12a

0380

(K12a

0380

)

A knot diagram

1

Linearized knot diagam

3 6 9 10 2 1 12 11 5 4 8 7

Solving Sequence

4,11

10 5 9 3 8 12 7 1 2 6

c

10

c

4

c

9

c

3

c

8

c

11

c

7

c

12

c

1

c

6

c

2

, c

5

Ideals for irreducible components

2

of X

par

I

u

1

= hu

38

+ u

37

+ ··· + u + 1i

* 1 irreducible components of dim

C

= 0, with total 38 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

= hu

38

+ u

37

+ · · · + u + 1i

(i) Arc colorings

a

4

=



0

u



a

11

=



1

0



a

10

=



1

u

2



a

5

=



u

3

+ u



a

9

=



u

2

+ 1

u

4

+ 2u

2



a

3

=



−u

5

− 2u

3

− u

−u

7

− 3u

5

− 2u

3

+ u



a

8

=



−u

4

− u

2

+ 1

u

4

+ 2u

2



a

12

=



u

8

+ 3u

6

+ u

4

− 2u

2

+ 1

−u

8

− 4u

6

− 4u

4



a

7

=



−u

12

− 5u

10

− 7u

8

+ 2u

4

− 3u

2

+ 1

u

12

+ 6u

10

+ 12u

8

+ 8u

6

+ u

4

+ 2u

2



a

1

=



u

16

+ 7u

14

+ 17u

12

+ 14u

10

− u

8

+ 2u

6

+ 6u

4

− 4u

2

+ 1

−u

16

− 8u

14

− 24u

12

− 32u

10

− 18u

8

− 8u

6

− 8u

4



a

2

=



u

28

+ 13u

26

+ ··· − 5u

2

+ 1

u

30

+ 14u

28

+ ··· − 16u

4

+ u

2



a

6

=



−u

20

− 9u

18

+ ··· − 5u

2

+ 1

u

20

+ 10u

18

+ 40u

16

+ 80u

14

+ 83u

12

+ 50u

10

+ 36u

8

+ 24u

6

+ u

4

+ 2u

2



(ii) Obstruction class = −1

(iii) Cusp Shapes

= −4u

36

− 4u

35

− 72u

34

− 68u

33

− 580u

32

− 516u

31

− 2748u

30

− 2292u

29

− 8476u

28

−

6576u

27

−17864u

26

−12736u

25

−26568u

24

−17112u

23

−29228u

22

−16736u

21

−26160u

20

−

13388u

19

− 21072u

18

− 9832u

17

− 14636u

16

− 5896u

15

− 7812u

14

− 2336u

13

− 3700u

12

−

856u

11

−1816u

10

−336u

9

−456u

8

+ 80u

7

−56u

6

+ 40u

5

−68u

4

+ 20u

3

+ 24u

2

+ 16u + 2

2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

u

38

+ 23u

37

+ ··· + 5u + 1

c

2

, c

5

u

38

+ u

37

+ ··· + u + 1

c

3

u

38

− u

37

+ ··· + 81u + 317

c

4

, c

9

, c

10

u

38

+ u

37

+ ··· + u + 1

c

6

, c

7

, c

8

c

11

, c

12

u

38

+ 3u

37

+ ··· + 15u + 3

3

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

y

38

− 15y

37

+ ··· + 3y + 1

c

2

, c

5

y

38

− 23y

37

+ ··· − 5y + 1

c

3

y

38

+ 25y

37

+ ··· + 1416135y + 100489

c

4

, c

9

, c

10

y

38

+ 37y

37

+ ··· − 5y + 1

c

6

, c

7

, c

8

c

11

, c

12

y

38

+ 53y

37

+ ··· + 123y + 9

4

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = −0.699030 + 0.516783I

−16.5834 + 2.6642I −1.43407 − 0.13323I

u = −0.699030 − 0.516783I

−16.5834 − 2.6642I −1.43407 + 0.13323I

u = −0.709471 + 0.500003I

−16.5259 − 7.3585I −1.27138 + 5.67363I

u = −0.709471 − 0.500003I

−16.5259 + 7.3585I −1.27138 − 5.67363I

