12a

0724

(K12a

0724

)

A knot diagram

Linearized knot diagam

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

Solving Sequence

2,9

8 3 4 10 5 1 7 11 12 6

, c

Ideals for irreducible components

of X

par

= hu

− u

+ ··· − u − 1i

* 1 irreducible components of dim

= 0, with total 53 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

− u

+ 1

+ 2u

+ u





+ 2u

+ u

− 2u

− u

−u

− 3u

+ u





+ u





−u

− u

+ 1

−u

− 2u





−u

− 5u

− 11u

− 10u

+ 2u

+ 13u

+ 9u

− 2u

− 5u

− u

+ 1

−u

− 6u

− 17u

− 26u

− 20u

+ 13u

+ 10u

+ 3u

+ 2u

+ u





+ 6u

+ ··· + 6u

+ 2u

−u

− 7u

+ ··· − 3u

+ u





+ 14u

+ ··· − u

− 2u

− u

+ ··· + 2u + 1



(ii) Obstruction class = −1

(iii) Cusp Shapes = 4u

− 4u

+ ··· − 8u − 14

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

+ 31u

+ ··· + 3u − 1

, c

− u

+ ··· − u − 1

, c

+ u

+ ··· + 17u − 5

, c

− u

+ ··· − 3u − 1

, c

+ 3u

+ ··· − 15u − 3

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

− 17y

+ ··· + 35y −1

, c

+ 31y

+ ··· + 3y −1

, c

− 65y

+ ··· + 899y −25

, c

− 45y

+ ··· + 3y −1

, c

+ 23y

+ ··· + 39y −9

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.128755 + 1.019230I

−4.90434 − 2.79376I −17.4626 + 3.5787I

u = −0.128755 − 1.019230I

−4.90434 + 2.79376I −17.4626 − 3.5787I

u = −0.911842

−15.0851 −15.7790

u = 0.452670 + 0.785816I

−0.74858 + 5.61733I −7.84958 − 7.79371I

u = 0.452670 − 0.785816I

−0.74858 − 5.61733I −7.84958 + 7.79371I

u = 0.904077 + 0.035348I

−10.76820 − 8.15829I −12.92275 + 4.70754I

u = 0.904077 − 0.035348I

−10.76820 + 8.15829I −12.92275 − 4.70754I

u = −0.894263 + 0.030410I

−5.73332 + 4.23818I −8.49578 − 3.55105I

u = −0.894263 − 0.030410I

−5.73332 − 4.23818I −8.49578 + 3.55105I

u = −0.435840 + 1.018520I

−3.18288 − 2.63277I −11.73208 + 4.34581I

u = −0.435840 − 1.018520I

−3.18288 + 2.63277I −11.73208 − 4.34581I

u = 0.270662 + 1.080700I

−1.60759 + 0.28866I −11.63603 + 0.60703I

u = 0.270662 − 1.080700I

−1.60759 − 0.28866I −11.63603 − 0.60703I

u = 0.885161 + 0.012504I

−7.93829 − 0.20732I −11.52979 − 0.97702I

u = 0.885161 − 0.012504I

−7.93829 + 0.20732I −11.52979 + 0.97702I

u = −0.366265 + 1.058630I

−3.39452 − 3.18652I −15.1026 + 5.9997I

u = −0.366265 − 1.058630I

−3.39452 + 3.18652I −15.1026 − 5.9997I

u = −0.438529 + 0.736447I

3.30946 − 1.89439I −2.29810 + 4.47995I

u = −0.438529 − 0.736447I

3.30946 + 1.89439I −2.29810 − 4.47995I

u = 0.459270 + 1.056820I

−0.23945 + 6.31415I −8.00000 − 7.97292I

u = 0.459270 − 1.056820I

−0.23945 − 6.31415I −8.00000 + 7.97292I

u = −0.271764 + 1.127110I

−6.33973 + 3.10223I −16.8942 − 2.0365I

u = −0.271764 − 1.127110I

−6.33973 − 3.10223I −16.8942 + 2.0365I

u = −0.471846 + 1.075850I

−4.85947 − 10.15110I −13.4245 + 9.4204I

u = −0.471846 − 1.075850I

−4.85947 + 10.15110I −13.4245 − 9.4204I

u = 0.147653 + 0.799603I

−0.621747 + 0.938340I −10.16569 − 6.80292I

u = 0.147653 − 0.799603I

−0.621747 − 0.938340I −10.16569 + 6.80292I

u = 0.443085 + 0.672743I

−0.43986 − 1.77287I −6.55805 − 0.17659I

u = 0.443085 − 0.672743I

−0.43986 + 1.77287I −6.55805 + 0.17659I

u = 0.386940 + 1.130380I

−9.24218 + 3.74726I −18.6066 + 0.I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.386940 − 1.130380I

−9.24218 − 3.74726I −18.6066 + 0.I

u = −0.626369 + 0.230684I

−2.49578 + 5.92364I −10.03468 − 5.69400I

u = −0.626369 − 0.230684I

−2.49578 − 5.92364I −10.03468 + 5.69400I

u = 0.461426 + 1.259080I

−11.80210 + 4.57211I 0

u = 0.461426 − 1.259080I

−11.80210 − 4.57211I 0

u = 0.474991 + 1.254660I

−11.70120 + 5.05761I 0

u = 0.474991 − 1.254660I

−11.70120 − 5.05761I 0

u = −0.452029 + 1.266230I

−9.69650 − 0.52013I 0

u = −0.452029 − 1.266230I

−9.69650 + 0.52013I 0

u = −0.485137 + 1.256070I

−9.45189 − 9.16998I 0

u = −0.485137 − 1.256070I

−9.45189 + 9.16998I 0

u = 0.450332 + 1.273070I

−14.7839 − 3.3745I 0

u = 0.450332 − 1.273070I

−14.7839 + 3.3745I 0

u = 0.489645 + 1.259800I

−14.4913 + 13.1415I 0

u = 0.489645 − 1.259800I

−14.4913 − 13.1415I 0

u = 0.647347

−6.05533 −14.6560

u = −0.472487 + 1.271320I

−18.9745 − 4.9215I 0

u = −0.472487 − 1.271320I

−18.9745 + 4.9215I 0

u = 0.573524 + 0.250742I

1.98282 − 2.24507I −4.39655 + 3.93832I

u = 0.573524 − 0.250742I

1.98282 + 2.24507I −4.39655 − 3.93832I

u = −0.505614 + 0.326260I

−1.29579 − 1.22009I −7.56412 + 0.50390I

u = −0.505614 − 0.326260I

−1.29579 + 1.22009I −7.56412 − 0.50390I

u = −0.436579

−0.780224 −12.8270

II. u-Polynomials

Crossings u-Polynomials at each crossing

+ 31u

+ ··· + 3u − 1

, c

− u

+ ··· − u − 1

, c

+ u

+ ··· + 17u − 5

, c

− u

+ ··· − 3u − 1

, c

+ 3u

+ ··· − 15u − 3

III. Riley Polynomials

Crossings Riley Polynomials at each crossing

− 17y

+ ··· + 35y −1

, c

+ 31y

+ ··· + 3y −1

, c

− 65y

+ ··· + 899y −25

, c

− 45y

+ ··· + 3y −1

, c

+ 23y

+ ··· + 39y −9