12n

0183

(K12n

0183

)

A knot diagram

Linearized knot diagam

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

Solving Sequence

5,10

3,11

2 1 4 9 7 12 8

, c

Ideals for irreducible components

of X

par

= h−1.20523 × 10

− 1.33633 × 10

+ ··· + 4.02644 × 10

b + 1.46507 × 10

1.44947 × 10

− 4.60820 × 10

+ ··· + 1.34215 × 10

a − 2.19191 × 10

, u

+ 2u

+ ··· + 4u + 1i

= hb + 1, 2u

+ u

− 5u

− 3u

+ 4u

+ 3u

+ 2u

+ a − 2, u

+ u

− 2u

− 3u

+ u

+ 3u

+ 2u

− u − 1i

* 2 irreducible components of dim

= 0, with total 72 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−1.21×10

−1.34×10

+· · ·+4.03×10

b+1.47×10

, 1.45×

−4.61×10

+· · ·+1.34×10

a−2.19×10

, u

+2u

+· · ·+4u+1i

(i) Arc colorings















−1.07996u

+ 0.0343346u

+ ··· − 1.91121u + 1.63313

0.299329u

+ 0.331888u

+ ··· + 1.56778u − 0.363863





−u

+ u





−0.780635u

+ 0.366222u

+ ··· − 0.343427u + 1.26927

0.299329u

+ 0.331888u

+ ··· + 1.56778u − 0.363863





0.498188u

+ 0.716504u

+ ··· + 2.18592u − 0.0731899

0.197906u

+ 0.176045u

+ ··· + 1.05588u + 0.392848





−1.09042u

− 0.00217631u

+ ··· − 1.99896u + 1.59173

0.208603u

+ 0.265857u

+ ··· + 1.12023u − 0.513655





− u

+ u





− u

+ 1

− 2u

+ 2u





0.153458u

+ 0.0698033u

+ ··· + 2.02811u − 0.0419731

0.369503u

+ 0.349046u

+ ··· + 2.10549u + 0.618121





−0.445304u

− 0.752007u

+ ··· − 4.41211u − 0.301292

0.301712u

+ 0.446342u

+ ··· + 1.60552u + 0.343270



(ii) Obstruction class = −1

(iii) Cusp Shapes = 20.7017u

+ 25.9299u

+ ··· + 68.1832u + 9.80994

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

+ 20u

+ ··· − 54u + 1

, c

− 10u

+ ··· − 6u + 1

, c

+ u

+ ··· + 5632u + 512

, c

+ 2u

+ ··· + 4u + 1

+ 6u

+ ··· + 1272u + 117

, c

+ 2u

+ ··· + 4u + 1

+ 28u

+ ··· + 6u + 1

− 36u

+ ··· + 6u + 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

+ 56y

+ ··· + 398y −1

, c

− 20y

+ ··· − 54y −1

, c

+ 57y

+ ··· + 10485760y −262144

, c

− 28y

+ ··· + 6y −1

− 4y

+ ··· + 236682y −13689

, c

+ 36y

+ ··· + 6y −1

+ 16y

+ ··· − 14y −1

− 16y

+ ··· + 90y −1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.926110 + 0.366074I

