12a

0092

(K12a

0092

)

A knot diagram

Linearized knot diagam

3 5 8 2 10 11 4 12 7 6 1 9

Solving Sequence

5,10

6 11

3,7

2 1 4 8 9 12

, c

Ideals for irreducible components

of X

par

= h−1.29904 × 10

129

111

+ 2.66514 × 10

129

110

+ ··· + 3.21272 × 10

129

b + 1.30058 × 10

129

5.52996 × 10

129

111

− 1.09032 × 10

130

110

+ ··· + 6.42545 × 10

129

a − 1.03393 × 10

130

112

− 2u

111

+ ··· + 24u + 8i

= hb + 1, 2u

− u

− 5u

+ 2u

+ 3u

+ a + 2u − 1, u

− u

− 3u

+ 2u

+ 3u

− 2u − 1i

= h32a

u + 14a

+ 6au + 463b + 292a + 118u − 122, 4a

+ 6a

u − 4a

+ 8au + 3u − 20, u

− 2i

= ha, −v

+ b + 3v + 1, v

− 2v

− 3v −1i

* 4 irreducible components of dim

= 0, with total 129 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−1.30 × 10

129

111

+ 2.67 × 10

129

110

+ · · · + 3.21 × 10

129

b + 1.30 ×

129

, 5.53 × 10

129

111

− 1.09 × 10

130

110

+ · · · + 6.43 × 10

129

a − 1.03 ×

130

, u

112

− 2u

111

+ · · · + 24u + 8i

(i) Arc colorings











−u





−u

+ u





−0.860634u

111

+ 1.69688u

110

+ ··· + 1.28833u + 1.60912

0.404343u

111

− 0.829559u

110

+ ··· − 2.02982u − 0.404820





−u

+ 1

− 2u





−0.456291u

111

+ 0.867320u

110

+ ··· − 0.741493u + 1.20430

0.404343u

111

− 0.829559u

110

+ ··· − 2.02982u − 0.404820





0.0400195u

111

− 0.574902u

110

+ ··· + 6.54098u + 2.08781

−0.0638486u

111

+ 0.551541u

110

+ ··· − 3.22913u − 1.01041





0.278988u

111

− 0.807051u

110

+ ··· + 0.947750u + 3.03165

−0.597516u

111

+ 1.47686u

110

+ ··· + 0.793252u − 1.62436





0.0413526u

111

− 0.529064u

110

+ ··· + 4.64588u + 1.51965

0.183846u

111

+ 0.260857u

110

+ ··· − 9.04776u − 3.12862





−u

+ 2u

− u

− 3u

+ 2u

+ u





−0.0392866u

111

− 0.413970u

110

+ ··· + 9.42044u + 2.69703

−0.101407u

111

+ 0.424993u

110

+ ··· − 2.32534u − 0.770762



(ii) Obstruction class = −1

(iii) Cusp Shapes = 1.31338u

111

− 3.41480u

110

+ ··· + 22.4635u + 1.55814

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

112

+ 52u

111

+ ··· + 2998u + 1

, c

112

− 12u

111

+ ··· + 54u + 1

, c

112

+ 2u

111

+ ··· + 2688u − 256

, c

112

− 2u

111

+ ··· + 24u + 8

, c

112

− 5u

111

+ ··· − 113u + 7

112

+ 6u

111

+ ··· + 84024u + 12200

112

− 57u

111

+ ··· − 4733u + 49

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

112

+ 28y

111

+ ··· − 8620798y + 1

, c

112

− 52y

111

+ ··· − 2998y + 1

, c

112

+ 60y

111

