11a

187

(K11a

187

)

A knot diagram

Linearized knot diagam

6 1 9 8 10 2 3 4 11 5 7

Solving Sequence

2,6

7 1 3

8,10

5 4 11 9

, c

Ideals for irreducible components

of X

par

= h2u

+ 2u

+ ··· + 4b + 2, 2u

+ u

+ ··· + 4a + 4, u

+ 2u

+ ··· + 3u + 2i

= h−42u

+ 6u

a + ··· − 33a − 16,

+ u

a − 2u

+ 2u

a + u

− 2a

− u

+ a

+ 2a

u − 3u

a + u

+ 2au + 2u

+ a − 2u + 1,

− u

+ 2u

− u + 1i

= hu

+ b, −u

− u

+ a + u + 1, u

− u

+ 1i

* 3 irreducible components of dim

= 0, with total 66 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.

= h2u

+2u

+· · ·+4b+2, 2u

+· · ·+4a+4, u

+2u

+· · ·+3u+2i

(i) Arc colorings



















−u

+ u





− u

+ u

+ 1

− 2u

+ 2u





−

+ ··· −

u − 1

−

+ ··· +

u −





− 5u

+ ··· +

u + 1

−

+ ··· +

u + 1





−

+ ··· +

u +

−

+ 2u

+ ··· −

+ u





− u

+ u





−

+ 5u

+ ··· −

u − 1

−u

− u

+ ··· −

u − 1





−

+ 5u

+ ··· −

u − 1

−u

− u

+ ··· −

u − 1



(ii) Obstruction class = −1

(iii) Cusp Shapes = −2u

+ 20u

+ 4u

− 104u

− 36u

+ 356u

+ 168u

−

886u

− 516u

+ 1682u

+ 1152u

− 2512u

− 1966u

+ 3018u

+ 2658u

−

2988u

− 2940u

+ 2506u

+ 2762u

− 1828u

− 2288u

+ 1160u

+ 1706u

−

614u

− 1138u

+ 234u

+ 680u

− 8u

− 356u

− 126u

+ 132u

+ 148u

30u

− 90u

− 66u

+ 36u

+ 8u

+ 12u

− 4u

− 12u + 2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

+ 2u

+ ··· + 3u + 2

+ 20u

+ ··· − 19u + 4

, c

− u

+ ··· − 16u + 1

, c

− u

+ ··· − 2u + 1

− 2u

+ ··· − 496u + 32

− 21u

+ ··· − 6u + 1

+ 6u

+ ··· + 352u + 128

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

− 20y

+ ··· + 19y + 4

+ 8y

+ ··· − 417y + 16

, c

+ 41y

+ ··· − 90y + 1

, c

+ 21y

+ ··· + 6y + 1

− 18y

+ ··· − 81664y + 1024

+ 9y

+ ··· + 26y + 1

+ 4y

+ ··· + 400384y + 16384

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.614083 + 0.757021I

a = −0.632443 + 1.216370I

b = −0.484382 − 1.114490I

1.31355 − 6.59166I 2.43428 + 6.77222I

u = 0.614083 − 0.757021I

a = −0.632443 − 1.216370I

b = −0.484382 + 1.114490I

1.31355 + 6.59166I 2.43428 − 6.77222I

u = 0.821139 + 0.488156I

a = −0.927633 + 0.608891I

b = −0.072544 − 0.992801I

1.71974 − 2.04449I 8.09534 + 3.92627I

u = 0.821139 − 0.488156I

a = −0.927633 − 0.608891I

b = −0.072544 + 0.992801I

1.71974 + 2.04449I 8.09534 − 3.92627I

u = −0.862505 + 0.618420I

a = 0.449298 + 0.919851I

b = 0.296344 − 0.458666I

−1.78260 + 2.32403I −3.34006 − 4.18594I

u = −0.862505 − 0.618420I

a = 0.449298 − 0.919851I

b = 0.296344 + 0.458666I

−1.78260 − 2.32403I −3.34006 + 4.18594I

u = 1.073220 + 0.159361I

a = −1.46758 + 0.81560I

b = −0.486107 + 1.058250I

−0.00015 + 3.23140I −0.12341 − 4.01153I

u = 1.073220 − 0.159361I

a = −1.46758 − 0.81560I

b = −0.486107 − 1.058250I

−0.00015 − 3.23140I −0.12341 + 4.01153I

u = −0.650664 + 0.627229I

a = −0.005189 + 0.303137I

b = −0.553759 − 0.162746I

−1.24285 + 2.41947I −1.11371 − 3.27345I

u = −0.650664 − 0.627229I

a = −0.005189 − 0.303137I

b = −0.553759 + 0.162746I

−1.24285 − 2.41947I −1.11371 + 3.27345I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.383154 + 0.817621I