a = −0.476922 + 0.252194I

b = −1.244610 + 0.271873I

−3.07412 − 1.36938I −14.1533 + 4.8337I

u = 0.926110 − 0.366074I

a = −0.476922 − 0.252194I

b = −1.244610 − 0.271873I

−3.07412 + 1.36938I −14.1533 − 4.8337I

u = −0.560970 + 0.838273I

a = −0.54543 + 1.39738I

b = 0.991983 − 0.885226I

8.30126 + 6.53190I −3.98974 − 5.60044I

u = −0.560970 − 0.838273I

a = −0.54543 − 1.39738I

b = 0.991983 + 0.885226I

8.30126 − 6.53190I −3.98974 + 5.60044I

u = 0.568620 + 0.802904I

a = −0.24496 − 1.43112I

b = 0.765553 + 0.905015I

4.93754 − 1.39094I −6.19355 + 2.18855I

u = 0.568620 − 0.802904I

a = −0.24496 + 1.43112I

b = 0.765553 − 0.905015I

4.93754 + 1.39094I −6.19355 − 2.18855I

u = −0.839102 + 0.489407I

a = 3.31553 + 9.53794I

b = −0.982885 + 0.004271I

0.04887 + 2.03557I −112.9138 + 23.7044I

u = −0.839102 − 0.489407I

a = 3.31553 − 9.53794I

b = −0.982885 − 0.004271I

0.04887 − 2.03557I −112.9138 − 23.7044I

u = −0.447997 + 0.861723I

a = −0.71326 − 1.29092I

b = 1.18245 + 0.86510I

7.62161 − 10.39330I −4.76838 + 5.34490I

u = −0.447997 − 0.861723I

a = −0.71326 + 1.29092I

b = 1.18245 − 0.86510I

7.62161 + 10.39330I −4.76838 − 5.34490I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.772884 + 0.566946I

a = 0.741522 − 0.337818I

b = 0.0483031 + 0.1203760I

1.79771 − 2.20109I −2.95390 + 4.60864I

u = 0.772884 − 0.566946I

a = 0.741522 + 0.337818I

b = 0.0483031 − 0.1203760I

1.79771 + 2.20109I −2.95390 − 4.60864I

u = −0.529043 + 0.791579I

a = −0.17601 + 1.78351I

b = 0.710973 − 1.169850I

9.18780 − 3.10441I −2.77684 + 1.28013I

u = −0.529043 − 0.791579I

a = −0.17601 − 1.78351I

b = 0.710973 + 1.169850I

9.18780 + 3.10441I −2.77684 − 1.28013I

u = 0.427955 + 0.848872I

a = −0.482691 + 1.203200I

b = 1.039060 − 0.804035I

4.08395 + 4.95084I −7.20670 − 2.70270I

u = 0.427955 − 0.848872I

a = −0.482691 − 1.203200I

b = 1.039060 + 0.804035I

4.08395 − 4.95084I −7.20670 + 2.70270I

u = −0.916546 + 0.249573I

a = 0.527016 − 0.043315I

b = −1.008620 − 0.698143I

−1.65763 − 1.62708I −12.47188 + 3.53384I

u = −0.916546 − 0.249573I

a = 0.527016 + 0.043315I

b = −1.008620 + 0.698143I

−1.65763 + 1.62708I −12.47188 − 3.53384I

u = 0.972660 + 0.400781I

a = −0.570758 + 1.097760I

b = −1.45853 + 0.06110I

−3.33869 − 1.43594I −8.00000 + 0.I

u = 0.972660 − 0.400781I

a = −0.570758 − 1.097760I

b = −1.45853 − 0.06110I

−3.33869 + 1.43594I −8.00000 + 0.I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.439813 + 0.813829I

