11a

121

(K11a

121

)

A knot diagram

1

Linearized knot diagam

6 1 10 8 2 5 3 11 4 9 7

Solving Sequence

2,6

1 3 5 7 8 4 11 9 10

c

1

c

2

c

5

c

6

c

7

c

4

c

11

c

8

c

10

c

3

, c

9

Ideals for irreducible components

2

of X

par

I

u

1

= hu

11

+ 2u

9

+ 4u

7

+ 4u

5

− u

4

+ 3u

3

− u

2

+ 2u − 1i

I

u

2

= hu

48

− u

47

+ ··· + 2u + 1i

* 2 irreducible components of dim

C

= 0, with total 59 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

11

+ 2u

9

+ 4u

7

+ 4u

5

− u

4

+ 3u

3

− u

2

+ 2u − 1i

(i) Arc colorings

a

2

=



1

0



a

6

=



0

u



a

1

=



1

u

2



a

3

=



u

2

+ 1

u

4



a

5

=



−u

u



a

7

=



−u

3

u

3

+ u



a

8

=



u

9

+ 2u

7

+ 3u

5

+ 2u

3

+ u

−u

9

− 2u

7

− 3u

5

+ u

4

− 2u

3

+ u

2

− u + 1



a

4

=



u

8

− u

7

+ u

6

− 2u

5

+ 2u

4

− 2u

3

+ u

2

− 2u

−u

9

− u

8

− u

7

− u

6

− u

5

− 2u

4

− u

2

+ u



a

11

=



−u

8

− u

6

− u

4

+ 1

u

8

+ 2u

6

+ 2u

4

+ 2u

2



a

9

=



u

10

+ u

9

+ u

8

+ 2u

7

+ u

6

+ 3u

5

+ 2u

3

− u

2

+ u

−u

10

− u

9

− 2u

8

− 2u

7

− 2u

6

− 3u

5

− u

4

− 2u

3

+ u

2

− u + 1



a

10

=



u

10

+ 2u

8

+ u

7

+ 3u

6

+ u

5

+ 2u

4

+ u

3

+ u

2

+ u

−u

8

− u

7

− u

6

− u

5

− u

4

− u

3

− u + 1



a

10

=



u

10

+ 2u

8

+ u

7

+ 3u

6

+ u

5

+ 2u

4

+ u

3

+ u

2

+ u

−u

8

− u

7

− u

6

− u

5

− u

4

− u

3

− u + 1



(ii) Obstruction class = −1

(iii) Cusp Shapes = 4u

10

+ 4u

9

+ 4u

8

+ 8u

7

+ 12u

6

+ 16u

5

+ 8u

4

+ 8u

3

+ 4u

2

+ 8u + 6

2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

, c

3

, c

5

c

9

u

11

+ 2u

9

+ 4u

7

+ 4u

5

− u

4

+ 3u

3

− u

2

+ 2u − 1

c

2

, c

6

, c

8

c

10

u

11

+ 4u

10

+ ··· + 2u − 1

c

4

, c

11

u

11

+ 2u

9

− 2u

8

+ 10u

7

+ 12u

5

− 3u

4

+ 5u

3

− u

2

− 1

c

7

u

11

− 7u

10

+ ··· + 28u − 8

3

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

, c

3

, c

5

c

9

y

11

+ 4y

10

+ ··· + 2y −1

c

2

, c

6

, c

8

c

10

y

11

+ 8y

10

+ ··· + 22y −1

c

4

, c

11

y

11

+ 4y

10

+ ··· − 2y −1

c

7

y

11

− 3y

10

+ ··· + 48y −64

4

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = −0.111009 + 1.030810I

−5.93919 − 3.55367I −6.35449 + 4.86751I

u = −0.111009 − 1.030810I

