12a

0651

(K12a

0651

)

A knot diagram

Linearized knot diagam

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

Solving Sequence

2,8

7 3 1 9 6 10 4 12 5 11

, c

Ideals for irreducible components

of X

par

= hu

− u

+ ··· − 2u

− 1i

* 1 irreducible components of dim

= 0, with total 48 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

+ · · · − 2u

− 1i

(i) Arc colorings















+ u





+ u





−u

− u

+ 1

−u

− 2u

− 3u

− 2u

− u





+ 1





+ 3u

+ 6u

+ 7u

+ 6u

+ 4u

+ 2u

+ 1

+ 2u

+ 3u

+ 2u

− u





−u

− 6u

+ ··· − 18u

− 6u

−u

− 5u

+ ··· + 2u

+ u





+ 2u

+ 3u

+ 2u

− u

+ 3u

+ 6u

+ 7u

+ 6u

+ 4u

+ 2u

+ u





−u

− 5u

+ ··· + 2u

+ 1

−u

− 6u

+ ··· − 18u

− 6u





−u

− 8u

+ ··· + 18u

+ 6u

−u

+ u

+ ··· − 2u

− 1



(ii) Obstruction class = −1

(iii) Cusp Shapes = 4u

− 4u

+ ··· + 12u − 6

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

+ 17u

+ ··· + 4u + 1

, c

+ u

+ ··· − 2u

− 1

, c

− u

+ ··· − 2u − 1

, c

− 5u

+ ··· + 100u − 39

− 5u

+ ··· + 912u + 1305

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

+ 29y

+ ··· − 16y + 1

, c

+ 17y

+ ··· + 4y + 1

, c

− 63y

+ ··· + 4y + 1

, c

+ 37y

+ ··· + 24632y + 1521

− 23y

+ ··· − 23246424y + 1703025

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.802127 + 0.589214I

−13.2341 − 6.6512I −8.69292 + 2.70499I

u = 0.802127 − 0.589214I

−13.2341 + 6.6512I −8.69292 − 2.70499I

u = −0.780450 + 0.595412I

−3.45383 + 5.14659I −7.86923 − 4.15340I

u = −0.780450 − 0.595412I

−3.45383 − 5.14659I −7.86923 + 4.15340I

u = −0.306787 + 0.928044I

−13.29560 − 2.74578I −13.24399 + 4.02587I

u = −0.306787 − 0.928044I

−13.29560 + 2.74578I −13.24399 − 4.02587I

u = 0.744340 + 0.609755I

0.47988 − 2.41400I −2.77620 + 3.95017I

u = 0.744340 − 0.609755I

0.47988 + 2.41400I −2.77620 − 3.95017I

u = −0.709694 + 0.805377I

1.43993 − 0.10326I −4.11691 − 1.57301I

u = −0.709694 − 0.805377I

1.43993 + 0.10326I −4.11691 + 1.57301I

u = −0.019095 + 1.077630I

−5.06998 − 1.60211I −10.45738 + 4.05120I

u = −0.019095 − 1.077630I

−5.06998 + 1.60211I −10.45738 − 4.05120I

u = 0.750182 + 0.779791I

−7.19201 − 0.77835I −5.36224 + 0.06889I

u = 0.750182 − 0.779791I

−7.19201 + 0.77835I −5.36224 − 0.06889I

u = −0.669363 + 0.604587I

0.001527 − 0.587302I −4.68221 + 4.09309I

u = −0.669363 − 0.604587I

0.001527 + 0.587302I −4.68221 − 4.09309I

u = 0.040819 + 1.103530I

−9.34090 + 4.19623I −14.8023 − 4.2142I

u = 0.040819 − 1.103530I

−9.34090 − 4.19623I −14.8023 + 4.2142I

u = 0.701243 + 0.856750I

3.68589 + 2.68723I 1.90848 − 3.59326I

u = 0.701243 − 0.856750I

3.68589 − 2.68723I 1.90848 + 3.59326I

u = 0.303851 + 0.826787I

−3.75546 + 2.27659I −12.89646 − 5.30128I

u = 0.303851 − 0.826787I

−3.75546 − 2.27659I −12.89646 + 5.30128I

u = −0.050388 + 1.121400I

−19.3092 − 5.5995I −15.3152 + 3.0524I

u = −0.050388 − 1.121400I

−19.3092 + 5.5995I −15.3152 − 3.0524I

u = −0.701027 + 0.900492I

1.15320 − 5.29793I −5.03627 + 7.68449I

u = −0.701027 − 0.900492I

1.15320 + 5.29793I −5.03627 − 7.68449I

u = −0.715058 + 0.438137I

−14.1380 − 3.7995I −9.38326 + 2.79474I

u = −0.715058 − 0.438137I

−14.1380 + 3.7995I −9.38326 − 2.79474I

u = 0.719743 + 0.928582I

−7.64175 + 6.35454I −6.48748 − 5.77861I

u = 0.719743 − 0.928582I

−7.64175 − 6.35454I −6.48748 + 5.77861I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.672923 + 0.473750I

−4.26296 + 2.63953I −9.04168 − 4.04694I

u = 0.672923 − 0.473750I

−4.26296 − 2.63953I −9.04168 + 4.04694I

u = 0.620090 + 1.027290I

−5.75948 + 2.34942I −11.55550 − 1.52820I

u = 0.620090 − 1.027290I

−5.75948 − 2.34942I −11.55550 + 1.52820I

u = −0.648633 + 1.012460I

−1.18407 − 4.57916I −6.64611 + 1.38024I

u = −0.648633 − 1.012460I

−1.18407 + 4.57916I −6.64611 − 1.38024I

u = −0.608868 + 1.044010I

−15.8277 − 1.2103I −12.22073 + 2.35699I

u = −0.608868 − 1.044010I

−15.8277 + 1.2103I −12.22073 − 2.35699I

u = 0.668938 + 1.023950I

−0.74329 + 7.81387I −4.00000 − 8.53366I

u = 0.668938 − 1.023950I

−0.74329 − 7.81387I −4.00000 + 8.53366I

u = −0.676813 + 1.038570I

−4.76998 − 10.66020I −9.85701 + 8.71110I

u = −0.676813 − 1.038570I

−4.76998 + 10.66020I −9.85701 − 8.71110I

u = 0.681817 + 1.047990I

−14.6043 + 12.2368I −10.70547 − 7.24531I

u = 0.681817 − 1.047990I

−14.6043 − 12.2368I −10.70547 + 7.24531I

u = −0.545430

−10.6248 −6.00350

u = −0.257194 + 0.480005I

−0.181190 − 0.868139I −4.26608 + 7.69273I

u = −0.257194 − 0.480005I

−0.181190 + 0.868139I −4.26608 − 7.69273I

u = 0.420030

−1.58694 −4.88980

II. u-Polynomials

Crossings u-Polynomials at each crossing

, c

+ 17u

+ ··· + 4u + 1

, c

+ u

+ ··· − 2u

− 1

, c

− u

+ ··· − 2u − 1

, c

− 5u

+ ··· + 100u − 39

− 5u

+ ··· + 912u + 1305

III. Riley Polynomials

Crossings Riley Polynomials at each crossing

, c

+ 29y

+ ··· − 16y + 1

, c

+ 17y

+ ··· + 4y + 1

, c

− 63y

+ ··· + 4y + 1

, c

+ 37y

+ ··· + 24632y + 1521

− 23y

+ ··· − 23246424y + 1703025