a = −0.22505 − 1.43226I

b = 0.872307 + 0.941914I

8.68256 − 0.17840I −3.11591 − 0.13366I

u = −0.439813 − 0.813829I

a = −0.22505 + 1.43226I

b = 0.872307 − 0.941914I

8.68256 + 0.17840I −3.11591 + 0.13366I

u = 0.946126 + 0.549853I

a = 1.30038 + 1.55435I

b = −0.476073 − 0.045942I

1.19543 − 2.08630I 0

u = 0.946126 − 0.549853I

a = 1.30038 − 1.55435I

b = −0.476073 + 0.045942I

1.19543 + 2.08630I 0

u = −1.003650 + 0.458888I

a = −0.56877 − 1.84841I

b = −1.42816 + 0.42370I

−2.91315 + 4.52729I 0

u = −1.003650 − 0.458888I

a = −0.56877 + 1.84841I

b = −1.42816 − 0.42370I

−2.91315 − 4.52729I 0

u = 1.111750 + 0.078744I

a = 0.931682 − 0.009722I

b = 0.606356 − 0.865246I

3.30246 − 1.91069I 0

u = 1.111750 − 0.078744I

a = 0.931682 + 0.009722I

b = 0.606356 + 0.865246I

3.30246 + 1.91069I 0

u = −0.992246 + 0.519940I

a = −0.33704 − 1.95730I

b = −0.879799 + 0.608584I

−1.95839 + 4.15867I 0

u = −0.992246 − 0.519940I

a = −0.33704 + 1.95730I

b = −0.879799 − 0.608584I

−1.95839 − 4.15867I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.027300 + 0.547178I

a = −0.62187 + 1.64598I

b = −0.674886 − 1.080260I

0.27233 − 7.55007I 0

u = 1.027300 − 0.547178I

a = −0.62187 − 1.64598I

b = −0.674886 + 1.080260I

0.27233 + 7.55007I 0

u = 0.105288 + 0.803613I

a = 0.163733 + 0.190487I

b = 0.635693 − 0.133199I

−1.46958 + 2.74391I −2.52412 − 4.27240I

u = 0.105288 − 0.803613I

a = 0.163733 − 0.190487I

b = 0.635693 + 0.133199I

−1.46958 − 2.74391I −2.52412 + 4.27240I

u = −1.190260 + 0.105981I

a = 0.841204 + 0.034521I

b = 0.922740 + 0.637535I

−1.51798 − 2.46440I 0

u = −1.190260 − 0.105981I

a = 0.841204 − 0.034521I

b = 0.922740 − 0.637535I

−1.51798 + 2.46440I 0

u = 1.205040 + 0.067480I

a = 0.816284 + 0.015394I

b = 1.112880 − 0.749697I

1.77097 + 7.99701I 0

u = 1.205040 − 0.067480I

a = 0.816284 − 0.015394I

b = 1.112880 + 0.749697I

1.77097 − 7.99701I 0

u = 1.039570 + 0.658560I

a = −0.914741 + 0.261872I

b = 0.622398 − 0.949236I

3.52241 − 4.08840I 0

u = 1.039570 − 0.658560I

a = −0.914741 − 0.261872I

b = 0.622398 + 0.949236I

3.52241 + 4.08840I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −1.059960 + 0.641966I

a = −1.231410 − 0.420346I

b = 0.637529 + 1.260300I

7.59858 + 8.49760I 0

u = −1.059960 − 0.641966I

a = −1.231410 + 0.420346I

b = 0.637529 − 1.260300I

7.59858 − 8.49760I 0

u = −1.057440 + 0.680554I

a = −1.002810 + 0.058966I

b = 0.898990 + 0.875767I

6.80806 − 0.88135I 0

u = −1.057440 − 0.680554I

a = −1.002810 − 0.058966I

b = 0.898990 − 0.875767I

6.80806 + 0.88135I 0

u = 0.568628 + 0.459189I

a = 1.57734 + 0.31772I

b = −0.253084 − 0.388928I

2.13125 − 2.17129I −3.22626 + 3.56149I

u = 0.568628 − 0.459189I

a = 1.57734 − 0.31772I

b = −0.253084 + 0.388928I

2.13125 + 2.17129I −3.22626 − 3.56149I

u = −1.206380 + 0.395280I

a = 0.870666 + 0.422612I

b = 0.706799 − 0.004491I

−5.38670 + 1.34424I 0

u = −1.206380 − 0.395280I

a = 0.870666 − 0.422612I

b = 0.706799 + 0.004491I

−5.38670 − 1.34424I 0

u = −1.109200 + 0.619508I

a = 1.24867 + 1.72679I

b = 0.939930 − 0.857494I

6.67687 + 5.54473I 0

u = −1.109200 − 0.619508I

a = 1.24867 − 1.72679I

b = 0.939930 + 0.857494I

6.67687 − 5.54473I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.452256 + 0.561618I

