11n

161

(K11n

161

)

A knot diagram

1

Linearized knot diagam

9 8 1 10 2 3 1 6 5 4 8

Solving Sequence

2,9 1,6

5 10 4 8 3 7 11

c

1

c

5

c

9

c

4

c

8

c

2

c

7

c

11

c

3

, c

6

, c

10

Ideals for irreducible components

2

of X

par

I

u

1

= hb − u, −32825u

16

− 78351u

15

+ ··· + 149349a + 108694,

u

17

+ u

16

− u

15

− u

14

+ 9u

13

+ 7u

12

− 5u

11

− 2u

10

+ 18u

9

+ 12u

8

− 4u

7

− 5u

6

+ 5u

5

− u

4

− u

3

− u

2

+ u − 1i

I

u

2

= h1.70203 × 10

30

u

23

+ 4.57303 × 10

30

u

22

+ ··· + 8.77268 × 10

30

b + 5.47196 × 10

31

,

− 6.45612 × 10

27

u

23

− 1.61756 × 10

28

u

22

+ ··· + 5.13568 × 10

28

a − 1.36907 × 10

29

,

u

24

+ 3u

23

+ ··· + 46u + 11i

I

u

3

= hb + u, −14u

9

− u

8

+ 16u

7

− 3u

6

− 69u

5

+ 26u

4

+ 25u

3

− 21u

2

+ 5a − 20u − 12,

u

10

+ u

9

− u

8

− u

7

+ 5u

6

+ 3u

5

− 3u

4

− u

3

+ 3u

2

+ 3u + 1i

* 3 irreducible components of dim

C

= 0, with total 51 representations.

1

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).

2

All coeﬃcients of polynomials are rational numbers. But the coeﬃcients are sometimes approximated

in decimal forms when there is not enough margin.