a = −0.699793 − 1.003430I

b = −0.559403 + 1.175300I

0.02553 + 9.64814I 1.87633 − 5.89081I

u = 0.383154 − 0.817621I

a = −0.699793 + 1.003430I

b = −0.559403 − 1.175300I

0.02553 − 9.64814I 1.87633 + 5.89081I

u = −0.541524 + 0.710426I

a = 0.69602 + 1.31058I

b = 0.390858 − 1.163740I

5.49978 + 2.81685I 7.91209 − 3.62313I

u = −0.541524 − 0.710426I

a = 0.69602 − 1.31058I

b = 0.390858 + 1.163740I

5.49978 − 2.81685I 7.91209 + 3.62313I

u = −1.012810 + 0.465132I

a = 0.56553 + 1.48232I

b = 0.441089 + 0.401407I

−2.03263 + 1.73845I −4.12033 − 0.48900I

u = −1.012810 − 0.465132I

a = 0.56553 − 1.48232I

b = 0.441089 − 0.401407I

−2.03263 − 1.73845I −4.12033 + 0.48900I

u = −0.406877 + 0.760900I

a = 0.879442 − 1.067170I

b = 0.490957 + 1.153170I

4.79783 − 5.37629I 6.38044 + 4.26424I

u = −0.406877 − 0.760900I

a = 0.879442 + 1.067170I

b = 0.490957 − 1.153170I

4.79783 + 5.37629I 6.38044 − 4.26424I

u = 1.059790 + 0.421005I

a = 2.19306 + 0.61348I

b = 0.508638 + 0.730201I

−2.20066 − 4.83120I −3.00848 + 8.38874I

u = 1.059790 − 0.421005I

a = 2.19306 − 0.61348I

b = 0.508638 − 0.730201I

−2.20066 + 4.83120I −3.00848 − 8.38874I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.136200 + 0.221185I

a = 1.46732 + 0.20761I

b = 0.820180 + 0.375098I

−7.36306 + 1.79166I −7.40265 − 0.27193I

u = 1.136200 − 0.221185I

a = 1.46732 − 0.20761I

b = 0.820180 − 0.375098I

−7.36306 − 1.79166I −7.40265 + 0.27193I

u = −0.340701 + 0.765223I

a = −0.166604 − 0.002494I

b = −0.831807 + 0.245624I

−2.73686 − 4.51181I −1.28953 + 2.54030I

u = −0.340701 − 0.765223I

a = −0.166604 + 0.002494I

b = −0.831807 − 0.245624I

−2.73686 + 4.51181I −1.28953 − 2.54030I

u = −1.163100 + 0.154076I

a = 1.25749 + 0.76708I

b = 0.592275 + 1.120500I

−5.13953 − 7.03997I −4.35205 + 4.78449I

u = −1.163100 − 0.154076I

a = 1.25749 − 0.76708I

b = 0.592275 − 1.120500I

−5.13953 + 7.03997I −4.35205 − 4.78449I

u = −1.023700 + 0.599662I

a = 0.681062 + 0.160774I

b = −0.337241 − 1.172950I

4.07169 + 2.20922I 5.83455 − 2.04205I

u = −1.023700 − 0.599662I

a = 0.681062 − 0.160774I

b = −0.337241 + 1.172950I

4.07169 − 2.20922I 5.83455 + 2.04205I

u = 0.989262 + 0.656622I

a = −0.585610 + 0.177116I

b = 0.449630 − 1.070930I

0.200378 + 1.249410I 0.49362 − 2.01846I

u = 0.989262 − 0.656622I

a = −0.585610 − 0.177116I

b = 0.449630 + 1.070930I

0.200378 − 1.249410I 0.49362 + 2.01846I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.154760 + 0.388979I