+ ··· − 3850240y + 65536

, c

112

− 104y

111

+ ··· − 960y + 64

, c

112

− 57y

111

+ ··· − 4733y + 49

112

− 8y

111

+ ··· − 4167168576y + 148840000

112

+ 7y

111

+ ··· − 16407805y + 2401

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −1.018720 + 0.149036I

a = 0.076859 − 0.861231I

b = −1.158720 + 0.319869I

−1.29796 − 1.03206I 0

u = −1.018720 − 0.149036I

a = 0.076859 + 0.861231I

b = −1.158720 − 0.319869I

−1.29796 + 1.03206I 0

u = 0.814215 + 0.446584I

a = −0.037466 − 0.261223I

b = 1.067950 + 0.549015I

0.00125 − 3.68506I 0

u = 0.814215 − 0.446584I

a = −0.037466 + 0.261223I

b = 1.067950 − 0.549015I

0.00125 + 3.68506I 0

u = −0.711966 + 0.574552I

a = −0.174449 + 0.367324I

b = 1.131830 − 0.614451I

1.90412 + 8.94633I 0

u = −0.711966 − 0.574552I

a = −0.174449 − 0.367324I

b = 1.131830 + 0.614451I

1.90412 − 8.94633I 0

u = 1.036270 + 0.398425I

a = 0.447897 + 0.876758I

b = 0.979382 − 0.404050I

−0.78854 + 2.81223I 0

u = 1.036270 − 0.398425I

a = 0.447897 − 0.876758I

b = 0.979382 + 0.404050I

−0.78854 − 2.81223I 0

u = 1.116570 + 0.051427I

a = 0.657850 − 0.997380I

b = −0.177665 + 0.553771I

1.74796 + 0.16171I 0

u = 1.116570 − 0.051427I

a = 0.657850 + 0.997380I

b = −0.177665 − 0.553771I

1.74796 − 0.16171I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.110930 + 0.219371I

a = −0.14481 − 1.71768I

b = −1.153040 + 0.367430I

−1.22070 + 3.54389I 0

u = 1.110930 − 0.219371I

a = −0.14481 + 1.71768I

b = −1.153040 − 0.367430I

−1.22070 − 3.54389I 0

u = −0.355833 + 0.788222I

a = 1.05625 − 1.50575I

b = 1.170610 + 0.637818I

0.72546 − 13.62000I 0. + 9.98825I

u = −0.355833 − 0.788222I

a = 1.05625 + 1.50575I

b = 1.170610 − 0.637818I

0.72546 + 13.62000I 0. − 9.98825I

u = 0.146754 + 0.822078I

a = 0.893745 + 0.277347I

b = 0.911228 + 0.313596I

−3.54227 + 1.59081I 1.56582 + 2.52489I

u = 0.146754 − 0.822078I

a = 0.893745 − 0.277347I

b = 0.911228 − 0.313596I

−3.54227 − 1.59081I 1.56582 − 2.52489I

u = −1.167790 + 0.097848I

a = 0.725202 − 0.286646I

b = 0.881268 − 0.521081I

6.34503 + 2.09810I 0

u = −1.167790 − 0.097848I

a = 0.725202 + 0.286646I

b = 0.881268 + 0.521081I

6.34503 − 2.09810I 0

u = −0.624872 + 0.541441I

a = 0.485440 − 1.097800I

b = 0.392106 + 0.829105I

4.11190 + 3.56494I 7.21254 − 1.29951I

u = −0.624872 − 0.541441I

a = 0.485440 + 1.097800I

b = 0.392106 − 0.829105I

4.11190 − 3.56494I 7.21254 + 1.29951I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.274658 + 0.777797I

