12n

0046

(K12n

0046

)

A knot diagram

Linearized knot diagam

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

Solving Sequence

6,12 2,7

5 3 1 11 8 9 4 10

, c

Ideals for irreducible components

of X

par

= h−u

− 2u

+ ··· + 2b − 6u, u

+ 2u

+ ··· + 2a + 4, u

+ 3u

+ ··· + 6u + 1i

= h−au + b − u, u

a − u

+ a

+ 3au − 2u, u

− u

+ 3u

− 2u + 1i

* 2 irreducible components of dim

= 0, with total 36 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

h−u

−2u

+· · ·+2b −6u, u

+2u

+· · ·+2a +4, u

+3u

+· · ·+6u +1i

(i) Arc colorings











−

− u

+ ··· −

− 2

+ u

+ ··· + u

+ 3u









−

+ ··· − 15u − 2

−

− u

+ ··· − 3u − 1





+ ··· + 20u + 3

−

− 2u

+ ··· − 14u

− 2u





+ 4u

+ 5u

+ 7u

+ 2u

+ u





+ u





+ 1

+ 2u





−u

− 2u

+ u

+ 3u

+ u





−

+ ··· − 22u − 3

+ 2u

+ ··· + 14u

+ 2u





+ 2u

+ 3u

+ u



(ii) Obstruction class = −1

(iii) Cusp Shapes =

+ 5u

+ ··· + 21u +

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

+ 5u

+ ··· + 14u + 1

, c

+ 5u

+ ··· + 4u + 1

− 5u

+ ··· + 5562u + 1321

, c

+ u

+ ··· + 384u + 256

, c

− 3u

+ ··· − 6u + 1

− 3u

+ ··· − 2u + 1

+ 11u

+ ··· + 184u + 209

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

+ 41y

+ ··· + 14y + 1

, c

+ 5y

+ ··· + 14y + 1

+ 77y

+ ··· + 102223598y + 1745041

, c

+ 45y

+ ··· + 344064y + 65536

, c

+ 35y

+ ··· + 6y + 1

− 49y

+ ··· + 6y + 1

− 29y

+ ··· + 2808126y + 43681

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.546864 + 0.864620I

a = −1.78266 + 0.81365I

b = 0.938673 + 1.030660I

12.0428 + 7.8502I 0.54802 − 5.73315I

u = −0.546864 − 0.864620I

a = −1.78266 − 0.81365I

b = 0.938673 − 1.030660I

12.0428 − 7.8502I 0.54802 + 5.73315I

u = −0.512075 + 0.914815I

a = −0.310810 + 0.834490I

b = 1.006070 − 0.921537I

12.40950 + 0.72573I 1.20101 − 1.26627I

u = −0.512075 − 0.914815I

a = −0.310810 − 0.834490I

b = 1.006070 + 0.921537I

12.40950 − 0.72573I 1.20101 + 1.26627I

u = 0.041750 + 0.816332I

a = 0.984967 − 0.816170I

b = −0.730216 + 0.546904I

2.67787 − 1.51352I 3.15826 + 2.96332I

u = 0.041750 − 0.816332I

a = 0.984967 + 0.816170I

b = −0.730216 − 0.546904I

2.67787 + 1.51352I 3.15826 − 2.96332I

u = −0.755205 + 0.031373I

a = −0.154324 − 0.783184I

b = 0.955403 − 0.970517I

9.53090 − 3.51075I −2.36490 + 2.10810I

u = −0.755205 − 0.031373I

a = −0.154324 + 0.783184I

b = 0.955403 + 0.970517I

9.53090 + 3.51075I −2.36490 − 2.10810I

u = 0.429610 + 0.590805I

a = −1.30185 − 0.60397I

b = 0.291696 − 0.394438I

−0.15101 − 2.02920I −3.29658 + 3.20774I

u = 0.429610 − 0.590805I

a = −1.30185 + 0.60397I

b = 0.291696 + 0.394438I

−0.15101 + 2.02920I −3.29658 − 3.20774I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.179883 + 0.692364I

a = 2.11541 − 0.80616I

b = −0.514946 − 1.029420I

1.04465 + 3.25872I 1.94579 − 3.88394I

u = −0.179883 − 0.692364I

a = 2.11541 + 0.80616I

b = −0.514946 + 1.029420I

1.04465 − 3.25872I 1.94579 + 3.88394I

u = 0.398241 + 0.347741I

a = −0.595350 + 0.678601I

b = −0.007486 + 0.515758I

−0.844911 − 0.963937I −7.23227 + 5.09608I

u = 0.398241 − 0.347741I

a = −0.595350 − 0.678601I

b = −0.007486 − 0.515758I

−0.844911 + 0.963937I −7.23227 − 5.09608I

u = 0.05307 + 1.53702I

a = −0.565559 + 0.333640I

b = 0.007766 + 0.841204I

5.52882 − 2.13387I −4.00000 + 3.29212I

u = 0.05307 − 1.53702I

a = −0.565559 − 0.333640I

b = 0.007766 − 0.841204I

5.52882 + 2.13387I −4.00000 − 3.29212I

u = 0.12702 + 1.57248I

a = −1.339830 − 0.272553I

b = 0.478138 − 0.445759I

7.19200 − 4.05999I 0

u = 0.12702 − 1.57248I

a = −1.339830 + 0.272553I

b = 0.478138 + 0.445759I

7.19200 + 4.05999I 0

u = −0.04195 + 1.63425I

a = 1.62168 + 0.08443I

b = −0.578450 − 1.150140I

9.22292 + 4.03870I 0. − 2.65080I

u = −0.04195 − 1.63425I

a = 1.62168 − 0.08443I

b = −0.578450 + 1.150140I

9.22292 − 4.03870I 0. + 2.65080I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.01177 + 1.65893I