1

I. I

u

1

= hb − u, −3.28 × 10

4

u

16

− 7.84 × 10

4

u

15

+ · · · + 1.49 × 10

5

a + 1.09 ×

10

5

, u

17

+ u

16

+ · · · + u − 1i

(i) Arc colorings

a

2

=



1

0



a

9

=



0

u



a

1

=



1

u

2



a

6

=



0.219787u

16

+ 0.524617u

15

+ ··· + 1.20532u − 0.727785

u



a

5

=



0.219787u

16

+ 0.524617u

15

+ ··· + 0.205324u − 0.727785

u



a

10

=



0.966327u

16

+ 1.11448u

15

+ ··· − 2.99444u + 1.19912

−0.0803353u

16

− 0.516903u

15

+ ··· + 1.08504u − 0.304830



a

4

=



0.265559u

16

+ 0.586479u

15

+ ··· + 3.63417u + 1.42934

−0.537426u

16

− 0.452303u

15

+ ··· + 0.266865u − 0.452979



a

8

=



0.805657u

16

+ 0.0806701u

15

+ ··· − 2.82436u + 0.589458

−0.0803353u

16

− 0.516903u

15

+ ··· + 1.08504u − 0.304830



a

3

=



0.567001u

16

+ 0.839992u

15

+ ··· + 3.95640u + 0.655438

−0.544229u

16

− 0.276594u

15

+ ··· + 0.616234u − 0.500907



a

7

=



0.385085u

16

− 0.447562u

15

+ ··· − 3.26996u + 1.00962

0.245726u

16

− 0.325151u

15

+ ··· + 0.772131u − 0.412490



a

11

=



0.175562u

16

+ 1.94315u

15

+ ··· + 2.59534u + 1.27888

−0.301442u

16

− 0.253514u

15

+ ··· − 0.322225u + 0.773899



a

11

=



0.175562u

16

+ 1.94315u

15

+ ··· + 2.59534u + 1.27888

−0.301442u

16

− 0.253514u

15

+ ··· − 0.322225u + 0.773899



(ii) Obstruction class = −1

(iii) Cusp Shapes =

163298

149349

u

16

+

580790

149349

u

15

+ ··· +

328192

149349

u −

306609

49783

2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

, c

5

u

17

− u

16

+ ··· + u + 1

c

2

u

17

− 2u

15

+ ··· − u − 2

c

3

u

17

− 14u

16

+ ··· − 32u − 64

c

4

, c

9

, c

10

u

17

+ 9u

16

+ ··· + 144u + 16

c

6

, c

7

, c

11

u

17

+ u

16

+ ··· + u + 1

c

8

u

17

+ 12u

16

+ ··· + 64u + 8

3

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

, c

5

y

17

− 3y

16

+ ··· − y −1

c

2

y

17

− 4y

16

+ ··· + 29y −4

c

3

y

17

− 14y

16

+ ··· + 50688y −4096

c

4

, c

9

, c

10

y

17

+ 15y

16

+ ··· − 128y −256

c

6

, c

7

, c

11

y

17

− 23y

16

+ ··· + 9y −1

c

8

y

17

+ 4y

16

+ ··· − 608y −64

4

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = −0.736595 + 0.759560I

a = −0.631113 + 0.062721I

b = −0.736595 + 0.759560I

−0.05757 − 2.36290I −6.52154 + 3.94257I

u = −0.736595 − 0.759560I

a = −0.631113 − 0.062721I

b = −0.736595 − 0.759560I

−0.05757 + 2.36290I −6.52154 − 3.94257I

u = −1.008910 + 0.431442I

a = −0.889354 − 0.979858I

b = −1.008910 + 0.431442I

1.14436 − 6.14847I −1.51565 + 5.18000I

u = −1.008910 − 0.431442I

a = −0.889354 + 0.979858I

b = −1.008910 − 0.431442I

1.14436 + 6.14847I −1.51565 − 5.18000I

u = −0.534388 + 0.570811I

a = −2.28268 + 0.49285I

b = −0.534388 + 0.570811I

−5.66005 − 1.97491I −5.96248 + 6.00520I

u = −0.534388 − 0.570811I

a = −2.28268 − 0.49285I

b = −0.534388 − 0.570811I

−5.66005 + 1.97491I −5.96248 − 6.00520I

u = 0.700751

a = 2.48391

b = 0.700751

−3.84845 2.74050

u = 0.902645 + 0.958889I

a = 1.194590 + 0.162669I

b = 0.902645 + 0.958889I

−6.98471 + 8.59095I −7.08514 − 6.35872I

u = 0.902645 − 0.958889I

a = 1.194590 − 0.162669I

b = 0.902645 − 0.958889I

−6.98471 − 8.59095I −7.08514 + 6.35872I

u = 0.482184 + 0.448786I

a = −1.16928 − 1.33243I

