135

(K10n

)

A knot diagram

Linearized knot diagam

3 9 1 7 4 9 5 2 7 8

Solving Sequence

2,8

9 3

1,5

7 4 6 10

, c

Ideals for irreducible components

of X

par

= h−u

− u

+ ··· + b − 2u, u

+ u

+ ··· + a + 2, u

+ 2u

+ ··· + u − 1i

= hb + 1, a + u, u

− u

+ 1i

* 2 irreducible components of dim

= 0, with total 24 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.

= h−u

−u

+· · · + b− 2u, u

+· · · + a + 2, u

+2u

+· · · + u − 1i

(i) Arc colorings











−u





−u

+ u





−u

− u

+ u





−u

− u

+ ··· − u − 2

+ u

+ ··· + 4u

+ 2u





−u

− u

+ ··· + u + 3

−u

− u

+ ··· − 5u

− u





+ u

−u

+ u

− 2u

+ u





+ 3u

+ ··· + 2u − 4

+ u

+ ··· + 8u

+ 7u





−u

− u

+ u



(ii) Obstruction class = −1

(iii) Cusp Shapes

= −7u

− 10u

+ 19u

+ 42u

− 31u

− 99u

+ 18u

+ 172u

+ 44u

− 198u

−

125u

+ 168u

+ 183u

− 76u

− 166u

− 8u

+ 93u

+ 26u

− 41u

− 28u + 1

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

− 8u

+ ··· + 17u − 1

, c

− 2u

+ ··· + u + 1

, c

− 4u

+ ··· − 2u + 1

+ 6u

+ ··· − 2u + 1

, c

− u

+ ··· + 4u + 8

+ 2u

+ ··· + 3u + 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

+ 12y

+ ··· + 137y − 1

, c

− 8y

+ ··· + 17y − 1

, c

− 6y

+ ··· − 2y − 1

+ 22y

+ ··· + 66y − 1

, c

+ 21y

+ ··· − 176y − 64

− 24y

+ ··· + 17y − 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.567882 + 0.851579I

a = −0.521076 − 0.321393I

b = −1.047460 + 0.802568I

2.42497 + 4.94435I −1.24866 − 2.70559I

u = −0.567882 − 0.851579I

a = −0.521076 + 0.321393I

b = −1.047460 − 0.802568I

2.42497 − 4.94435I −1.24866 + 2.70559I

u = −0.848992 + 0.598239I

a = 1.09099 − 1.32571I

b = 1.272850 + 0.072825I

−3.02655 − 2.36605I −0.59037 + 2.67274I

u = −0.848992 − 0.598239I

a = 1.09099 + 1.32571I

b = 1.272850 − 0.072825I

−3.02655 + 2.36605I −0.59037 − 2.67274I

u = −0.427156 + 0.796867I

a = −0.517814 + 0.424717I

b = −0.770704 − 0.886977I

3.29052 − 1.36266I −0.18856 + 2.27516I

u = −0.427156 − 0.796867I

a = −0.517814 − 0.424717I

b = −0.770704 + 0.886977I

3.29052 + 1.36266I −0.18856 − 2.27516I

u = 0.707761 + 0.560391I

a = −0.427154 − 0.668417I

b = 0.837997 + 0.449477I

−1.83472 + 0.21101I −3.18710 − 0.57244I

u = 0.707761 − 0.560391I

a = −0.427154 + 0.668417I

b = 0.837997 − 0.449477I

−1.83472 − 0.21101I −3.18710 + 0.57244I

u = 0.951460 + 0.595395I

a = 0.13569 + 1.78932I

b = 0.666759 − 0.637720I

−1.06863 + 4.45806I −0.43689 − 6.14529I

u = 0.951460 − 0.595395I

a = 0.13569 − 1.78932I

b = 0.666759 + 0.637720I

−1.06863 − 4.45806I −0.43689 + 6.14529I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.853051 + 0.160221I