a = −0.93774 + 1.14513I

b = −0.753378 + 0.721249I

−9.26869 − 1.33308I −7.30769 + 0.69505I

u = 1.154760 − 0.388979I

a = −0.93774 − 1.14513I

b = −0.753378 − 0.721249I

−9.26869 + 1.33308I −7.30769 − 0.69505I

u = −1.155640 + 0.451289I

a = −2.06743 + 0.02294I

b = −0.716747 + 0.865040I

−8.84980 + 6.81745I −6.19135 − 6.52038I

u = −1.155640 − 0.451289I

a = −2.06743 − 0.02294I

b = −0.716747 − 0.865040I

−8.84980 − 6.81745I −6.19135 + 6.52038I

u = −1.101670 + 0.589261I

a = −2.50240 − 0.70880I

b = −0.527845 + 1.156650I

2.74383 + 10.48610I 3.00784 − 8.49174I

u = −1.101670 − 0.589261I

a = −2.50240 + 0.70880I

b = −0.527845 − 1.156650I

2.74383 − 10.48610I 3.00784 + 8.49174I

u = −1.123580 + 0.572511I

a = 0.627078 + 1.120360I

b = 0.896517 + 0.252922I

−5.03545 + 9.55347I −4.20919 − 6.36695I

u = −1.123580 − 0.572511I

a = 0.627078 − 1.120360I

b = 0.896517 − 0.252922I

−5.03545 − 9.55347I −4.20919 + 6.36695I

u = −0.068807 + 0.735625I

a = 0.599542 − 0.271859I

b = 0.657434 + 0.786735I

−5.68233 − 2.52073I −2.77619 + 3.16598I

u = −0.068807 − 0.735625I

a = 0.599542 + 0.271859I

b = 0.657434 − 0.786735I

−5.68233 + 2.52073I −2.77619 − 3.16598I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.127870 + 0.601926I

a = 2.30965 − 0.72062I

b = 0.581039 + 1.195430I

−2.1965 − 14.9450I 0. + 9.66907I

u = 1.127870 − 0.601926I

a = 2.30965 + 0.72062I

b = 0.581039 − 1.195430I

−2.1965 + 14.9450I 0. − 9.66907I

u = 0.092103 + 0.448304I

a = −0.983082 + 0.405423I

b = −0.301747 + 0.738058I

0.260137 + 1.355870I 2.16052 − 5.21178I

u = 0.092103 − 0.448304I

a = −0.983082 − 0.405423I

b = −0.301747 − 0.738058I

0.260137 − 1.355870I 2.16052 + 5.21178I

II. I

h−42u

+6u

a+· · ·−33a−16, u

a+u

+· · ·+a+1, u

−u

+2u

−u+1i

(i) Arc colorings



















−u

+ u





−u

+ u

− u





0.531646a

− 0.0759494au

+ ··· + 0.417722a + 0.202532





0.202532a

+ 0.113924au

+ ··· + 0.873418a + 1.69620

−0.354430a

+ 0.0506329au

+ ··· − 0.278481a + 0.531646





−0.151899a

+ 1.16456au

+ ··· + 0.594937a + 2.22785

−0.0886076a

+ 1.01266au

+ ··· − 0.569620a + 0.632911





− u

+ u





0.430380a

− 0.632911au

+ ··· + 1.48101a + 0.354430

0.708861a

+ 0.898734au

+ ··· + 0.556962a + 0.936709





0.430380a

− 0.632911au

+ ··· + 1.48101a + 0.354430

0.708861a

+ 0.898734au

+ ··· + 0.556962a + 0.936709



(ii) Obstruction class = −1

(iii) Cusp Shapes = 4u

− 4u

+ 4u + 2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

− u

+ 2u

− u + 1)

+ 3u

+ 5u

+ 4u

+ 2u

+ u + 1)

, c

+ 6u

+ ··· + u + 1

+ u

− u

− 2u

+ u + 1)

− 12u

+ ··· + u + 1

− 3u

+ 5u

− 4u

+ 2u

− u + 1)

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

− 3y

+ 5y

− 4y

+ 2y

− y + 1)

, c

+ y

+ 5y

+ 6y

+ 3y + 1)

, c

+ 12y

+ ··· − y + 1

− 12y

+ ··· − y + 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −1.002190 + 0.295542I

a = 1.172640 + 0.086416I

b = 0.115801 − 1.253200I

−1.89061 + 0.92430I −3.71672 − 0.79423I

u = −1.002190 + 0.295542I

a = −1.36195 + 0.61543I

b = −0.528367 + 0.395250I

−1.89061 + 0.92430I −3.71672 − 0.79423I

u = −1.002190 + 0.295542I

a = 1.55971 + 1.42467I

b = 0.412566 + 0.857945I

−1.89061 + 0.92430I −3.71672 − 0.79423I

u = −1.002190 − 0.295542I

a = 1.172640 − 0.086416I

b = 0.115801 + 1.253200I

−1.89061 − 0.92430I −3.71672 + 0.79423I

u = −1.002190 − 0.295542I

a = −1.36195 − 0.61543I

b = −0.528367 − 0.395250I

−1.89061 − 0.92430I −3.71672 + 0.79423I

u = −1.002190 − 0.295542I

a = 1.55971 − 1.42467I

b = 0.412566 − 0.857945I

−1.89061 − 0.92430I −3.71672 + 0.79423I

u = 0.428243 + 0.664531I

a = −1.25605 − 1.08267I

b = −0.402290 + 1.103490I

1.89061 + 0.92430I 3.71672 − 0.79423I

u = 0.428243 + 0.664531I

a = −0.73391 + 1.51018I

b = −0.293594 − 1.224710I

1.89061 + 0.92430I 3.71672 − 0.79423I

u = 0.428243 + 0.664531I

a = 0.153991 + 0.113906I

b = 0.695884 + 0.121220I

1.89061 + 0.92430I 3.71672 − 0.79423I

u = 0.428243 − 0.664531I

a = −1.25605 + 1.08267I

b = −0.402290 − 1.103490I

1.89061 − 0.92430I 3.71672 + 0.79423I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.428243 − 0.664531I