b = 0.482184 + 0.448786I

5.38217 + 1.40715I −2.06078 − 4.92367I

5

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = 0.482184 − 0.448786I

a = −1.16928 + 1.33243I

b = 0.482184 − 0.448786I

5.38217 − 1.40715I −2.06078 + 4.92367I

u = 0.175989 + 0.585685I

a = 0.864699 + 0.113620I

b = 0.175989 + 0.585685I

−0.850953 − 0.696665I −8.07292 + 4.89884I

u = 0.175989 − 0.585685I

a = 0.864699 − 0.113620I

b = 0.175989 − 0.585685I

−0.850953 + 0.696665I −8.07292 − 4.89884I

u = 1.14438 + 0.95543I

a = 0.540728 + 0.095251I

b = 1.14438 + 0.95543I

7.19647 + 4.49345I −5.42758 + 0.47721I

u = 1.14438 − 0.95543I

a = 0.540728 − 0.095251I

b = 1.14438 − 0.95543I

7.19647 − 4.49345I −5.42758 − 0.47721I

u = −1.27568 + 1.06823I

a = −0.869544 + 0.210846I

b = −1.27568 + 1.06823I

−0.71290 − 13.72760I −3.72416 + 7.05259I

u = −1.27568 − 1.06823I

a = −0.869544 − 0.210846I

b = −1.27568 − 1.06823I

−0.71290 + 13.72760I −3.72416 − 7.05259I

6

II. I

u

2

= h1.70 × 10

30

u

23

+ 4.57 × 10

30

u

22

+ · · · + 8.77 × 10

30

b + 5.47 ×

10

31

, −6.46 × 10

27

u

23

− 1.62 × 10

28

u

22

+ · · · + 5.14 × 10

28

a − 1.37 ×

10

29

, u

24

+ 3u

23

+ · · · + 46u + 11i

(i) Arc colorings

a

2

=



1

0



a

9

=



0

u



a

1

=



1

u

2



a

6

=



0.125711u

23

+ 0.314966u

22

+ ··· + 7.79270u + 2.66581

−0.194014u

23

− 0.521280u

22

+ ··· − 10.4641u − 6.23750



a

5

=



0.319725u

23

+ 0.836246u

22

+ ··· + 18.2568u + 8.90330

−0.194014u

23

− 0.521280u

22

+ ··· − 10.4641u − 6.23750



a

10

=



−0.0116621u

23

− 0.0806554u

22

+ ··· + 4.00812u − 3.44719

−0.175665u

23

− 0.437895u

22

+ ··· − 9.21681u − 2.60383



a

4

=



−0.240478u

23

− 0.644174u

22

+ ··· − 11.8851u − 8.16867

0.0316958u

23

+ 0.103215u

22

+ ··· + 0.735566u + 2.15396



a

8

=



−0.190587u

23

− 0.510517u

22

+ ··· − 7.93355u − 4.80896

−0.00326046u

23

+ 0.00803404u

22

+ ··· − 0.724864u + 1.24206



a

3

=



−0.190071u

23

− 0.496722u

22

+ ··· − 10.2408u − 5.16485

0.0231595u

23

+ 0.0870786u

22

+ ··· + 0.354516u + 2.19543



a

7

=



−0.148842u

23

− 0.367537u

22

+ ··· − 7.93760u − 2.89321

−0.0152103u

23

− 0.0113006u

22

+ ··· − 2.00024u + 1.04689



a

11

=



0.240478u

23

+ 0.644174u

22

+ ··· + 11.8851u + 8.16867

−0.0504074u

23

− 0.147452u

22

+ ··· − 1.64431u − 3.00383



a

11

=



0.240478u

23

+ 0.644174u

22

+ ··· + 11.8851u + 8.16867

−0.0504074u

23

− 0.147452u

22

+ ··· − 1.64431u − 3.00383



(ii) Obstruction class = −1

(iii) Cusp Shapes = 0.802694u

23

+ 2.06436u

22

+ ··· + 39.8732u + 14.4982

7

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

, c

5

u

24

− 3u

23

+ ··· − 46u + 11

c

2

u

24

− u

23

+ ··· − 178u + 59

c

3

(u

4

+ 3u

3

+ u

2

− 2u + 1)

6

c

4

, c

9

, c

10

(u

3

− u

2

+ 2u − 1)

8

c

6

, c

7

, c

11

u

24

− u

23

+ ··· − 568u + 89

c

8

(u

4

− u

3

+ u

2

+ 1)

6

8

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

, c

5

y

24

− 5y

23

+ ··· − 1544y + 121

c

2

y

24

− 9y

23

+ ··· − 77232y + 3481

c

3

(y

4

− 7y

3

+ 15y

2

− 2y + 1)

6

c

4

, c

9

, c

10

(y

3

+ 3y

2

+ 2y −1)

8

c

6

, c

7

, c

11

y

24

− 21y

23

+ ··· − 204788y + 7921

c

8

(y

4

+ y

3

+ 3y

2

+ 2y + 1)