a = 1.28184 + 1.22191I

b = 1.134650 − 0.590961I

−1.75122 + 8.04540I −0.69722 − 6.48181I

u = 0.274658 − 0.777797I

a = 1.28184 − 1.22191I

b = 1.134650 + 0.590961I

−1.75122 − 8.04540I −0.69722 + 6.48181I

u = −0.011399 + 0.820861I

a = 1.141370 + 0.028393I

b = 1.003200 − 0.397478I

−4.15841 + 4.21135I −1.12819 − 7.26950I

u = −0.011399 − 0.820861I

a = 1.141370 − 0.028393I

b = 1.003200 + 0.397478I

−4.15841 − 4.21135I −1.12819 + 7.26950I

u = −0.358023 + 0.736800I

a = −0.605113 + 0.240449I

b = 0.369589 − 0.924331I

3.15487 − 7.91029I 5.30872 + 6.56414I

u = −0.358023 − 0.736800I

a = −0.605113 − 0.240449I

b = 0.369589 + 0.924331I

3.15487 + 7.91029I 5.30872 − 6.56414I

u = 0.303360 + 0.725677I

a = −0.65527 − 1.79904I

b = −1.015110 + 0.566452I

−1.69797 + 7.17522I 0.68379 − 7.57915I

u = 0.303360 − 0.725677I

a = −0.65527 + 1.79904I

b = −1.015110 − 0.566452I

−1.69797 − 7.17522I 0.68379 + 7.57915I

u = 0.652565 + 0.422024I

a = 0.774209 + 0.886160I

b = −0.995831 − 0.466362I

−0.38831 − 3.14093I 2.48859 + 2.59563I

u = 0.652565 − 0.422024I

a = 0.774209 − 0.886160I

b = −0.995831 + 0.466362I

−0.38831 + 3.14093I 2.48859 − 2.59563I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −1.217770 + 0.231362I

a = 0.066728 + 0.949450I

b = 0.002019 − 0.679432I

2.29898 − 4.70132I 0

u = −1.217770 − 0.231362I

a = 0.066728 − 0.949450I

b = 0.002019 + 0.679432I

2.29898 + 4.70132I 0

u = −0.263923 + 0.703760I

a = −0.978990 + 0.422628I

b = −1.309070 + 0.166176I

−2.65149 − 4.51648I 1.07409 + 6.59561I

u = −0.263923 − 0.703760I

a = −0.978990 − 0.422628I

b = −1.309070 − 0.166176I

−2.65149 + 4.51648I 1.07409 − 6.59561I

u = 0.294109 + 0.686488I

a = −0.364849 + 0.009699I

b = 0.339982 + 0.789548I

0.57903 + 2.86162I 2.21640 − 3.05288I

u = 0.294109 − 0.686488I

a = −0.364849 − 0.009699I

b = 0.339982 − 0.789548I

0.57903 − 2.86162I 2.21640 + 3.05288I

u = −1.196320 + 0.379749I

a = 0.446586 − 1.195840I

b = 1.071020 + 0.461092I

−0.50009 − 8.52415I 0

u = −1.196320 − 0.379749I

a = 0.446586 + 1.195840I

b = 1.071020 − 0.461092I

−0.50009 + 8.52415I 0

u = 0.584146 + 0.424260I

a = 0.495792 + 0.880233I

b = 0.508203 − 0.602695I

1.72036 + 0.90594I 4.78781 − 4.00969I

u = 0.584146 − 0.424260I

a = 0.495792 − 0.880233I

b = 0.508203 + 0.602695I

1.72036 − 0.90594I 4.78781 + 4.00969I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.229960 + 0.360736I