a = 1.40155 − 1.36845I

b = −0.506448 + 0.882679I

1.87503 + 3.06479I −4.36652 − 4.78234I

u = 0.452256 − 0.561618I

a = 1.40155 + 1.36845I

b = −0.506448 − 0.882679I

1.87503 − 3.06479I −4.36652 + 4.78234I

u = 1.124570 + 0.631526I

a = 0.93240 − 1.80350I

b = 1.123120 + 0.773338I

1.99016 − 10.45010I 0

u = 1.124570 − 0.631526I

a = 0.93240 + 1.80350I

b = 1.123120 − 0.773338I

1.99016 + 10.45010I 0

u = −1.120990 + 0.642900I

a = 0.86354 + 2.02077I

b = 1.24190 − 0.85165I

5.5911 + 15.9697I 0

u = −1.120990 − 0.642900I

a = 0.86354 − 2.02077I

b = 1.24190 + 0.85165I

5.5911 − 15.9697I 0

u = 1.198640 + 0.490741I

a = 0.872834 − 0.659332I

b = 0.755641 + 0.177473I

−4.71317 − 7.47420I 0

u = 1.198640 − 0.490741I

a = 0.872834 + 0.659332I

b = 0.755641 − 0.177473I

−4.71317 + 7.47420I 0

u = −0.575685 + 0.399556I

a = 1.31366 + 0.78416I

b = −0.548676 − 0.386355I

−0.700698 − 0.064745I −10.52169 + 0.11838I

u = −0.575685 − 0.399556I

a = 1.31366 − 0.78416I

b = −0.548676 + 0.386355I

−0.700698 + 0.064745I −10.52169 − 0.11838I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.505150

a = 1.23248

b = −0.339414

−0.801265 −12.3320

u = −0.145540 + 0.342331I

a = 2.27747 + 0.36324I

b = −1.183120 − 0.244413I

−1.04760 − 1.10754I −6.89009 + 0.60196I

u = −0.145540 − 0.342331I

a = 2.27747 − 0.36324I

b = −1.183120 + 0.244413I

−1.04760 + 1.10754I −6.89009 − 0.60196I

II.

= hb +1, 2u

+· · · + a −2, u

−2u

−3u

+3u

+2u

−u −1i

(i) Arc colorings















−2u

− u

+ 5u

+ 3u

− 4u

− 3u

− 2u

+ 2

−1





−u

+ u





−2u

− u

+ 5u

+ 3u

− 4u

− 3u

− 2u

+ 1

−1





−1





−2u

− u

+ 5u

+ 3u

− 4u

− 3u

− 2u

+ 2

−1





− u

+ u





− u

+ 1

− 2u

+ 2u





−u

+ u





− u

+ u



(ii) Obstruction class = 1

(iii) Cusp Shapes = 6u

− 5u

− 10u

+ 8u

+ 10u

− 8u

+ 4u

− 8u − 10

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

(u − 1)

, c

(u + 1)

+ u

− 2u

− 3u

+ u

+ 3u

+ 2u

− u − 1

, c

+ 3u

+ 8u

+ 13u

+ 17u

+ 12u

+ 6u

+ u − 1

+ u

+ 2u

+ u

+ 3u

+ u

+ 2u

+ u − 1

− 5u

+ 12u

− 15u

+ 9u

+ u

− 4u

+ 2u

+ u − 1

− u

− 2u

+ 3u

+ u

− 3u

+ 2u

− u + 1

− u

+ 2u

− u

+ 3u

− u

+ 2u

+ u + 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

(y −1)

