12a

1040

(K12a

1040

)

A knot diagram

Linearized knot diagam

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

Solving Sequence

2,7

3 8 4 9 1 10 6 11 5 12

, c

Ideals for irreducible components

of X

par

= hu

− u

+ ··· + u + 1i

* 1 irreducible components of dim

= 0, with total 57 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.

I. I

= hu

− u

+ · · · + u + 1i

(i) Arc colorings











−u





−u

+ u





−u

+ 1

− 2u





−u

+ 2u

−u

+ u





− 3u

+ 2u

+ 1

−u

+ 4u

− 4u





−u

+ 8u

− 25u

+ 36u

− 19u

− 4u

+ 2u

+ 3u

− 9u

+ 32u

− 55u

+ 43u

− 9u

− 4u

− u

+ u





− 4u

+ 4u

− 3u

+ 2u

+ u





−u

+ 16u

+ ··· + 2u

+ 3u

−u

+ 15u

+ ··· + 2u

+ u





−u

+ 25u

+ ··· + 2u

+ 1

− 26u

+ ··· + 4u

− 2u





− 13u

+ ··· + 5u

+ 1

−u

+ 14u

+ ··· − 4u

+ u



(ii) Obstruction class = −1

(iii) Cusp Shapes = −4u

+ 104u

+ ··· + 20u + 2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

− 9u

+ ··· + 417u − 41

, c

+ u

+ ··· + u − 1

, c

+ u

+ ··· − u − 1

− 3u

+ ··· − 313u + 175

, c

+ 11u

+ ··· + 57u + 11

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

+ 43y

+ ··· − 48987y −1681

, c

− 53y

+ ··· − 7y −1

, c

+ 63y

+ ··· − 7y −1

− 17y

+ ··· + 297469y −30625

, c

+ 27y

+ ··· − 3483y −121

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.167470 + 0.169882I

5.94879 − 1.26768I 0

u = 1.167470 − 0.169882I

5.94879 + 1.26768I 0

u = −0.380989 + 0.687075I

7.59135 − 9.78879I 4.20807 + 7.63690I

u = −0.380989 − 0.687075I

7.59135 + 9.78879I 4.20807 − 7.63690I

u = −1.210720 + 0.186692I

−0.388499 − 1.147720I 0

u = −1.210720 − 0.186692I

−0.388499 + 1.147720I 0

u = −0.450772 + 0.625585I

12.14170 − 2.06019I 8.03202 + 3.36390I

u = −0.450772 − 0.625585I

12.14170 + 2.06019I 8.03202 − 3.36390I

u = 0.370067 + 0.674356I

0.31418 + 7.17616I 0.93396 − 9.10668I

u = 0.370067 − 0.674356I

0.31418 − 7.17616I 0.93396 + 9.10668I

u = −0.535939 + 0.537357I

8.22131 + 5.67967I 5.83026 − 1.65476I

u = −0.535939 − 0.537357I

8.22131 − 5.67967I 5.83026 + 1.65476I

u = 1.236620 + 0.206975I

−0.13889 + 5.01254I 0

u = 1.236620 − 0.206975I

−0.13889 − 5.01254I 0

u = −0.355064 + 0.654949I

−0.47604 − 3.30732I −1.43106 + 3.04352I

u = −0.355064 − 0.654949I

−0.47604 + 3.30732I −1.43106 − 3.04352I

u = 0.418277 + 0.595875I

3.97873 + 1.92695I 7.08631 − 3.98477I

u = 0.418277 − 0.595875I

3.97873 − 1.92695I 7.08631 + 3.98477I

u = 0.514622 + 0.512995I

0.95022 − 3.20263I 2.71277 + 3.09003I

u = 0.514622 − 0.512995I

0.95022 + 3.20263I 2.71277 − 3.09003I

u = −1.255720 + 0.225833I

6.68945 − 7.58268I 0

u = −1.255720 − 0.225833I

6.68945 + 7.58268I 0

u = −1.27874

2.94486 0

u = 0.301202 + 0.630196I

5.12502 + 1.19979I 1.84526 − 3.54784I

u = 0.301202 − 0.630196I

5.12502 − 1.19979I 1.84526 + 3.54784I

u = −0.464588 + 0.473428I

0.149387 − 0.437986I 0.20836 + 3.87750I

u = −0.464588 − 0.473428I

0.149387 + 0.437986I 0.20836 − 3.87750I

u = 1.336280 + 0.067950I

4.76158 + 2.12463I 0

u = 1.336280 − 0.067950I

4.76158 − 2.12463I 0

u = 0.053954 + 0.654719I

2.66786 + 4.37051I −1.69929 − 3.89268I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.053954 − 0.654719I

2.66786 − 4.37051I −1.69929 + 3.89268I

u = −0.019054 + 0.641634I

−3.95983 − 1.90551I −5.97209 + 4.06985I

u = −0.019054 − 0.641634I

−3.95983 + 1.90551I −5.97209 − 4.06985I

u = −1.395500 + 0.073443I

12.03160 − 3.33838I 0

u = −1.395500 − 0.073443I

12.03160 + 3.33838I 0

u = 0.521676 + 0.299528I

6.18669 + 2.12511I 5.30374 − 3.18757I

u = 0.521676 − 0.299528I

6.18669 − 2.12511I 5.30374 + 3.18757I

u = −1.42263 + 0.23603I

10.65770 − 4.35539I 0

u = −1.42263 − 0.23603I

10.65770 + 4.35539I 0

u = 1.44389 + 0.19016I

6.16952 + 2.93600I 0

u = 1.44389 − 0.19016I

6.16952 − 2.93600I 0

u = 1.44231 + 0.24847I

5.29940 + 6.61308I 0

u = 1.44231 − 0.24847I

5.29940 − 6.61308I 0

u = −1.45405 + 0.22055I

9.99378 − 4.92353I 0

u = −1.45405 − 0.22055I

9.99378 + 4.92353I 0

u = −1.46020 + 0.18074I

7.24551 + 0.69473I 0

u = −1.46020 − 0.18074I

7.24551 − 0.69473I 0

u = −1.44938 + 0.25463I

6.16341 − 10.57050I 0

u = −1.44938 − 0.25463I

6.16341 + 10.57050I 0

u = 1.45510 + 0.25844I

13.4982 + 13.2410I 0

u = 1.45510 − 0.25844I

13.4982 − 13.2410I 0

u = 1.47223 + 0.17915I

14.6669 − 3.1156I 0

u = 1.47223 − 0.17915I

14.6669 + 3.1156I 0

u = 1.46992 + 0.22438I

18.3360 + 5.1622I 0

u = 1.46992 − 0.22438I

18.3360 − 5.1622I 0

u = −0.209648 + 0.330630I

0.018322 − 0.795288I 0.54519 + 8.56502I

u = −0.209648 − 0.330630I

0.018322 + 0.795288I 0.54519 − 8.56502I

II. u-Polynomials

Crossings u-Polynomials at each crossing

, c

− 9u

+ ··· + 417u − 41

, c

+ u

+ ··· + u − 1

, c

+ u

+ ··· − u − 1

− 3u

+ ··· − 313u + 175

, c

+ 11u

+ ··· + 57u + 11

III. Riley Polynomials

Crossings Riley Polynomials at each crossing

, c

+ 43y

+ ··· − 48987y −1681

, c

− 53y

+ ··· − 7y −1

, c

+ 63y

+ ··· − 7y −1

− 17y

+ ··· + 297469y −30625

, c

+ 27y

+ ··· − 3483y −121