6

9

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

2

√

−1(vol +

√

−1CS) Cusp shape

u = −0.726600 + 0.525022I

a = 0.174808 + 1.380500I

b = 0.834345 + 0.058079I

4.88007 + 0.33584I −2.66351 + 0.41465I

u = −0.726600 − 0.525022I

a = 0.174808 − 1.380500I

b = 0.834345 − 0.058079I

4.88007 − 0.33584I −2.66351 − 0.41465I

u = 0.834345 + 0.058079I

a = −1.09167 − 1.01623I

b = −0.726600 + 0.525022I

4.88007 + 0.33584I −2.66351 + 0.41465I

u = 0.834345 − 0.058079I

a = −1.09167 + 1.01623I

b = −0.726600 − 0.525022I

4.88007 − 0.33584I −2.66351 − 0.41465I

u = −0.951037 + 0.715358I

a = 1.032340 − 0.181700I

b = 0.649666 − 0.469539I

0.74248 − 3.16396I −9.19277 + 2.56480I

u = −0.951037 − 0.715358I

a = 1.032340 + 0.181700I

b = 0.649666 + 0.469539I

0.74248 + 3.16396I −9.19277 − 2.56480I

u = 0.649666 + 0.469539I

a = −1.52720 − 0.29894I

b = −0.951037 − 0.715358I

0.74248 + 3.16396I −9.19277 − 2.56480I

u = 0.649666 − 0.469539I

a = −1.52720 + 0.29894I

b = −0.951037 + 0.715358I

0.74248 − 3.16396I −9.19277 + 2.56480I

u = −0.238976 + 1.192720I

a = −0.637456 − 0.167240I

b = −1.72582 − 0.12950I

−2.12168 + 1.41302I −6.31698 + 1.92930I

u = −0.238976 − 1.192720I

a = −0.637456 + 0.167240I

b = −1.72582 + 0.12950I

−2.12168 − 1.41302I −6.31698 − 1.92930I

10

Solutions to I

u

2

√

−1(vol +

√

−1CS) Cusp shape

u = 0.168821 + 0.703789I

a = 1.081210 − 0.240521I

b = 1.26487 − 1.00614I

−6.25926 + 1.41510I −12.84625 − 4.90874I

u = 0.168821 − 0.703789I

a = 1.081210 + 0.240521I

b = 1.26487 + 1.00614I

−6.25926 − 1.41510I −12.84625 + 4.90874I

u = −0.939501 + 0.901901I

a = 0.956419 − 0.051833I

b = 1.53236 − 0.89026I

4.88007 − 5.99209I −2.66351 + 5.54425I

u = −0.939501 − 0.901901I

a = 0.956419 + 0.051833I

b = 1.53236 + 0.89026I

4.88007 + 5.99209I −2.66351 − 5.54425I

u = −0.369838 + 0.105617I

a = −1.39380 + 1.54969I

b = −0.99828 − 1.87172I

−2.12168 − 4.24323I −6.31698 + 7.88819I

u = −0.369838 − 0.105617I

a = −1.39380 − 1.54969I

b = −0.99828 + 1.87172I

−2.12168 + 4.24323I −6.31698 − 7.88819I

u = 1.26487 + 1.00614I

a = −0.107103 − 0.484305I

b = 0.168821 − 0.703789I

−6.25926 − 1.41510I −12.84625 + 4.90874I

u = 1.26487 − 1.00614I

a = −0.107103 + 0.484305I

b = 0.168821 + 0.703789I

−6.25926 + 1.41510I −12.84625 − 4.90874I

u = −1.72582 + 0.12950I

a = −0.171564 − 0.430263I

b = −0.238976 − 1.192720I

−2.12168 − 1.41302I −6.31698 − 1.92930I

u = −1.72582 − 0.12950I

a = −0.171564 + 0.430263I

b = −0.238976 + 1.192720I

−2.12168 + 1.41302I −6.31698 + 1.92930I

11

Solutions to I

u

2

√

−1(vol +

√

−1CS) Cusp shape

u = 1.53236 + 0.89026I

a = −0.673917 − 0.203172I

b = −0.939501 − 0.901901I

4.88007 + 5.99209I −2.66351 − 5.54425I

u = 1.53236 − 0.89026I

a = −0.673917 + 0.203172I

b = −0.939501 + 0.901901I

4.88007 − 5.99209I −2.66351 + 5.54425I

u = −0.99828 + 1.87172I

a = 0.221577 − 0.306137I

b = −0.369838 − 0.105617I

−2.12168 + 4.24323I −5.00000 − 7.88819I

u = −0.99828 − 1.87172I

a = 0.221577 + 0.306137I

b = −0.369838 + 0.105617I

−2.12168 − 4.24323I −5.00000 + 7.88819I

12

III. I

u

3

= hb + u, −14u

9

− u

8

+ · · · + 5a − 12, u

10

+ u

9

+ · · · + 3u + 1i

(i) Arc colorings

a

2

=



1

0



a

9

=



0

u



a

1

=



1

u

2



a

6

=



14

5

u

9

+

1

5

u

8

+ ··· + 4u +

12

5

−u



a

5

=



14

5

u

9

+

1

5

u

8

+ ··· + 5u +

12

5

−u



a

10

=



−

6

5

u

9

−

4

5

u

8

+ ··· − 2u −

13

5

11

5

u

9

+

4

5

u

8

+ ··· + 6u +

13

5



a

4

=



−

29

5

u

9

−

