12n

0340

(K12n

0340

)

A knot diagram

1

Linearized knot diagam

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

Solving Sequence

4,7

8 5

9,11

12 3 6 2 1 10

c

7

c

4

c

8

c

11

c

3

c

6

c

2

c

1

c

10

c

5

, c

9

, c

12

Ideals for irreducible components

2

of X

par

I

u

1

= h−62822499u

16

+ 98950048u

15

+ ··· + 179809420b + 1255421292,

75505587u

16

− 95682099u

15

+ ··· + 179809420a − 2254628556, u

17

− u

16

+ ··· − 40u − 8i

I

u

2

= h2a

2

+ 2au + 5b + 4a + 1, 4a

3

+ 4a

2

− 2au + 6a − 7u + 8, u

2

− 2i

I

v

1

= ha, b + v + 1, v

3

+ 2v

2

+ v + 1i

* 3 irreducible components of dim

C

= 0, with total 26 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

= h−6.28 × 10

7

u

16

+ 9.90 × 10

7

u

15

+ · · · + 1.80 × 10

8

b + 1.26 × 10

9

, 7.55 ×

10

7

u

16

−9.57×10

7

u

15

+· · ·+1.80×10

8

a−2.25×10

9

, u

17

−u

16

+· · ·−40u −8i

(i) Arc colorings

a

4

=



0

u



a

7

=



1

0



a

8

=



1

−u

2



a

5

=



u

−u

3

+ u



a

9

=



−u

2

+ 1

u

4

− 2u

2



a

11

=



−0.419920u

16

+ 0.532131u

15

+ ··· + 20.6991u + 12.5390

0.349384u

16

− 0.550305u

15

+ ··· − 19.0383u − 6.98196



a

12

=



−0.769304u

16

+ 1.08244u

15

+ ··· + 39.7373u + 19.5209

0.349384u

16

− 0.550305u

15

+ ··· − 19.0383u − 6.98196



a

3

=



−u

u



a

6

=



−0.706889u

16

+ 0.968606u

15

+ ··· + 35.6654u + 16.9023

−0.0874591u

16

+ 0.0795210u

15

+ ··· + 3.47438u + 1.11299



a

2

=



0.706889u

16

− 0.968606u

15

+ ··· − 35.6654u − 16.9023

−0.159634u

16

+ 0.215306u

15

+ ··· + 8.28792u + 3.20672



a

1

=



0.796542u

16

− 1.07340u

15

+ ··· − 39.5291u − 18.5507

−0.249287u

16

+ 0.320105u

15

+ ··· + 12.1516u + 4.85508



a

10

=



−0.267792u

16

+ 0.361424u

15

+ ··· + 13.1869u + 7.51366

0.153138u

16

− 0.238805u

15

+ ··· − 8.95604u − 3.24946



(ii) Obstruction class = −1

(iii) Cusp Shapes = −

54399547

25687060

u

16

+

11504827

3669580

u

15

+ ··· +

93333338

917395

u +

275633814

6421765

2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

u

17

− 4u

16

+ ··· + 3757u + 529

c

2

, c

5

u

17

+ 4u

16

+ ··· − 59u + 23

c

3

, c

4

, c

7

c

8

u

17

− u

16

+ ··· − 40u − 8

c

6

, c

11

u

17

− 2u

16

+ ··· − 4u + 1

c

9

u

17

+ 2u

16

+ ··· − 284u + 1429

c

10

, c

12

u

17

+ 2u

16

+ ··· + 10u + 1

3

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

y

17

+ 60y

16

+ ··· + 3317101y −279841

c

2

, c

5

y

17

+ 4y

16

+ ··· + 3757y −529

c

3

, c

4

, c

7

c

8

y

17

− 31y

16

+ ··· + 960y −64

c

6

, c

11

y

17

− 2y

16

+ ··· + 10y −1

c

9

y

17

+ 102y

16

+ ··· + 30338302y −2042041

c

10

, c

12

y

17

+ 30y

16

+ ··· + 34y −1

4

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = 1.030470 + 0.189629I

a = −0.224345 − 0.523213I

b = −0.453303 + 0.618424I

2.71496 + 0.03038I 1.85613 − 0.36758I

u = 1.030470 − 0.189629I

a = −0.224345 + 0.523213I

b = −0.453303 − 0.618424I

2.71496 − 0.03038I 1.85613 + 0.36758I

u = −0.761878 + 0.176219I