−5.93919 + 3.55367I −6.35449 − 4.86751I

u = 0.594105 + 0.723647I

1.48764 + 1.96750I 4.49213 − 3.23948I

u = 0.594105 − 0.723647I

1.48764 − 1.96750I 4.49213 + 3.23948I

u = −0.817015 + 0.707633I

6.68078 + 3.13136I 8.76083 − 0.56604I

u = −0.817015 − 0.707633I

6.68078 − 3.13136I 8.76083 + 0.56604I

u = −0.617277 + 0.966546I

−0.07920 − 7.68222I 0.97285 + 8.49443I

u = −0.617277 − 0.966546I

−0.07920 + 7.68222I 0.97285 − 8.49443I

u = 0.729012 + 1.011350I

4.8176 + 14.7555I 5.24582 − 10.31160I

u = 0.729012 − 1.011350I

4.8176 − 14.7555I 5.24582 + 10.31160I

u = 0.444369

0.869046 11.7660

5

II. I

u

2

= hu

48

− u

47

+ · · · + 2u + 1i

(i) Arc colorings

a

2

=



1

0



a

6

=



0

u



a

1

=



1

u

2



a

3

=



u

2

+ 1

u

4



a

5

=



−u

u



a

7

=



−u

3

u

3

+ u



a

8

=



u

9

+ 2u

7

+ 3u

5

+ 2u

3

+ u

u

11

+ u

9

+ 2u

7

+ u

5

+ u

3

+ u



a

4

=



−u

21

− 4u

19

+ ··· − 2u

3

− u

−u

23

− 3u

21

+ ··· − 2u

3

+ u



a

11

=



−u

8

− u

6

− u

4

+ 1

u

8

+ 2u

6

+ 2u

4

+ 2u

2



a

9

=



−u

27

− 4u

25

+ ··· + 10u

5

+ 3u

3

u

27

+ 5u

25

+ ··· − u

3

+ u



a

10

=



−u

46

− 7u

44

+ ··· − 4u

4

+ 1

u

46

+ 8u

44

+ ··· + 4u

4

+ u

2



a

10

=



−u

46

− 7u

44

+ ··· − 4u

4

+ 1

u

46

+ 8u

44

+ ··· + 4u

4

+ u

2



(ii) Obstruction class = −1

(iii) Cusp Shapes = 4u

45

+ 28u

43

+ 132u

41

+ 448u

39

+ 1224u

37

+ 2772u

35

+ 5348u

33

+

8916u

31

+ 12948u

29

−4u

28

+ 16456u

27

−20u

26

+ 18292u

25

−68u

24

+ 17704u

23

−164u

22

+

14776u

21

− 308u

20

+ 10428u

19

− 468u

18

+ 6020u

17

− 576u

16

+ 2644u

15

− 580u

14

+

720u

13

−468u

12

−288u

10

−88u

9

−124u

8

−4u

7

−24u

6

+ 36u

5

+ 8u

4

+ 24u

3

+ 4u

2

+ 4u + 2

6

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

, c

3

, c

5

c

9

u

48

− u

47

+ ··· + 2u + 1

c

2

, c

6

, c

8

c

10

u

48

+ 15u

47

+ ··· + 8u

3

+ 1

c

4

, c

11

u

48

+ 5u

47

+ ··· + 12u + 1

c

7

(u

24

+ 3u

23

+ ··· + 18u + 7)

2

7

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

, c

3

, c

5

c

9

y

48

+ 15y

47

+ ··· + 8y

3

+ 1

c

2

, c

6

, c

8

c

10

y

48

+ 35y

47

+ ··· + 88y

2

+ 1

c

4

, c

11

y

48

− 5y

47

+ ··· − 24y + 1

c

7

(y

24

− 9y

23

+ ··· − 212y + 49)