a = 0.037108 + 0.251367I

b = 0.915433 + 0.334717I

−0.329456 + 0.040199I 0

u = 1.229960 − 0.360736I

a = 0.037108 − 0.251367I

b = 0.915433 − 0.334717I

−0.329456 − 0.040199I 0

u = −0.654491 + 0.272544I

a = 0.04579 + 1.78125I

b = −1.182700 − 0.184351I

−1.085270 + 0.846553I 3.79032 − 3.13132I

u = −0.654491 − 0.272544I

a = 0.04579 − 1.78125I

b = −1.182700 + 0.184351I

−1.085270 − 0.846553I 3.79032 + 3.13132I

u = −0.188194 + 0.675147I

a = −1.11851 + 1.65238I

b = −1.051720 − 0.452819I

−3.69167 − 2.26136I −3.60384 + 2.58351I

u = −0.188194 − 0.675147I

a = −1.11851 − 1.65238I

b = −1.051720 + 0.452819I

−3.69167 + 2.26136I −3.60384 − 2.58351I

u = 0.240940 + 0.637061I

a = 0.719669 + 0.632063I

b = −0.562579 − 0.604506I

−0.34785 + 2.50804I 1.82220 − 3.40193I

u = 0.240940 − 0.637061I

a = 0.719669 − 0.632063I

b = −0.562579 + 0.604506I

−0.34785 − 2.50804I 1.82220 + 3.40193I

u = 0.112061 + 0.664682I

a = −1.48275 + 0.14053I

b = −1.214020 − 0.246890I

−4.20929 − 0.20936I −3.46102 − 1.21494I

u = 0.112061 − 0.664682I

a = −1.48275 − 0.14053I

b = −1.214020 + 0.246890I

−4.20929 + 0.20936I −3.46102 + 1.21494I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −1.327970 + 0.003111I

a = −0.87431 + 1.66645I

b = 0.894917 − 0.825816I

8.09882 + 3.06301I 0

u = −1.327970 − 0.003111I

a = −0.87431 − 1.66645I

b = 0.894917 + 0.825816I

8.09882 − 3.06301I 0

u = 1.324830 + 0.184519I

a = 1.29142 + 1.08887I

b = −0.530536 − 0.575105I

2.68371 + 1.14617I 0

u = 1.324830 − 0.184519I

a = 1.29142 − 1.08887I

b = −0.530536 + 0.575105I

2.68371 − 1.14617I 0

u = −0.332085 + 0.570168I

a = −0.823871 − 0.740483I

b = 0.570546 − 0.745691I

5.19659 + 0.52268I 7.07371 + 1.25938I

u = −0.332085 − 0.570168I

a = −0.823871 + 0.740483I

b = 0.570546 + 0.745691I

5.19659 − 0.52268I 7.07371 − 1.25938I

u = −0.213775 + 0.619265I

a = 2.33602 − 1.25730I

b = 1.026980 + 0.623990I

3.82789 − 4.68728I 3.46609 + 6.29400I

u = −0.213775 − 0.619265I

a = 2.33602 + 1.25730I

b = 1.026980 − 0.623990I

3.82789 + 4.68728I 3.46609 − 6.29400I

u = −1.339170 + 0.244598I

a = 0.128580 + 0.409997I

b = −1.292610 + 0.172501I

0.35822 − 3.05224I 0

u = −1.339170 − 0.244598I

a = 0.128580 − 0.409997I

b = −1.292610 − 0.172501I

0.35822 + 3.05224I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.003632 + 0.612874I

a = 0.533006 − 0.318247I

b = −0.213424 + 0.523869I

−1.41839 + 1.56464I −0.45093 − 4.40997I

u = −0.003632 − 0.612874I

a = 0.533006 + 0.318247I

b = −0.213424 − 0.523869I

−1.41839 − 1.56464I −0.45093 + 4.40997I

u = −1.38959

a = 0.908732

b = −0.0184563

6.53354 0

u = −1.346640 + 0.354641I

a = −0.027424 − 0.336567I

b = 0.849993 − 0.240388I

1.14529 − 5.82695I 0

u = −1.346640 − 0.354641I

a = −0.027424 + 0.336567I

b = 0.849993 + 0.240388I

1.14529 + 5.82695I 0

u = 1.372090 + 0.263367I

a = 0.10678 − 2.41007I

b = −1.015250 + 0.548202I

1.26200 + 5.66357I 0

u = 1.372090 − 0.263367I

a = 0.10678 + 2.41007I

b = −1.015250 − 0.548202I

1.26200 − 5.66357I 0

u = 1.389480 + 0.176832I

a = −1.12892 − 1.39935I

b = 1.035730 + 0.807448I

9.96290 + 0.00502I 0

u = 1.389480 − 0.176832I

a = −1.12892 + 1.39935I

b = 1.035730 − 0.807448I

9.96290 − 0.00502I 0

u = −0.333286 + 0.497276I

a = 0.205344 − 0.950156I

b = 0.722048 + 0.843897I

5.42986 − 3.71507I 6.56090 + 8.40821I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.333286 − 0.497276I