a = 1.41681 − 0.67494I

b = −0.955702 + 0.548085I

11.38100 − 1.72426I 3.45594 + 0.I

u = 0.01177 − 1.65893I

a = 1.41681 + 0.67494I

b = −0.955702 − 0.548085I

11.38100 + 1.72426I 3.45594 + 0.I

u = −0.16140 + 1.66866I

a = −1.98113 + 0.05979I

b = 0.93469 + 1.08649I

−18.7492 + 10.6138I 0. − 4.77955I

u = −0.16140 − 1.66866I

a = −1.98113 − 0.05979I

b = 0.93469 − 1.08649I

−18.7492 − 10.6138I 0. + 4.77955I

u = −0.14287 + 1.68669I

a = −1.04698 + 1.01839I

b = 1.072160 − 0.890015I

−18.0712 + 3.2992I 0

u = −0.14287 − 1.68669I

a = −1.04698 − 1.01839I

b = 1.072160 + 0.890015I

−18.0712 − 3.2992I 0

u = −0.221218 + 0.191391I

a = −2.06037 + 1.41739I

b = −0.397798 + 0.843645I

−0.31537 − 1.65529I −2.65586 + 5.38450I

u = −0.221218 − 0.191391I

a = −2.06037 − 1.41739I

b = −0.397798 − 0.843645I

−0.31537 + 1.65529I −2.65586 − 5.38450I

II.

= h−au + b − u, u

a − u

+ a

+ 3au − 2u, u

− u

+ 3u

− 2u + 1i

(i) Arc colorings











au + u









− au − u

+ a + 2u

au + u − 1





− u

+ a + 3u − 1

au + u − 1





−1





+ u





+ 1

− u

+ 2u − 1





+ 1

− u

+ 2u − 1





− au − u

+ a + 2u

au + u − 1





+ 2u

− u

+ 2u − 1



(ii) Obstruction class = 1

(iii) Cusp Shapes = −u

a + 4u

− 4au − 5u

+ a + 9u − 5

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

− u + 1)

+ u + 1)

, c

− u

+ 3u

− 2u + 1)

, c

+ u

+ 1)

, c

+ u

+ 3u

+ 2u + 1)

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

+ y + 1)

, c

+ 5y

+ 7y

+ 2y + 1)

, c

+ y

+ 3y

+ 2y + 1)

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.395123 + 0.506844I

a = 0.541116 + 0.214920I

b = 0.500000 + 0.866025I

−0.211005 + 0.614778I −1.64912 + 1.57080I

u = 0.395123 + 0.506844I

a = −1.58443 − 1.44211I

b = 0.500000 − 0.866025I

−0.21101 − 3.44499I −4.65255 + 7.52635I

u = 0.395123 − 0.506844I

a = 0.541116 − 0.214920I

b = 0.500000 − 0.866025I

−0.211005 − 0.614778I −1.64912 − 1.57080I

u = 0.395123 − 0.506844I

a = −1.58443 + 1.44211I

b = 0.500000 + 0.866025I

−0.21101 + 3.44499I −4.65255 − 7.52635I

u = 0.10488 + 1.55249I

a = −0.423047 − 0.283088I

b = 0.500000 + 0.866025I

6.79074 − 1.13408I 1.80063 − 0.49697I

u = 0.10488 + 1.55249I

a = −1.53364 − 0.35811I

b = 0.500000 − 0.866025I

6.79074 − 5.19385I −1.99896 + 6.53786I

u = 0.10488 − 1.55249I

a = −0.423047 + 0.283088I

b = 0.500000 − 0.866025I

6.79074 + 1.13408I 1.80063 + 0.49697I

u = 0.10488 − 1.55249I

a = −1.53364 + 0.35811I

b = 0.500000 + 0.866025I

6.79074 + 5.19385I −1.99896 − 6.53786I

III. u-Polynomials

Crossings u-Polynomials at each crossing

((u

− u + 1)

)(u

+ 5u

+ ··· + 14u + 1)

((u

+ u + 1)

)(u

+ 5u

+ ··· + 4u + 1)

((u

− u + 1)

)(u

− 5u

+ ··· + 5562u + 1321)

, c

+ u

+ ··· + 384u + 256)

((u

− u + 1)

)(u

+ 5u

+ ··· + 4u + 1)

, c

((u

− u

+ 3u

− 2u + 1)

)(u

− 3u

+ ··· − 6u + 1)

((u

+ u

+ 1)

)(u

− 3u

+ ··· − 2u + 1)

, c

((u

+ u

+ 3u

+ 2u + 1)

)(u

− 3u

+ ··· − 6u + 1)

((u

+ u

+ 1)

)(u

+ 11u

+ ··· + 184u + 209)

IV. Riley Polynomials

Crossings Riley Polynomials at each crossing

((y

+ y + 1)

)(y

+ 41y

+ ··· + 14y + 1)

, c

((y

+ y + 1)

)(y

+ 5y

+ ··· + 14y + 1)

((y

+ y + 1)

)(y

+ 77y

+ ··· + 1.02224 × 10

y + 1745041)

, c

+ 45y

+ ··· + 344064y + 65536)

, c

((y

+ 5y

+ 7y

+ 2y + 1)

)(y

+ 35y

+ ··· + 6y + 1)

((y

+ y

+ 3y

+ 2y + 1)

)(y

− 49y

+ ··· + 6y + 1)

((y

+ y

+ 3y

+ 2y + 1)

)(y

− 29y

+ ··· + 2808126y + 43681)