a = −0.985793 + 0.858266I

b = 0.040042 − 0.421446I

1.46918 − 0.34630I 5.96536 + 0.53554I

u = −0.853051 − 0.160221I

a = −0.985793 − 0.858266I

b = 0.040042 + 0.421446I

1.46918 + 0.34630I 5.96536 − 0.53554I

u = 1.169830 + 0.051846I

a = 0.79206 − 1.88563I

b = −0.960607 + 0.961815I

8.83595 + 3.51416I 4.91512 − 2.66916I

u = 1.169830 − 0.051846I

a = 0.79206 + 1.88563I

b = −0.960607 − 0.961815I

8.83595 − 3.51416I 4.91512 + 2.66916I

u = 0.882737 + 0.780973I

a = −0.878224 − 0.429656I

b = −0.622642 + 0.052532I

−3.85955 + 2.93752I 2.97600 − 3.43881I

u = 0.882737 − 0.780973I

a = −0.878224 + 0.429656I

b = −0.622642 − 0.052532I

−3.85955 − 2.93752I 2.97600 + 3.43881I

u = −1.083580 + 0.616829I

a = 1.133680 − 0.321228I

b = −0.721179 + 1.021470I

5.21503 − 3.89686I 2.41425 + 2.65107I

u = −1.083580 − 0.616829I

a = 1.133680 + 0.321228I

b = −0.721179 − 1.021470I

5.21503 + 3.89686I 2.41425 − 2.65107I

u = −1.075840 + 0.689537I

a = −0.86208 + 1.97593I

b = −1.117050 − 0.836949I

3.96319 − 10.68720I 0.56681 + 6.96141I

u = −1.075840 − 0.689537I

a = −0.86208 − 1.97593I

b = −1.117050 + 0.836949I

3.96319 + 10.68720I 0.56681 − 6.96141I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.289436

a = −1.92057

b = 0.843987

−1.20998 −9.37190

II. I

= hb + 1, a + u, u

− u

+ 1i

(i) Arc colorings











−u





−u

+ u + 1





−u

+ 1

−u





−u

−1





−u + 1

−1





−1





−u + 1

−1





−u



(ii) Obstruction class = 1

(iii) Cusp Shapes = 2u

− 7u − 2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

+ u

+ 2u + 1

+ u

− 1

, c

− u

+ 2u − 1

(u − 1)

, c

(u + 1)

, c

− u

+ 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

+ 3y

+ 2y − 1

, c

− y

+ 2y − 1

, c

(y − 1)

, c

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.877439 + 0.744862I

a = −0.877439 − 0.744862I

b = −1.00000

−4.66906 + 2.82812I −7.71191 − 2.59975I

u = 0.877439 − 0.744862I

a = −0.877439 + 0.744862I

b = −1.00000

−4.66906 − 2.82812I −7.71191 + 2.59975I

u = −0.754878

a = 0.754878

b = −1.00000

−0.531480 4.42380

III. u-Polynomials

Crossings u-Polynomials at each crossing

+ u

+ 2u + 1)(u

− 8u

+ ··· + 17u − 1)

+ u

− 1)(u

− 2u

+ ··· + u + 1)

− u

+ 2u − 1)(u

− 8u

+ ··· + 17u − 1)

((u − 1)

)(u

− 4u

+ ··· − 2u + 1)

((u + 1)

)(u

+ 6u

+ ··· − 2u + 1)

, c

− u

+ ··· + 4u + 8)

((u + 1)

)(u

− 4u

+ ··· − 2u + 1)

− u

+ 1)(u

− 2u

+ ··· + u + 1)

− u

+ 2u − 1)(u

+ 2u

+ ··· + 3u + 1)

IV. Riley Polynomials

Crossings Riley Polynomials at each crossing

, c

+ 3y

+ 2y − 1)(y

+ 12y

+ ··· + 137y − 1)

, c

− y

+ 2y − 1)(y

− 8y

+ ··· + 17y − 1)

, c

((y − 1)

)(y

− 6y

+ ··· − 2y − 1)

((y − 1)

)(y

+ 22y

+ ··· + 66y − 1)

, c

+ 21y

+ ··· − 176y − 64)

+ 3y

+ 2y − 1)(y

− 24y

+ ··· + 17y − 1)