2

8

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

2

√

−1(vol +

√

−1CS) Cusp shape

u = −0.447030 + 0.894068I

0.85406 + 3.28062I 1.88284 − 1.76353I

u = −0.447030 − 0.894068I

0.85406 − 3.28062I 1.88284 + 1.76353I

u = −0.037970 + 1.018320I

−3.47428 + 2.08425I −3.81787 − 2.59078I

u = −0.037970 − 1.018320I

−3.47428 − 2.08425I −3.81787 + 2.59078I

u = 0.103335 + 0.964930I

−2.07060 + 1.71275I 0.95839 − 4.38827I

u = 0.103335 − 0.964930I

−2.07060 − 1.71275I 0.95839 + 4.38827I

u = 0.709249 + 0.753994I

1.54659 + 2.07802I 3.74247 − 4.14356I

u = 0.709249 − 0.753994I

1.54659 − 2.07802I 3.74247 + 4.14356I

u = 0.161802 + 1.028080I

0.15229 + 3.45771I 1.61918 − 3.33537I

u = 0.161802 − 1.028080I

0.15229 − 3.45771I 1.61918 + 3.33537I

u = 0.786969 + 0.691947I

0.15229 − 3.45771I 1.61918 + 3.33537I

u = 0.786969 − 0.691947I

0.15229 + 3.45771I 1.61918 − 3.33537I

u = −0.156596 + 1.043700I

−0.78809 − 9.12338I −0.18249 + 8.13527I

u = −0.156596 − 1.043700I

−0.78809 + 9.12338I −0.18249 − 8.13527I

u = −0.779513 + 0.728650I

3.78730 + 1.05884I 9.33375 − 1.03697I

u = −0.779513 − 0.728650I

3.78730 − 1.05884I 9.33375 + 1.03697I

u = 0.820160 + 0.698926I

5.77023 − 8.94227I 7.03302 + 5.48937I

u = 0.820160 − 0.698926I

5.77023 + 8.94227I 7.03302 − 5.48937I

u = −0.559504 + 0.928720I

−3.47428 − 2.08425I −3.81787 + 2.59078I

u = −0.559504 − 0.928720I

−3.47428 + 2.08425I −3.81787 − 2.59078I

u = 0.357761 + 0.828361I

1.54659 + 2.07802I 3.74247 − 4.14356I

u = 0.357761 − 0.828361I

1.54659 − 2.07802I 3.74247 + 4.14356I

u = −0.798379 + 0.782289I

7.98533 10.04300 + 0.I

u = −0.798379 − 0.782289I

7.98533 10.04300 + 0.I

u = 0.795531 + 0.794799I

7.45278 + 5.81585I 8.97012 − 5.48927I

u = 0.795531 − 0.794799I

7.45278 − 5.81585I 8.97012 + 5.48927I

u = 0.644764 + 0.924836I

0.94545 + 3.01303I 3.90717 − 2.47987I

u = 0.644764 − 0.924836I

0.94545 − 3.01303I 3.90717 + 2.47987I

u = 0.684868 + 0.970999I

0.85406 + 3.28062I 1.88284 − 1.76353I

u = 0.684868 − 0.970999I

0.85406 − 3.28062I 1.88284 + 1.76353I

9

Solutions to I

u

2

√

−1(vol +

√

−1CS) Cusp shape

u = 0.750786 + 0.945298I

6.98909 8.15485 + 0.I

u = 0.750786 − 0.945298I

6.98909 8.15485 + 0.I

u = −0.748039 + 0.955471I

7.45278 − 5.81585I 8.97012 + 5.48927I

u = −0.748039 − 0.955471I

7.45278 + 5.81585I 8.97012 − 5.48927I

u = −0.718495 + 0.983429I

3.01107 − 6.72706I 7.45449 + 6.34172I

u = −0.718495 − 0.983429I

3.01107 + 6.72706I 7.45449 − 6.34172I

u = 0.712082 + 1.003140I

−0.78809 + 9.12338I 0. − 8.13527I

u = 0.712082 − 1.003140I

−0.78809 − 9.12338I 0. + 8.13527I

u = −0.730704 + 1.006040I

5.77023 − 8.94227I 7.03302 + 5.48937I

u = −0.730704 − 1.006040I

5.77023 + 8.94227I 7.03302 − 5.48937I

u = −0.520871 + 0.529700I

0.94545 + 3.01303I 3.90717 − 2.47987I

u = −0.520871 − 0.529700I

0.94545 − 3.01303I 3.90717 + 2.47987I

u = −0.619099 + 0.144052I

3.01107 − 6.72706I 7.45449 + 6.34172I

u = −0.619099 − 0.144052I

3.01107 + 6.72706I 7.45449 − 6.34172I

u = 0.605322 + 0.114770I

3.78730 + 1.05884I 9.33375 − 1.03697I

u = 0.605322 − 0.114770I

3.78730 − 1.05884I 9.33375 + 1.03697I

u = −0.516429 + 0.228211I

−2.07060 − 1.71275I 0.95839 + 4.38827I

u = −0.516429 − 0.228211I

−2.07060 + 1.71275I 0.95839 − 4.38827I

10

III. u-Polynomials

Crossings u-Polynomials at each crossing

c

1

, c

3

, c

5

c

9

(u

11

+ 2u

9

+ ··· + 2u − 1)(u

48

− u

47

+ ··· + 2u + 1)

c

2

, c

6

, c

8

c

10

(u

11

+ 4u

10

+ ··· + 2u − 1)(u

48

+ 15u

47

+ ··· + 8u

3

+ 1)

c

4

, c

11

(u

11

+ 2u

9

− 2u

8

+ 10u

7

+ 12u

5

− 3u

4

+ 5u

3

− u

2

− 1)

· (u

48

+ 5u

47

+ ··· + 12u + 1)

c

7

(u

11

− 7u

10

+ ··· + 28u − 8)(u

24

+ 3u

23

+ ··· + 18u + 7)

2

11

IV. Riley Polynomials

Crossings Riley Polynomials at each crossing

c

1

, c

3

, c

5

c

9

(y

11

+ 4y

10

+ ··· + 2y −1)(y

48

+ 15y

47

+ ··· + 8y

3

+ 1)

c

2

, c

6

, c

8

c

10

(y

11

+ 8y

10

+ ··· + 22y −1)(y

48

+ 35y

47

+ ··· + 88y

2

+ 1)

c

4

, c

11

(y

11

+ 4y

10

+ ··· − 2y −1)(y

48

− 5y

47

+ ··· − 24y + 1)

c

7

(y

11

− 3y

10

+ ··· + 48y −64)(y

24

− 9y

23

+ ··· − 212y + 49)

2

12