

−1(vol +

√

−1CS) Cusp shape

u = −1.00000

a = 0

b = −1.00000

−3.28987 −12.0000

15

IV. u-Polynomials

Crossings u-Polynomials at each crossing

c

1

(u − 1)(u

3

− u

2

+ 2u − 1)

2

(u

26

+ 20u

25

+ ··· + 79u + 1)

c

2

(u − 1)(u

3

+ u

2

− 1)

2

(u

26

− 4u

25

+ ··· − 11u − 1)

c

3

u(u

3

− u

2

+ 2u − 1)

2

(u

26

− 3u

25

+ ··· − 6u + 2)

c

4

(u + 1)(u

3

− u

2

+ 1)

2

(u

26

− 4u

25

+ ··· − 11u − 1)

c

5

u

6

(u − 1)(u

26

− 2u

25

+ ··· − 96u + 64)

c

6

u(u

3

+ u

2

+ 2u + 1)

2

(u

26

− 3u

25

+ ··· − 6u + 2)

c

7

, c

8

(u − 1)(u

2

+ u − 1)

3

(u

26

+ 5u

25

+ ··· + 14u − 1)

c

9

u

6

(u + 1)(u

26

− 2u

25

+ ··· − 96u + 64)

c

10

, c

11

(u + 1)(u

2

− u − 1)

3

(u

26

+ 5u

25

+ ··· + 14u − 1)

c

12

(u + 1)(u

2

− u − 1)

3

(u

26

− 21u

25

+ ··· + 52120u + 337)

16

V. Riley Polynomials

Crossings Riley Polynomials at each crossing

c

1

(y −1)(y

3

+ 3y

2

+ 2y −1)

2

(y

26

− 24y

25

+ ··· − 6127y + 1)

c

2

, c

4

(y −1)(y

3

− y

2

+ 2y −1)

2

(y

26

− 20y

25

+ ··· − 79y + 1)

c

3

, c

6

y(y

3

+ 3y

2

+ 2y −1)

2

(y

26

− 3y

25

+ ··· − 40y + 4)

c

5

, c

9

y

6

(y −1)(y

26

+ 34y

25

+ ··· − 95232y + 4096)

c

7

, c

8

, c

10

c

11

(y −1)(y

2

− 3y + 1)

3

(y

26

− 39y

25

+ ··· − 304y + 1)

c

12

(y −1)(y

2

− 3y + 1)

3

(y

26

− 123y

25

+ ··· − 2.28560 × 10

9

y + 113569)

17