, c

− 5y

+ 12y

− 15y

+ 9y

+ y

− 4y

+ 2y

+ y −1

, c

+ 7y

+ 20y

+ 25y

+ 5y

− 15y

+ 22y

+ 13y −1

, c

+ 3y

+ 8y

+ 13y

+ 17y

+ 12y

+ 6y

+ y −1

− y

+ 12y

− 7y

+ 37y

+ y

− 10y

+ 5y −1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.772920 + 0.510351I

a = 1.67861 + 2.31573I

b = −1.00000

0.13850 + 2.09337I 0.6725 − 14.2088I

u = −0.772920 − 0.510351I

a = 1.67861 − 2.31573I

b = −1.00000

0.13850 − 2.09337I 0.6725 + 14.2088I

u = 0.825933

a = −0.871015

b = −1.00000

−2.84338 −13.8440

u = 1.173910 + 0.391555I

a = −0.893484 + 0.630694I

b = −1.00000

−6.01628 − 1.33617I −18.6190 + 0.6500I

u = 1.173910 − 0.391555I

a = −0.893484 − 0.630694I

b = −1.00000

−6.01628 + 1.33617I −18.6190 − 0.6500I

u = −0.141484 + 0.739668I

a = 0.309843 + 0.043204I

b = −1.00000

−2.26187 − 2.45442I −11.89962 + 1.90984I

u = −0.141484 − 0.739668I

a = 0.309843 − 0.043204I

b = −1.00000

−2.26187 + 2.45442I −11.89962 − 1.90984I

u = −1.172470 + 0.500383I

a = −0.659464 − 0.874093I

b = −1.00000

−5.24306 + 7.08493I −15.2318 − 2.9321I

u = −1.172470 − 0.500383I

a = −0.659464 + 0.874093I

b = −1.00000

−5.24306 − 7.08493I −15.2318 + 2.9321I

III. u-Polynomials

Crossings u-Polynomials at each crossing

((u − 1)

)(u

+ 20u

+ ··· − 54u + 1)

((u − 1)

)(u

− 10u

+ ··· − 6u + 1)

, c

+ u

+ ··· + 5632u + 512)

((u + 1)

)(u

− 10u

+ ··· − 6u + 1)

+ u

+ ··· − u − 1)(u

+ 2u

+ ··· + 4u + 1)

+ 3u

+ 8u

+ 13u

+ 17u

+ 12u

+ 6u

+ u − 1)

· (u

+ 6u

+ ··· + 1272u + 117)

+ u

+ ··· + u − 1)(u

+ 2u

+ ··· + 4u + 1)

− 5u

+ 12u

− 15u

+ 9u

+ u

− 4u

+ 2u

+ u − 1)

· (u

+ 28u

+ ··· + 6u + 1)

− u

+ ··· − u + 1)(u

+ 2u

+ ··· + 4u + 1)

+ 3u

+ 8u

+ 13u

+ 17u

+ 12u

+ 6u

+ u − 1)

· (u

− 36u

+ ··· + 6u + 1)

− u

+ ··· + u + 1)(u

+ 2u

+ ··· + 4u + 1)

IV. Riley Polynomials

Crossings Riley Polynomials at each crossing

((y −1)

)(y

+ 56y

+ ··· + 398y −1)

, c

((y −1)

)(y

− 20y

+ ··· − 54y −1)

, c

+ 57y

+ ··· + 1.04858 × 10

y −262144)

, c

− 5y

+ 12y

− 15y

+ 9y

+ y

− 4y

+ 2y

+ y −1)

· (y

− 28y

+ ··· + 6y −1)

+ 7y

+ 20y

+ 25y

+ 5y

− 15y

+ 22y

+ 13y −1)

· (y

− 4y

+ ··· + 236682y −13689)

, c

+ 3y

+ 8y

+ 13y

+ 17y

+ 12y

+ 6y

+ y −1)

· (y

+ 36y

+ ··· + 6y −1)

− y

+ 12y

− 7y

+ 37y

+ y

− 10y

+ 5y −1)

· (y

+ 16y

+ ··· − 14y −1)

+ 7y

+ 20y

+ 25y

+ 5y

− 15y

+ 22y

+ 13y −1)

· (y

− 16y

+ ··· + 90y −1)