12n

0793

(K12n

0793

)

A knot diagram

Linearized knot diagam

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

Solving Sequence

7,11

12 8 1

3,6

2 5 10 4 9

, c

Ideals for irreducible components

of X

par

= h−9.06380 × 10

+ 1.37425 × 10

+ ··· + 2.41942 × 10

b − 1.11983 × 10

− 3.26749 × 10

− 3.64396 × 10

+ ··· + 2.66137 × 10

a + 8.28132 × 10

+ 2u

+ ··· − 46u + 11i

= hu

− 5u

+ 7u

+ b − 2u, u

− 5u

+ 7u

− u

+ a − 2u + 2,

+ u

− 8u

− 7u

+ 24u

+ 17u

− 33u

− 16u

+ 20u

+ 4u

− 4u

− u − 1i

* 2 irreducible components of dim

= 0, with total 54 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−9.06 × 10

+ 1.37 × 10

+ · · · + 2.42 × 10

b − 1.12 ×

, −3.27 × 10

− 3.64 × 10

+ · · · + 2.66 × 10

a + 8.28 ×

, u

+ 2u

+ · · · − 46u + 11i

(i) Arc colorings















−u

+ u





−u

+ 1

−u

+ 2u





0.122775u

+ 0.136921u

+ ··· + 9.26541u − 3.11168

0.00374626u

− 0.568007u

+ ··· − 19.2584u + 4.62848









0.552701u

+ 0.271165u

+ ··· − 10.9013u + 2.02390

0.433672u

− 0.433763u

+ ··· − 39.4251u + 9.76406





1.16210u

+ 1.69216u

+ ··· + 6.54468u − 3.34003

0.919505u

+ 0.221580u

+ ··· − 40.9514u + 10.5711





1.17084u

+ 1.34160u

+ ··· − 4.55540u − 2.12767

1.14646u

+ 1.21035u

+ ··· − 7.23546u − 2.71408





0.785947u

+ 1.09699u

+ ··· + 0.412589u − 1.16966

0.634717u

+ 0.515957u

+ ··· − 23.4534u + 6.67222





−1.45613u

− 1.65616u

+ ··· + 6.43111u + 2.36059

−1.31980u

− 1.39650u

+ ··· + 8.42549u + 3.12293



(ii) Obstruction class = −1

(iii) Cusp Shapes = 0.0586366u

+ 0.331503u

+ ··· + 5.71695u − 17.0612

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

− 2u

+ ··· − 45u − 1

, c

+ 3u

+ ··· + 3244u + 611

, c

+ u

+ ··· − 26u + 7

, c

− 3u

+ ··· + 222u + 79

, c

− 2u

+ ··· + 46u + 11

+ u

+ ··· − 48u + 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

+ 34y

+ ··· − 3015y + 1

, c

− 29y

+ ··· − 6104784y + 373321

, c

+ 43y

+ ··· − 1208y + 49

, c

− 37y

+ ··· − 146770y + 6241

, c

− 52y

+ ··· − 2050y + 121

+ 39y

+ ··· − 3522y + 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.221678 + 0.929619I

a = 0.236802 + 0.144006I

b = 0.200628 + 1.379120I

−0.23479 + 3.42452I −7.25006 − 2.36788I

u = 0.221678 − 0.929619I

a = 0.236802 − 0.144006I

b = 0.200628 − 1.379120I

−0.23479 − 3.42452I −7.25006 + 2.36788I

u = 0.834678 + 0.726650I

a = 0.942471 + 1.038720I

b = −0.32235 + 1.47004I

−2.09585 − 8.88492I −8.23343 + 6.33839I

u = 0.834678 − 0.726650I

a = 0.942471 − 1.038720I

b = −0.32235 − 1.47004I

−2.09585 + 8.88492I −8.23343 − 6.33839I

u = 0.839481

a = −0.147245

b = 0.446812

−1.61731 −3.83040

u = −0.649459 + 0.528735I

a = 0.425369 − 0.221209I

b = −0.883358 − 0.331381I

3.71527 + 4.57178I −4.48983 − 6.21438I

u = −0.649459 − 0.528735I

a = 0.425369 + 0.221209I

b = −0.883358 + 0.331381I

3.71527 − 4.57178I −4.48983 + 6.21438I

u = −1.205320 + 0.086480I

a = −0.45359 + 1.35560I

b = 0.093741 + 0.991733I

−4.64795 + 1.97026I −11.59090 − 3.85800I

u = −1.205320 − 0.086480I

a = −0.45359 − 1.35560I

b = 0.093741 − 0.991733I

−4.64795 − 1.97026I −11.59090 + 3.85800I

u = 0.550462 + 0.540915I

a = −1.409400 − 0.043470I

b = 0.125351 − 1.359680I

−6.87451 − 1.88626I −7.91284 + 3.72193I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.550462 − 0.540915I