11

5

u

8

+ ··· − 15u −

42

5

−2u

9

− u

8

+ 3u

7

+ u

6

− 11u

5

− u

4

+ 8u

3

− 2u

2

− 6u − 3



a

8

=



16

5

u

9

+

4

5

u

8

+ ··· + 8u +

13

5

11

5

u

9

+

4

5

u

8

+ ··· + 6u +

13

5



a

3

=



−

28

5

u

9

−

12

5

u

8

+ ··· − 16u −

39

5

−

6

5

u

9

−

4

5

u

8

+ ··· − 5u −

13

5



a

7

=



18

5

u

9

+

7

5

u

8

+ ··· + 10u +

14

5

9

5

u

9

+

6

5

u

8

+ ··· + 5u +

12

5



a

11

=



−

12

5

u

9

+

2

5

u

8

+ ··· − 3u −

11

5

−

1

5

u

9

+

1

5

u

8

+ ··· + u −

3

5



a

11

=



−

12

5

u

9

+

2

5

u

8

+ ··· − 3u −

11

5

−

1

5

u

9

+

1

5

u

8

+ ··· + u −

3

5



(ii) Obstruction class = 1

(iii) Cusp Shapes

=

34

5

u

9

+

16

5

u

8

−

56

5

u

7

−

17

5

u

6

+

184

5

u

5

+

9

5

u

4

− 31u

3

+

31

5

u

2

+ 18u +

42

5

13

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

, c

5

u

10

+ u

9

− u

8

− u

7

+ 5u

6

+ 3u

5

− 3u

4

− u

3

+ 3u

2

+ 3u + 1

c

2

u

10

− 2u

8

+ 4u

6

+ 2u

5

+ 4u

4

+ 5u

3

+ 2u

2

+ 2u + 5

c

3

u

10

+ 7u

9

+ ··· + 8u + 5

c

4

u

10

+ 6u

8

− u

7

+ 12u

6

− 3u

5

+ 8u

4

− u

3

+ 2u + 1

c

6

, c

11

u

10

− u

9

− 3u

8

+ 4u

7

− u

5

+ 4u

4

− 3u

3

+ 4u

2

− u + 1

c

7

u

10

+ u

9

− 3u

8

− 4u

7

+ u

5

+ 4u

4

+ 3u

3

+ 4u

2

+ u + 1

c

8

u

10

− 3u

9

+ 6u

8

− 6u

7

+ 6u

6

− 6u

5

+ 9u

4

− 6u

3

+ 3u

2

+ 1

c

9

, c

10

u

10

+ 6u

8

+ u

7

+ 12u

6

+ 3u

5

+ 8u

4

+ u

3

− 2u + 1

14

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

, c

5

y

10

− 3y

9

+ 13y

8

− 23y

7

+ 45y

6

− 51y

5

+ 49y

4

− 27y

3

+ 9y

2

− 3y + 1

c

2

y

10

− 4y

9

+ 12y

8

− 8y

7

+ 4y

6

+ 30y

5

− 8y

4

+ 23y

3

+ 24y

2

+ 16y + 25

c

3

y

10

− 7y

9

+ ··· + 246y + 25

c

4

, c

9

, c

10

y

10

+ 12y

9

+ ··· − 4y + 1

c

6

, c

7

, c

11

y

10

− 7y

9

+ 17y

8

− 10y

7

− 14y

6

− y

5

+ 12y

4

+ 21y

3

+ 18y

2

+ 7y + 1

c

8

y

10

+ 3y

9

+ ··· + 6y + 1

15

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

3

√

−1(vol +

√

−1CS) Cusp shape

u = 0.914248 + 0.570518I

a = −1.119990 − 0.219282I

b = −0.914248 − 0.570518I

1.60755 + 3.42301I 1.79285 − 5.67056I

u = 0.914248 − 0.570518I

a = −1.119990 + 0.219282I

b = −0.914248 + 0.570518I

1.60755 − 3.42301I 1.79285 + 5.67056I

u = −0.727640 + 0.146538I

a = 0.66217 + 1.95900I

b = 0.727640 − 0.146538I

6.16667 + 0.45837I 4.93396 + 0.07525I

u = −0.727640 − 0.146538I

a = 0.66217 − 1.95900I

b = 0.727640 + 0.146538I

6.16667 − 0.45837I 4.93396 − 0.07525I

u = 0.914629 + 0.935183I

a = −0.112008 − 0.341459I

b = −0.914629 − 0.935183I

−2.02274 − 3.06369I −5.25989 + 0.93808I

u = 0.914629 − 0.935183I

a = −0.112008 + 0.341459I

b = −0.914629 + 0.935183I

−2.02274 + 3.06369I −5.25989 − 0.93808I

u = −0.380408 + 0.491558I

a = 0.39322 − 1.67428I

b = 0.380408 − 0.491558I

−5.23124 + 0.62784I −5.27518 + 0.19626I

u = −0.380408 − 0.491558I

a = 0.39322 + 1.67428I

b = 0.380408 + 0.491558I

−5.23124 − 0.62784I −5.27518 − 0.19626I

u = −1.22083 + 0.93479I

a = 0.676610 − 0.110678I

b = 1.22083 − 0.93479I

7.70444 − 5.09459I 1.80827 + 6.72626I

u = −1.22083 − 0.93479I

a = 0.676610 + 0.110678I

b = 1.22083 + 0.93479I

7.70444 + 5.09459I 1.80827 − 6.72626I

16

IV. u-Polynomials

Crossings u-Polynomials at each crossing

c

1

, c

5

(u

10

+ u

9

− u

8

− u

7

+ 5u

6

+ 3u

5

− 3u

4

− u

3

+ 3u

2

+ 3u + 1)