a = 0.205344 + 0.950156I

b = 0.722048 − 0.843897I

5.42986 + 3.71507I 6.56090 − 8.40821I

u = 1.398300 + 0.107009I

a = −0.59433 − 1.65394I

b = −1.165440 − 0.052793I

5.03887 + 0.33340I 0

u = 1.398300 − 0.107009I

a = −0.59433 + 1.65394I

b = −1.165440 + 0.052793I

5.03887 − 0.33340I 0

u = −1.394040 + 0.168090I

a = −0.05486 + 2.88093I

b = −0.899734 − 0.466308I

6.09712 − 2.33253I 0

u = −1.394040 − 0.168090I

a = −0.05486 − 2.88093I

b = −0.899734 + 0.466308I

6.09712 + 2.33253I 0

u = 1.386180 + 0.248074I

a = 0.67456 + 2.27430I

b = 1.098480 − 0.642310I

8.93573 + 7.87318I 0

u = 1.386180 − 0.248074I

a = 0.67456 − 2.27430I

b = 1.098480 + 0.642310I

8.93573 − 7.87318I 0

u = −1.39563 + 0.25220I

a = 1.35096 − 1.26835I

b = −0.652912 + 0.690244I

4.87673 − 5.76508I 0

u = −1.39563 − 0.25220I

a = 1.35096 + 1.26835I

b = −0.652912 − 0.690244I

4.87673 + 5.76508I 0

u = 1.41403 + 0.20520I

a = −0.39049 + 1.93565I

b = 0.695558 − 0.941026I

10.99240 + 6.37614I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.41403 − 0.20520I

a = −0.39049 − 1.93565I

b = 0.695558 + 0.941026I

10.99240 − 6.37614I 0

u = 1.43186

a = 7.47358

b = −0.970695

4.97680 0

u = 1.40615 + 0.27781I

a = 0.451286 − 0.581959I

b = −1.358830 − 0.131787I

2.67390 + 8.08693I 0

u = 1.40615 − 0.27781I

a = 0.451286 + 0.581959I

b = −1.358830 + 0.131787I

2.67390 − 8.08693I 0

u = 1.42100 + 0.21744I

a = −1.228290 − 0.553828I

b = 0.474203 + 0.831698I

10.80900 + 2.37680I 0

u = 1.42100 − 0.21744I

a = −1.228290 + 0.553828I

b = 0.474203 − 0.831698I

10.80900 − 2.37680I 0

u = −1.41572 + 0.27049I

a = −0.978454 + 0.922450I

b = 0.368700 − 0.903629I

6.03543 − 6.35471I 0

u = −1.41572 − 0.27049I

a = −0.978454 − 0.922450I

b = 0.368700 + 0.903629I

6.03543 + 6.35471I 0

u = −1.44321 + 0.10269I

a = −0.43536 − 1.61858I

b = 0.716567 + 0.769054I

8.22583 − 2.63796I 0

u = −1.44321 − 0.10269I

a = −0.43536 + 1.61858I

b = 0.716567 − 0.769054I

8.22583 + 2.63796I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −1.41705 + 0.31061I