a = −1.409400 + 0.043470I

b = 0.125351 + 1.359680I

−6.87451 + 1.88626I −7.91284 − 3.72193I

u = −0.560203 + 0.440638I

a = 1.43565 − 1.00821I

b = −0.04993 − 1.58808I

−7.60002 + 1.56574I −5.17924 − 4.63604I

u = −0.560203 − 0.440638I

a = 1.43565 + 1.00821I

b = −0.04993 + 1.58808I

−7.60002 − 1.56574I −5.17924 + 4.63604I

u = −0.334964 + 0.627307I

a = −0.026307 + 1.176530I

b = 0.577071 − 0.144380I

4.67940 − 0.63289I −1.299354 − 0.211342I

u = −0.334964 − 0.627307I

a = −0.026307 − 1.176530I

b = 0.577071 + 0.144380I

4.67940 + 0.63289I −1.299354 + 0.211342I

u = −1.244160 + 0.465780I

a = −0.79090 + 1.18454I

b = −0.025737 + 1.302660I

−4.81553 + 1.49702I 0

u = −1.244160 − 0.465780I

a = −0.79090 − 1.18454I

b = −0.025737 − 1.302660I

−4.81553 − 1.49702I 0

u = 0.595320 + 0.215476I

a = 0.20407 − 3.29680I

b = 0.272977 − 1.203760I

1.45303 − 2.42211I −8.67176 + 3.95905I

u = 0.595320 − 0.215476I

a = 0.20407 + 3.29680I

b = 0.272977 + 1.203760I

1.45303 + 2.42211I −8.67176 − 3.95905I

u = 1.42044 + 0.21754I

a = −0.455901 + 0.764179I

b = −0.205009 + 0.109418I

−0.93890 − 2.37365I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.42044 − 0.21754I

a = −0.455901 − 0.764179I

b = −0.205009 − 0.109418I

−0.93890 + 2.37365I 0

u = 0.509507 + 0.231007I

a = 0.734692 − 0.787767I

b = −0.636452 − 1.034150I

1.69283 + 0.80157I −9.60902 + 2.15996I

u = 0.509507 − 0.231007I

a = 0.734692 + 0.787767I

b = −0.636452 + 1.034150I

1.69283 − 0.80157I −9.60902 − 2.15996I

u = −0.506114

a = −1.86988

b = 0.407424

−2.40722 5.24600

u = −1.56067 + 0.05190I

a = 0.204618 − 1.091020I

b = 0.907751 − 0.996705I

−5.42360 + 0.16996I 0

u = −1.56067 − 0.05190I

a = 0.204618 + 1.091020I

b = 0.907751 + 0.996705I

−5.42360 − 0.16996I 0

u = 1.56797

a = 0.157767

b = −0.854086

−9.60649 0

u = −1.58059 + 0.15570I

a = 0.76812 − 1.50303I

b = −0.36026 − 1.39238I

−14.1195 + 4.4084I 0

u = −1.58059 − 0.15570I

a = 0.76812 + 1.50303I

b = −0.36026 + 1.39238I

−14.1195 − 4.4084I 0

u = 1.58699 + 0.12206I

a = −0.62381 − 2.20399I

b = 0.15580 − 1.70095I

−14.9835 − 3.5968I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.58699 − 0.12206I