a = −0.73391 − 1.51018I

b = −0.293594 + 1.224710I

1.89061 − 0.92430I 3.71672 + 0.79423I

u = 0.428243 − 0.664531I

a = 0.153991 − 0.113906I

b = 0.695884 − 0.121220I

1.89061 − 0.92430I 3.71672 + 0.79423I

u = 1.073950 + 0.558752I

a = −0.746547 + 0.100402I

b = 0.274969 − 1.288580I

− 5.69302I 0. + 5.51057I

u = 1.073950 + 0.558752I

a = −0.586060 + 1.174340I

b = −0.750911 + 0.211085I

− 5.69302I 0. + 5.51057I

u = 1.073950 + 0.558752I

a = 2.79818 − 0.51224I

b = 0.475942 + 1.077500I

− 5.69302I 0. + 5.51057I

u = 1.073950 − 0.558752I

a = −0.746547 − 0.100402I

b = 0.274969 + 1.288580I

5.69302I 0. − 5.51057I

u = 1.073950 − 0.558752I

a = −0.586060 − 1.174340I

b = −0.750911 − 0.211085I

5.69302I 0. − 5.51057I

u = 1.073950 − 0.558752I

a = 2.79818 + 0.51224I

b = 0.475942 − 1.077500I

5.69302I 0. − 5.51057I

III. I

= hu

+ b, −u

− u

+ a + u + 1, u

− u

+ 1i

(i) Arc colorings



















−u

+ u









+ u

− u − 1

−u





−u

− u + 1





−u

− u

− u + 1

−u

+ u + 1









− u − 1

−u





− u − 1

−u



(ii) Obstruction class = 1

(iii) Cusp Shapes = 4u

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

− u

+ 1

+ u + 1)

, c

+ 1)

(u + 1)

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

− y + 1)

+ y + 1)

, c

(y + 1)

(y −1)

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.866025 + 0.500000I

a = −1.36603 + 1.36603I

b = − 1.000000I

− 2.02988I 2.00000 + 3.46410I

u = 0.866025 − 0.500000I

a = −1.36603 − 1.36603I

b = 1.000000I

2.02988I 2.00000 − 3.46410I

u = −0.866025 + 0.500000I

a = 0.366025 − 0.366025I

b = − 1.000000I

2.02988I 2.00000 − 3.46410I

u = −0.866025 − 0.500000I

a = 0.366025 + 0.366025I

b = 1.000000I

− 2.02988I 2.00000 + 3.46410I

IV. u-Polynomials

Crossings u-Polynomials at each crossing

, c

− u

+ 1)(u

− u

+ ··· − u + 1)

+ 2u

+ ··· + 3u + 2)

+ u + 1)

+ 3u

+ 5u

+ 4u

+ 2u

+ u + 1)

· (u

+ 20u

+ ··· − 19u + 4)

, c

((u

+ 1)

)(u

+ 6u

+ ··· + u + 1)(u

− u

+ ··· − 16u + 1)

, c

((u

+ 1)

)(u

+ 6u

+ ··· + u + 1)(u

− u

+ ··· − 2u + 1)

+ u

+ ··· + u + 1)

− 2u

+ ··· − 496u + 32)

((u + 1)

)(u

− 12u

+ ··· + u + 1)(u

− 21u

+ ··· − 6u + 1)

− u

+ 1)(u

− 3u

+ 5u

− 4u

+ 2u

− u + 1)

· (u

+ 6u

+ ··· + 352u + 128)

V. Riley Polynomials

Crossings Riley Polynomials at each crossing

, c

− y + 1)

− 3y

+ 5y

− 4y

+ 2y

− y + 1)

· (y

− 20y

+ ··· + 19y + 4)

+ y + 1)

+ y

+ 5y

+ 6y

+ 3y + 1)

· (y

+ 8y

+ ··· − 417y + 16)

, c

((y + 1)

)(y

+ 12y

+ ··· − y + 1)(y

+ 41y

+ ··· − 90y + 1)

, c

((y + 1)

)(y

+ 12y

+ ··· − y + 1)(y

+ 21y

+ ··· + 6y + 1)

− 3y

+ 5y

− 4y

+ 2y

− y + 1)

· (y

− 18y

+ ··· − 81664y + 1024)

((y −1)

)(y

− 12y

+ ··· − y + 1)(y

+ 9y

+ ··· + 26y + 1)

− y + 1)

+ y

+ 5y

+ 6y

+ 3y + 1)

· (y

+ 4y

+ ··· + 400384y + 16384)