a = 0.23451 − 2.12729I

b = 1.162710 + 0.631820I

3.63940 − 11.98600I 0

u = −1.41705 − 0.31061I

a = 0.23451 + 2.12729I

b = 1.162710 − 0.631820I

3.63940 + 11.98600I 0

u = −1.42523 + 0.28547I

a = 0.28388 + 2.43754I

b = −0.995964 − 0.623300I

3.82611 − 10.85450I 0

u = −1.42523 − 0.28547I

a = 0.28388 − 2.43754I

b = −0.995964 + 0.623300I

3.82611 + 10.85450I 0

u = −1.46859 + 0.11194I

a = 1.69922 − 1.26036I

b = −0.841564 + 0.435407I

6.34093 + 1.39160I 0

u = −1.46859 − 0.11194I

a = 1.69922 + 1.26036I

b = −0.841564 − 0.435407I

6.34093 − 1.39160I 0

u = 1.45063 + 0.28488I

a = −1.11139 − 1.11493I

b = 0.397230 + 0.978223I

8.9567 + 11.6332I 0

u = 1.45063 − 0.28488I

a = −1.11139 + 1.11493I

b = 0.397230 − 0.978223I

8.9567 − 11.6332I 0

u = 1.45761 + 0.30717I

a = 0.05506 + 2.27142I

b = 1.184370 − 0.665894I

6.5408 + 17.6016I 0

u = 1.45761 − 0.30717I

a = 0.05506 − 2.27142I

b = 1.184370 + 0.665894I

6.5408 − 17.6016I 0

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −1.50703 + 0.02402I

a = −0.74209 + 1.21258I

b = 0.927314 − 0.617513I

7.63433 + 2.61707I 0

u = −1.50703 − 0.02402I

a = −0.74209 − 1.21258I

b = 0.927314 + 0.617513I

7.63433 − 2.61707I 0

u = 1.50704 + 0.14911I

a = −0.10240 + 1.73413I

b = 0.513892 − 0.813284I

11.06290 − 1.16602I 0

u = 1.50704 − 0.14911I

a = −0.10240 − 1.73413I

b = 0.513892 + 0.813284I

11.06290 + 1.16602I 0

u = −0.237025 + 0.395062I

a = 0.003829 + 0.713299I

b = 0.958789 − 0.771571I

4.74030 + 2.24272I 3.61623 + 6.16785I

u = −0.237025 − 0.395062I

a = 0.003829 − 0.713299I

b = 0.958789 + 0.771571I

4.74030 − 2.24272I 3.61623 − 6.16785I

u = 1.53699 + 0.12427I

a = −0.99596 − 1.13045I

b = 1.073900 + 0.645562I

9.38113 − 6.62724I 0

u = 1.53699 − 0.12427I

a = −0.99596 + 1.13045I

b = 1.073900 − 0.645562I

9.38113 + 6.62724I 0

u = 0.276680 + 0.321195I

a = −0.57913 − 4.82110I

b = −0.757806 + 0.273988I

0.771024 + 0.267712I 2.70998 − 9.56080I

u = 0.276680 − 0.321195I

a = −0.57913 + 4.82110I

b = −0.757806 − 0.273988I

0.771024 − 0.267712I 2.70998 + 9.56080I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.417834

a = 1.69611

b = −0.141393

0.992954 11.5370

u = −0.236458

a = 2.76698

b = −0.881202

−1.26916 −9.80040

II. I

hb+1, 2u

−u

−5u

+2u

+3u

+a+2u−1, u

−u

−3u

+2u

+3u

−2u−1i

(i) Arc colorings











−u





−u

+ u





−2u

+ u

+ 5u

− 2u

− 3u

− 2u + 1

−1





−u

+ 1

− 2u





−2u

+ u

+ 5u

− 2u

− 3u

− 2u

−1





−1





−2u

+ u

+ 5u

− 2u

− 3u

− 2u + 1

−1





−u

+ 1

− 2u





−u

+ 2u

− u

− 3u

+ 2u

+ u





−u

+ 2u

−u

+ u



(ii) Obstruction class = 1

(iii) Cusp Shapes = 4u

+ 9u

− 10u

− 27u

− 2u

+ 18u

+ 20u + 17

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

(u − 1)

, c

(u + 1)

, c

− u

− 3u

+ 2u

+ 3u

− 2u − 1

+ u

− u

− 2u

+ u

+ 2u

− 2u − 1

− 3u

+ 7u

− 10u

+ 11u

− 10u

+ 6u

− 4u + 1

+ u

− 3u

− 2u

+ 3u

+ 2u − 1

+ 3u

+ 7u

+ 10u

+ 11u

+ 10u

+ 6u

+ 4u + 1

− u

+ 2u

+ u

− 2u

+ 2u − 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

(y −1)