a = −0.62381 + 2.20399I

b = 0.15580 + 1.70095I

−14.9835 + 3.5968I 0

u = −1.59898 + 0.06331I

a = −0.27626 − 2.55653I

b = −0.08483 − 1.42792I

−6.19779 + 3.44957I 0

u = −1.59898 − 0.06331I

a = −0.27626 + 2.55653I

b = −0.08483 + 1.42792I

−6.19779 − 3.44957I 0

u = 1.59624 + 0.14855I

a = 0.294078 − 0.648191I

b = 1.115930 − 0.471602I

−3.89460 − 7.04306I 0

u = 1.59624 − 0.14855I

a = 0.294078 + 0.648191I

b = 1.115930 + 0.471602I

−3.89460 + 7.04306I 0

u = 0.230807 + 0.288001I

a = 0.966776 + 0.311482I

b = −0.188196 + 0.489488I

−0.234295 − 0.833962I −5.60412 + 8.29990I

u = 0.230807 − 0.288001I

a = 0.966776 − 0.311482I

b = −0.188196 − 0.489488I

−0.234295 + 0.833962I −5.60412 − 8.29990I

u = −1.66654 + 0.22609I

a = −0.61931 + 1.92291I

b = 0.40841 + 1.58400I

−10.5286 + 12.5719I 0

u = −1.66654 − 0.22609I

a = −0.61931 − 1.92291I

b = 0.40841 − 1.58400I

−10.5286 − 12.5719I 0

u = −1.69539

a = −0.0379052

b = −0.681558

−10.7530 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.75180 + 0.08364I

a = 0.43693 + 1.85011I

b = −0.26084 + 1.40596I

−15.4551 − 3.4434I 0

u = 1.75180 − 0.08364I

a = 0.43693 − 1.85011I

b = −0.26084 − 1.40596I

−15.4551 + 3.4434I 0

II. I

−5u

+7u

+b −2u, u

−5u

+7u

−u

+a −2u+2, u

+· · ·−u−1i

(i) Arc colorings















−u

+ u





−u

+ 1

−u

+ 2u





−u

+ 5u

− 7u

+ u

+ 2u − 2

−u

+ 5u

− 7u

+ 2u









−u

+ 5u

− u

− 7u

+ 3u

+ 2u − 2

−u

+ 5u

− u

− 7u

+ 2u





−u

+ 7u

− u

− 17u

+ 5u

+ 16u

− 8u

− 4u

+ 5u

−u

+ 7u

− u

− 17u

+ 4u

+ 16u

− 4u

+ u





−u

+ 7u

− 17u

+ 17u

− 6u

− 2u − 1





−u

+ 7u

− u

− 17u

+ 6u

+ 16u

− 11u

− 4u

+ 6u

−u

+ 7u

− 17u

+ 16u

− 4u





− 9u

+ 30u

− 45u

+ 30u

− 9u − 1

−u − 1



(ii) Obstruction class = 1

(iii) Cusp Shapes = −u

+ 6u

+ u

−10u

−u

+ 29u

+ 10u

−27u

+ u −7

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

− u

+ 3u

+ u

+ 3u

− 2u

− u

− 4u

− u

+ 2u + 1

+ 2u

− u

− 4u

− u

− 2u

+ 3u

+ u

+ 3u

− u + 1

+ 7u

+ 19u

− u

+ 25u

− 4u

+ 16u

− 5u

+ 3u

− 3u − 1

− 2u

− u

+ 4u

− 3u

+ 4u

− 7u

+ 4u

− 7u

+ 8u

+ 3u − 1

− 2u

− u

+ 4u

− u

+ u

− 2u

− 3u

+ u

+ 3u

+ u + 1

, c

− u

+ ··· + u − 1

+ 2u

− u

− 4u

− 3u

− 4u

+ 7u

+ 4u

+ 7u

+ 8u

− 3u − 1

+ 3u

− u

− 2u

− 8u

+ 7u

− 4u

+ 15u

+ 4u

+ u − 3

+ 7u

+ 19u

+ u

+ 25u

+ 4u

+ 16u

+ 5u

+ 3u

+ 3u − 1

, c

+ u

+ ··· − u − 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

+ 5y

+ ··· − 6y + 1

, c

− 6y

+ ··· + 5y + 1

, c

+ 14y

+ ··· − 15y + 1

, c

− 6y

+ ··· − 25y + 1

, c

− 17y

+ ··· + 7y + 1

+ 6y

+ ··· − 25y + 9