a = −0.973738 + 0.882302I

b = −0.880524 − 0.587541I

1.72734 − 4.32421I −0.54590 + 7.81400I

u = −0.761878 − 0.176219I

a = −0.973738 − 0.882302I

b = −0.880524 + 0.587541I

1.72734 + 4.32421I −0.54590 − 7.81400I

u = 1.35959

a = −0.625953

b = −0.396497

3.15281 3.23020

u = −0.013551 + 0.593749I

a = 0.794033 − 0.406646I

b = 0.490534 − 0.506411I

−0.43270 + 1.37617I −3.71871 − 4.10562I

u = −0.013551 − 0.593749I

a = 0.794033 + 0.406646I

b = 0.490534 + 0.506411I

−0.43270 − 1.37617I −3.71871 + 4.10562I

u = −0.456807

a = 1.47926

b = 0.882527

−1.65919 −3.40410

u = −0.340015

a = 4.30114

b = −0.599895

−2.41310 6.57470

u = 1.70987 + 0.34907I

a = −0.035901 − 0.854639I

b = 1.105810 + 0.797473I

10.32630 − 2.94049I 0.85532 + 2.11383I

5

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = 1.70987 − 0.34907I

a = −0.035901 + 0.854639I

b = 1.105810 − 0.797473I

10.32630 + 2.94049I 0.85532 − 2.11383I

u = −1.64126 + 0.59755I

a = 0.137352 − 1.120570I

b = 0.823579 + 1.043060I

11.40790 − 3.91728I 1.42724 + 2.75158I

u = −1.64126 − 0.59755I

a = 0.137352 + 1.120570I

b = 0.823579 − 1.043060I

11.40790 + 3.91728I 1.42724 − 2.75158I

u = 1.96918 + 0.29196I

a = −0.119407 − 1.324750I

b = −1.10155 + 0.95457I

−15.4344 + 9.3275I 0.15944 − 3.93386I

u = 1.96918 − 0.29196I

a = −0.119407 + 1.324750I

b = −1.10155 − 0.95457I

−15.4344 − 9.3275I 0.15944 + 3.93386I

u = −2.07422 + 0.20650I

a = 0.344781 − 0.929300I

b = −0.92761 + 1.10685I

−14.7845 − 1.8072I 0.766090 − 0.113701I

u = −2.07422 − 0.20650I

a = 0.344781 + 0.929300I

b = −0.92761 − 1.10685I

−14.7845 + 1.8072I 0.766090 + 0.113701I

6

II. I

u

2

= h2a

2

+ 2au + 5b + 4a + 1, 4a

3

+ 4a

2

− 2au + 6a − 7u + 8, u

2

− 2i

(i) Arc colorings

a

4

=



0

u



a

7

=



1

0



a

8

=



1

−2



a

5

=



u

−u



a

9

=



−1

0



a

11

=



a

−

2

5

a

2

−

2

5

au −

4

5

a −

1

5



a

12

=



2

5

a

2

+

2

5

au +

9

5

a +

1

5

−

2

5

a

2

−

2

5

au −

4

5

a −

1

5



a

3

=



−u

u



a

6

=



2

5

a

2

u +

1

5

au + ··· −

2

5

a +

1

5

−

2

5

a

2

u −

1

5

au + ··· +

2

5

a −

1

5



a

2

=



2

5

a

2

u +

1

5

au + ··· −

2

5

a +

1

5

−

2

5

a

2

u −

1

5

au + ··· +

2

5

a −

1

5



a

1

=



2

5

a

2

u +

1

5

au + ··· −

2

5

a +

1

5

−

2

5

a

2

u −

1

5

au + ··· +

2

5

a −

1

5



a

10

=



3

5

a

2

u +

2

5

au + ··· +

3

5

a −

7

5

−

2

5

a

2

u −

3

5

au + ··· −

2

5

a +

3

5



(ii) Obstruction class = 1

(iii) Cusp Shapes = −

8

5

a

2

−

8

5

au −

16

5

a −

24

5

7

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

, c

5

(u − 1)

6

c

2

(u + 1)

6

c

3

, c

4

, c

7

c

8

(u

2

− 2)

3

c

6

(u

3

− u

2

+ 1)

2

c

9

, c

10

(u

3

− u

2

+ 2u − 1)

2

c

11

(u

3

+ u

2

− 1)

2

c

12

(u

3

+ u

2

+ 2u + 1)

2

8

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

, c

2

, c

5

(y −1)

6

c

3

, c

4

, c

7

c

8

(y −2)

6

c

6

, c

11

(y

3

− y

2

+ 2y −1)

2

c

9

, c

10

, c

12

(y

3

+ 3y

2

+ 2y −1)