, c

− 7y

+ 19y

− 22y

+ 3y

+ 14y

− 6y

− 4y + 1

, c

− 3y

+ 7y

− 10y

+ 11y

− 10y

+ 6y

− 4y + 1

, c

+ 5y

+ 11y

+ 6y

− 17y

− 34y

− 22y

− 4y + 1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −1.180120 + 0.268597I

a = −0.085690 + 0.514779I

b = −1.00000

−0.604279 − 1.131230I 1.38132 + 1.25921I

u = −1.180120 − 0.268597I

a = −0.085690 − 0.514779I

b = −1.00000

−0.604279 + 1.131230I 1.38132 − 1.25921I

u = −0.108090 + 0.747508I

a = −1.036110 + 0.260696I

b = −1.00000

−3.80435 − 2.57849I −1.74277 + 4.63100I

u = −0.108090 − 0.747508I

a = −1.036110 − 0.260696I

b = −1.00000

−3.80435 + 2.57849I −1.74277 − 4.63100I

u = 1.37100

a = −3.88842

b = −1.00000

4.85780 25.4550

u = 1.334530 + 0.318930I

a = 0.043072 − 0.634428I

b = −1.00000

0.73474 + 6.44354I 1.71699 − 7.87618I

u = 1.334530 − 0.318930I

a = 0.043072 + 0.634428I

b = −1.00000

0.73474 − 6.44354I 1.71699 + 7.87618I

u = −0.463640

a = 2.04588

b = −1.00000

−0.799899 10.8330

III.

= h32a

u+6au+· · ·+292a −122, 4a

+6a

u−4a

+8au+3u−20, u

−2i

(i) Arc colorings











−2





−u





−0.0691145a

u − 0.0129590au + ··· − 0.630670a + 0.263499





−1





−0.0691145a

u − 0.0129590au + ··· + 0.369330a + 0.263499

−0.0691145a

u − 0.0129590au + ··· − 0.630670a + 0.263499





0.0604752a

u + 0.261339au + ··· + 0.0518359a − 0.980562

−0.0604752a

u − 0.261339au + ··· − 0.0518359a + 0.980562





0.0453564a

u − 0.0539957au + ··· + 0.0388769a + 0.764579

0.00863931a

u − 0.248380au + ··· + 0.578834a − 0.282937





0.0604752a

u + 0.261339au + ··· + 0.0518359a − 0.980562

−0.0604752a

u − 0.261339au + ··· − 0.0518359a + 0.980562





−u





0.0604752a

u + 0.261339au + ··· + 0.0518359a − 0.980562

−0.0604752a

u − 0.261339au + ··· − 0.0518359a + 0.980562



(ii) Obstruction class = 1

(iii) Cusp Shapes = −

128

463

u −

463

−

463

au −

1168

463

a −

472

463

u +

4192

463

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

− u

+ 2u − 1)

+ u

− 1)

+ u

+ 2u + 1)

− u

+ 1)

, c

− 2)

(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 −2)

, c

(y −1)

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.41421

a = 0.865932

b = −0.754878

5.46628 4.98050

u = 1.41421

a = −0.99363 + 1.88732I

b = 0.877439 − 0.744862I

9.60386 + 2.82812I 11.50976 − 2.97945I

u = 1.41421

a = −0.99363 − 1.88732I

b = 0.877439 + 0.744862I

9.60386 − 2.82812I 11.50976 + 2.97945I

u = −1.41421

a = −0.516129 + 1.092130I

b = 0.877439 − 0.744862I

9.60386 + 2.82812I 11.50976 − 2.97945I

u = −1.41421

a = −0.516129 − 1.092130I

b = 0.877439 + 0.744862I

9.60386 − 2.82812I 11.50976 + 2.97945I

u = −1.41421

a = 4.15358

b = −0.754878

5.46628 4.98050

IV. I

= ha, −v

+ b + 3v + 1, v

− 2v

− 3v − 1i

(i) Arc colorings



















− 3v − 1









− 3v − 1





− 3v − 1

−v

+ 2v + 3





−2v

+ 5v + 4

−2v

+ 5v + 3





−v

+ 3v + 1

− 2v − 3









− 2v − 1

−v

+ 2v + 3



(ii) Obstruction class = 1

(iii) Cusp Shapes = 8v

− 26v − 14

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

− u

+ 2u − 1

+ u

− 1

− u

+ 1

, c

+ u

+ 2u + 1

, c

(u + 1)