· (u

17

− u

16

+ ··· + u + 1)(u

24

− 3u

23

+ ··· − 46u + 11)

c

2

(u

10

− 2u

8

+ 4u

6

+ 2u

5

+ 4u

4

+ 5u

3

+ 2u

2

+ 2u + 5)

· (u

17

− 2u

15

+ ··· − u − 2)(u

24

− u

23

+ ··· − 178u + 59)

c

3

((u

4

+ 3u

3

+ u

2

− 2u + 1)

6

)(u

10

+ 7u

9

+ ··· + 8u + 5)

· (u

17

− 14u

16

+ ··· − 32u − 64)

c

4

(u

3

− u

2

+ 2u − 1)

8

(u

10

+ 6u

8

− u

7

+ 12u

6

− 3u

5

+ 8u

4

− u

3

+ 2u + 1)

· (u

17

+ 9u

16

+ ··· + 144u + 16)

c

6

, c

11

(u

10

− u

9

− 3u

8

+ 4u

7

− u

5

+ 4u

4

− 3u

3

+ 4u

2

− u + 1)

· (u

17

+ u

16

+ ··· + u + 1)(u

24

− u

23

+ ··· − 568u + 89)

c

7

(u

10

+ u

9

− 3u

8

− 4u

7

+ u

5

+ 4u

4

+ 3u

3

+ 4u

2

+ u + 1)

· (u

17

+ u

16

+ ··· + u + 1)(u

24

− u

23

+ ··· − 568u + 89)

c

8

(u

4

− u

3

+ u

2

+ 1)

6

· (u

10

− 3u

9

+ 6u

8

− 6u

7

+ 6u

6

− 6u

5

+ 9u

4

− 6u

3

+ 3u

2

+ 1)

· (u

17

+ 12u

16

+ ··· + 64u + 8)

c

9

, c

10

(u

3

− u

2

+ 2u − 1)

8

(u

10

+ 6u

8

+ u

7

+ 12u

6

+ 3u

5

+ 8u

4

+ u

3

− 2u + 1)

· (u

17

+ 9u

16

+ ··· + 144u + 16)

17

V. Riley Polynomials

Crossings Riley Polynomials at each crossing

c

1

, c

5

(y

10

− 3y

9

+ 13y

8

− 23y

7

+ 45y

6

− 51y

5

+ 49y

4

− 27y

3

+ 9y

2

− 3y + 1)

· (y

17

− 3y

16

+ ··· − y −1)(y

24

− 5y

23

+ ··· − 1544y + 121)

c

2

(y

10

− 4y

9

+ 12y

8

− 8y

7

+ 4y

6

+ 30y

5

− 8y

4

+ 23y

3

+ 24y

2

+ 16y + 25)

· (y

17

− 4y

16

+ ··· + 29y −4)(y

24

− 9y

23

+ ··· − 77232y + 3481)

c

3

((y

4

− 7y

3

+ 15y

2

− 2y + 1)

6

)(y

10

− 7y

9

+ ··· + 246y + 25)

· (y

17

− 14y

16

+ ··· + 50688y −4096)

c

4

, c

9

, c

10

((y

3

+ 3y

2

+ 2y −1)

8

)(y

10

+ 12y

9

+ ··· − 4y + 1)

· (y

17

+ 15y

16

+ ··· − 128y −256)

c

6

, c

7

, c

11

(y

10

− 7y

9

+ 17y

8

− 10y

7

− 14y

6

− y

5

+ 12y

4

+ 21y

3

+ 18y

2

+ 7y + 1)

· (y

17

− 23y

16

+ ··· + 9y −1)(y

24

− 21y

23

+ ··· − 204788y + 7921)

c

8

((y

4

+ y

3

+ 3y

2

+ 2y + 1)

6

)(y

10

+ 3y

9

+ ··· + 6y + 1)

· (y

17

+ 4y

16

+ ··· − 608y −64)

18