2

9

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

2

√

−1(vol +

√

−1CS) Cusp shape

u = 1.41421

a = −0.683438 + 0.909550I

b = 0.877439 − 0.744862I

6.31400 + 2.82812I −0.49024 − 2.97945I

u = 1.41421

a = −0.683438 − 0.909550I

b = 0.877439 + 0.744862I

6.31400 − 2.82812I −0.49024 + 2.97945I

u = 1.41421

a = 0.366877

b = −0.754878

2.17641 −7.01950

u = −1.41421

a = −1.50656

b = −0.754878

2.17641 −7.01950

u = −1.41421

a = 0.25328 + 1.70473I

b = 0.877439 − 0.744862I

6.31400 + 2.82812I −0.49024 − 2.97945I

u = −1.41421

a = 0.25328 − 1.70473I

b = 0.877439 + 0.744862I

6.31400 − 2.82812I −0.49024 + 2.97945I

10

III. I

v

1

= ha, b + v + 1, v

3

+ 2v

2

+ v + 1i

(i) Arc colorings

a

4

=



v

0



a

7

=



1

0



a

8

=



1

0



a

5

=



v

0



a

9

=



1

0



a

11

=



0

−v − 1



a

12

=



v + 1

−v − 1



a

3

=



v

0



a

6

=



1

−v

2

− 2v − 1



a

2

=



v − 1

v

2

+ 2v + 1



a

1

=



−1

v

2

+ 2v + 1



a

10

=



−v

2

− 2v

v

2

+ v − 1



(ii) Obstruction class = 1

(iii) Cusp Shapes = −4v

2

+ 2v − 2

11

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

, c

2

(u − 1)

3

c

3

, c

4

, c

7

c

8

u

3

c

5

(u + 1)

3

c

6

u

3

+ u

2

− 1

c

9

, c

12

u

3

+ u

2

+ 2u + 1

c

10

u

3

− u

2

+ 2u − 1

c

11

u

3

− u

2

+ 1

12

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

, c

2

, c

5

(y − 1)

3

c

3

, c

4

, c

7

c

8

y

3

c

6

, c

11

y

3

− y

2

+ 2y − 1

c

9

, c

10

, c

12

y

3

+ 3y

2

+ 2y − 1

13

(vi) Complex Volumes and Cusp Shapes

Solutions to I

v

1

√

−1(vol +

√

−1CS) Cusp shape

v = −0.122561 + 0.744862I

a = 0

b = −0.877439 − 0.744862I

1.37919 − 2.82812I −0.08593 + 2.22005I

v = −0.122561 − 0.744862I

a = 0

b = −0.877439 + 0.744862I

1.37919 + 2.82812I −0.08593 − 2.22005I

v = −1.75488

a = 0

b = 0.754878

−2.75839 −17.8280

14

IV. u-Polynomials

Crossings u-Polynomials at each crossing

c

1

((u − 1)

9

)(u

17

− 4u

16

+ ··· + 3757u + 529)

c

2

((u − 1)

3

)(u + 1)

6

(u

17

+ 4u

16

+ ··· − 59u + 23)

c

3

, c

4

, c

7

c

8

u

3

(u

2

− 2)

3

(u

17

− u

16

+ ··· − 40u − 8)

c

5

((u − 1)

6

)(u + 1)

3

(u

17

+ 4u

16

+ ··· − 59u + 23)

c

6

((u

3

− u

2

+ 1)

2

)(u

3

+ u

2

− 1)(u

17

− 2u

16

+ ··· − 4u + 1)

c

9

((u

3

− u

2

+ 2u − 1)

2

)(u

3

+ u

2

+ 2u + 1)(u

17

+ 2u

16

+ ··· − 284u + 1429)

c

10

((u

3

− u

2

+ 2u − 1)

3

)(u

17

+ 2u

16

+ ··· + 10u + 1)

c

11

(u

3

− u

2

+ 1)(u

3

+ u

2

− 1)

2

(u

17

− 2u

16

+ ··· − 4u + 1)

c

12

((u

3

+ u

2

+ 2u + 1)

3

)(u

17

+ 2u

16

+ ··· + 10u + 1)

15

V. Riley Polynomials

Crossings Riley Polynomials at each crossing

c

1

((y − 1)

9

)(y

17

+ 60y

16

+ ··· + 3317101y − 279841)

c

2

, c

5

((y − 1)

9

)(y

17

+ 4y

16

+ ··· + 3757y − 529)

c

3

, c

4

, c

7

c

8

y

3

(y − 2)

6

(y

17

− 31y

16

+ ··· + 960y − 64)

c

6

, c

11

((y

3

− y

2

+ 2y − 1)

3

)(y

17

− 2y

16

+ ··· + 10y − 1)

c

9

((y

3

+ 3y

2

+ 2y − 1)

3

)(y

17

+ 102y

16

+ ··· + 3.03383 × 10

7

y − 2042041)

c

10

, c

12

((y

3

+ 3y

2

+ 2y − 1)

3

)(y

17

+ 30y

16

+ ··· + 34y − 1)

16