(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)

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

v = −0.539798 + 0.182582I

a = 0

b = 0.877439 − 0.744862I

4.66906 + 2.82812I 2.09911 − 6.32406I

v = −0.539798 − 0.182582I

a = 0

b = 0.877439 + 0.744862I

4.66906 − 2.82812I 2.09911 + 6.32406I

v = 3.07960

a = 0

b = −0.754878

0.531480 −18.1980

V. u-Polynomials

Crossings u-Polynomials at each crossing

((u − 1)

)(u

− u

+ 2u − 1)

112

+ 52u

111

+ ··· + 2998u + 1)

((u − 1)

)(u

+ u

− 1)

112

− 12u

111

+ ··· + 54u + 1)

− u

+ 2u − 1)(u

+ u

+ 2u + 1)

· (u

112

+ 2u

111

+ ··· + 2688u − 256)

((u + 1)

)(u

− u

+ 1)

112

− 12u

111

+ ··· + 54u + 1)

, c

− 2)

− u

− 3u

+ 2u

+ 3u

− 2u − 1)

· (u

112

− 2u

111

+ ··· + 24u + 8)

− u

+ 2u − 1)

+ u

+ 2u + 1)

· (u

112

+ 2u

111

+ ··· + 2688u − 256)

(u − 1)

(u + 1)

+ u

− u

− 2u

+ u

+ 2u

− 2u − 1)

· (u

112

− 5u

111

+ ··· − 113u + 7)

− 2)

− 3u

+ 7u

− 10u

+ 11u

− 10u

+ 6u

− 4u + 1)

· (u

112

+ 6u

111

+ ··· + 84024u + 12200)

− 2)

+ u

− 3u

− 2u

+ 3u

+ 2u − 1)

· (u

112

− 2u

111

+ ··· + 24u + 8)

(u + 1)

+ 3u

+ 7u

+ 10u

+ 11u

+ 10u

+ 6u

+ 4u + 1)

· (u

112

− 57u

111

+ ··· − 4733u + 49)

(u − 1)

(u + 1)

− u

+ 2u

+ u

− 2u

+ 2u − 1)

· (u

112

− 5u

111

+ ··· − 113u + 7)

VI. Riley Polynomials

Crossings Riley Polynomials at each crossing

((y − 1)

)(y

+ 3y

+ 2y − 1)

112

+ 28y

111

+ ··· − 8620798y + 1)

, c

((y − 1)

)(y

− y

+ 2y − 1)

112

− 52y

111

+ ··· − 2998y + 1)

, c

+ 3y

+ 2y − 1)

112

+ 60y

111

+ ··· − 3850240y + 65536)

, c

(y − 2)

− 7y

+ 19y

− 22y

+ 3y

+ 14y

− 6y

− 4y + 1)

· (y

112

− 104y

111

+ ··· − 960y + 64)

, c

(y − 1)

− 3y

+ 7y

− 10y

+ 11y

− 10y

+ 6y

− 4y + 1)

· (y

112

− 57y

111

+ ··· − 4733y + 49)

(y − 2)

+ 5y

+ 11y

+ 6y

− 17y

− 34y

− 22y

− 4y + 1)

· (y

112

− 8y

111

+ ··· − 4167168576y + 148840000)

(y − 1)

+ 5y

+ 11y

+ 6y

− 17y

− 34y

− 22y

− 4y + 1)

· (y

112

+ 7y

111

+ ··· − 16407805y + 2401)