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.686882 + 0.356361I

a = −1.57192 − 1.03304I

b = 0.08327 − 1.52260I

−8.42506 − 1.23513I −14.9695 + 0.5232I

u = 0.686882 − 0.356361I

a = −1.57192 + 1.03304I

b = 0.08327 + 1.52260I

−8.42506 + 1.23513I −14.9695 − 0.5232I

u = −0.697854

a = −1.27667

b = 0.236332

−2.77397 −17.7110

u = −1.350010 + 0.165727I

a = 0.122773 + 0.422338I

b = 0.327726 + 0.869804I

−1.87314 + 3.35889I −9.63200 − 3.88261I

u = −1.350010 − 0.165727I

a = 0.122773 − 0.422338I

b = 0.327726 − 0.869804I

−1.87314 − 3.35889I −9.63200 + 3.88261I

u = 1.43456 + 0.19655I

a = 0.38745 + 1.66784I

b = 0.368130 + 1.103920I

−2.74104 − 0.62345I −7.00640 − 0.32990I

u = 1.43456 − 0.19655I

a = 0.38745 − 1.66784I

b = 0.368130 − 1.103920I

−2.74104 + 0.62345I −7.00640 + 0.32990I

u = −0.076876 + 0.352057I

a = −2.49621 + 0.92625I

b = −0.378175 + 0.980375I

2.45499 − 1.46473I −3.28668 + 1.82890I

u = −0.076876 − 0.352057I

a = −2.49621 − 0.92625I

b = −0.378175 − 0.980375I

2.45499 + 1.46473I −3.28668 − 1.82890I

u = 1.67252

a = 0.219784

b = −0.577555

−11.3408 −16.0060

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −1.68189 + 0.10991I

a = 0.58634 − 1.91439I

b = −0.23034 − 1.54467I

−16.9020 + 3.1092I −14.7470 − 0.9268I

u = −1.68189 − 0.10991I

a = 0.58634 + 1.91439I

b = −0.23034 + 1.54467I

−16.9020 − 3.1092I −14.7470 + 0.9268I

III. u-Polynomials

Crossings u-Polynomials at each crossing

− u

+ 3u

+ u

+ 3u

− 2u

− u

− 4u

− u

+ 2u + 1)

· (u

− 2u

+ ··· − 45u − 1)

+ 2u

− u

− 4u

− u

− 2u

+ 3u

+ u

+ 3u

− u + 1)

· (u

+ 3u

+ ··· + 3244u + 611)

+ 7u

+ 19u

− u

+ 25u

− 4u

+ 16u

− 5u

+ 3u

− 3u − 1)

· (u

+ u

+ ··· − 26u + 7)

− 2u

− u

+ 4u

− 3u

+ 4u

− 7u

+ 4u

− 7u

+ 8u

+ 3u − 1)

· (u

− 3u

+ ··· + 222u + 79)

− 2u

− u

+ 4u

− u

+ u

− 2u

− 3u

+ u

+ 3u

+ u + 1)

· (u

+ 3u

+ ··· + 3244u + 611)

, c

− u

+ ··· + u − 1)(u

− 2u

+ ··· + 46u + 11)

+ 2u

− u

− 4u

− 3u

− 4u

+ 7u

+ 4u

+ 7u

+ 8u

− 3u − 1)

· (u

− 3u

+ ··· + 222u + 79)

+ 3u

− u

− 2u

− 8u

+ 7u

− 4u

+ 15u

+ 4u

+ u − 3)

· (u

+ u

+ ··· − 48u + 1)

+ 7u

+ 19u

+ u

+ 25u

+ 4u

+ 16u

+ 5u

+ 3u

+ 3u − 1)

· (u

+ u

+ ··· − 26u + 7)

, c

+ u

+ ··· − u − 1)(u

− 2u

+ ··· + 46u + 11)

IV. Riley Polynomials

Crossings Riley Polynomials at each crossing

+ 5y

+ ··· − 6y + 1)(y

+ 34y

+ ··· − 3015y + 1)

, c

− 6y

+ ··· + 5y + 1)(y

− 29y

+ ··· − 6104784y + 373321)

, c

+ 14y

+ ··· − 15y + 1)(y

+ 43y

+ ··· − 1208y + 49)

, c

− 6y

+ ··· − 25y + 1)(y

− 37y

+ ··· − 146770y + 6241)

, c

− 17y

+ ··· + 7y + 1)(y

− 52y

+ ··· − 2050y + 121)

+ 6y

+ ··· − 25y + 9)(y

+ 39y

+ ··· − 3522y + 1)