u = 0.699159 + 0.504973I

−12.61000 + 2.32929I 1.79922 − 2.79577I

u = 0.699159 − 0.504973I

−12.61000 − 2.32929I 1.79922 + 2.79577I

u = 0.046655 + 1.266040I

−2.65817 + 1.73113I 5.04604 − 4.55747I

u = 0.046655 − 1.266040I

−2.65817 − 1.73113I 5.04604 + 4.55747I

u = 0.617788 + 0.394340I

−5.75531 + 5.89610I −0.12847 − 7.53727I

u = 0.617788 − 0.394340I

−5.75531 − 5.89610I −0.12847 + 7.53727I

u = 0.548294 + 0.475497I

−6.07647 − 2.03534I −1.49342 + 0.25635I

u = 0.548294 − 0.475497I

−6.07647 + 2.03534I −1.49342 − 0.25635I

u = −0.553289 + 0.398678I

−2.61813 − 1.78595I 2.96437 + 4.13592I

u = −0.553289 − 0.398678I

−2.61813 + 1.78595I 2.96437 − 4.13592I

u = 0.108014 + 1.329890I

−3.47258 + 1.99659I 3.63851 − 3.32884I

u = 0.108014 − 1.329890I

−3.47258 − 1.99659I 3.63851 + 3.32884I

u = −0.165337 + 1.349130I

−5.18486 − 5.72137I 0. + 8.45786I

u = −0.165337 − 1.349130I

−5.18486 + 5.72137I 0. − 8.45786I

u = −0.070878 + 1.410250I

−7.16634 − 0.25397I 0

u = −0.070878 − 1.410250I

−7.16634 + 0.25397I 0

u = −0.529018 + 0.191801I

−0.35654 − 3.20662I 5.93778 + 9.20174I

u = −0.529018 − 0.191801I

−0.35654 + 3.20662I 5.93778 − 9.20174I

u = −0.19412 + 1.44071I

−8.51769 − 4.51489I 0

u = −0.19412 − 1.44071I

−8.51769 + 4.51489I 0

u = 0.21879 + 1.44502I

−11.6645 + 8.9374I 0

u = 0.21879 − 1.44502I

−11.6645 − 8.9374I 0

u = 0.18046 + 1.46649I

−12.33810 + 0.59580I 0

u = 0.18046 − 1.46649I

−12.33810 − 0.59580I 0

u = 0.24198 + 1.50771I

−19.1586 + 5.7629I 0

u = 0.24198 − 1.50771I

−19.1586 − 5.7629I 0

5

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = −0.24749 + 1.50794I

16.4216 − 10.8522I 0

u = −0.24749 − 1.50794I

16.4216 + 10.8522I 0

u = −0.23899 + 1.51269I

16.2818 − 0.7569I 0

u = −0.23899 − 1.51269I

16.2818 + 0.7569I 0

u = 0.455694 + 0.048977I

0.826554 + 0.063442I 12.58366 − 0.84901I

u = 0.455694 − 0.048977I

0.826554 − 0.063442I 12.58366 + 0.84901I

u = −0.209212 + 0.399902I

−1.53939 + 0.81265I −1.98721 − 0.48886I

u = −0.209212 − 0.399902I

−1.53939 − 0.81265I −1.98721 + 0.48886I

6

II. u-Polynomials

Crossings u-Polynomials at each crossing

c

1

u

38

+ 23u

37

+ ··· + 5u + 1

c

2

, c

5

u

38

+ u

37

+ ··· + u + 1

c

3

u

38

− u

37

+ ··· + 81u + 317

c

4

, c

9

, c

10

u

38

+ u

37

+ ··· + u + 1

c

6

, c

7

, c

8

c

11

, c

12

u

38

+ 3u

37

+ ··· + 15u + 3

7

III. Riley Polynomials

Crossings Riley Polynomials at each crossing

c

1

y

38

− 15y

37

+ ··· + 3y + 1

c

2

, c

5

y

38

− 23y

37

+ ··· − 5y + 1

c

3

y

38

+ 25y

37

+ ··· + 1416135y + 100489

c

4

, c

9

, c

10

y

38

+ 37y

37

+ ··· − 5y + 1

c

6

, c

7

, c

8

c

11

, c

12

y

38

+ 53y

37

+ ··· + 123y + 9

8