12n

0304

(K12n

0304

)

A knot diagram

Linearized knot diagam

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

Solving Sequence

2,5

6 3

7,9

10 1 11 4 12 8

, c

Ideals for irreducible components

of X

par

= h−2u

− 5u

+ ··· + b − 2, 2u

+ 5u

+ ··· + 2a − 7, u

+ 3u

+ ··· − 4u + 1i

= hb, a

− au − u

+ a + 2u − 1, u

− u

+ 1i

* 2 irreducible components of dim

= 0, with total 47 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−2u

−5u

+· · ·+b−2, 2u

+5u

+· · ·+2a−7, u

+3u

+· · ·−4u+1i

(i) Arc colorings















−u

+ u





−u

+ 1





−u

−

+ ··· + 4u +

+ 5u

+ ··· − 12u + 2





+ 4u

+ ··· − 8u +

+ 5u

+ ··· − 12u + 2





− u

+ u





+ ··· −

u + 4

+ ··· −

u +





− 2u

+ 2u

− 2u

−u

+ u

− 2u

+ u





−

− u

+ ··· − 6u −

−u

+ 2u

− 4u

+ 4u

+ 2u

− 3u

− 2u

+ 2u





+ u

+ ··· +

u + 2

−

+ ··· +

u −



(ii) Obstruction class = −1

(iii) Cusp Shapes = −

− 20u

+ ··· + 75u −

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

+ 15u

+ ··· + 54u + 1

, c

+ 3u

+ ··· − 4u + 1

− 3u

+ ··· + 2u + 1

, c

− u

+ ··· + 32u + 64

, c

− 4u

+ ··· − u − 1

+ 6u

+ ··· − 25u − 1

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

, c

+ 25y

+ ··· + 1814y −1

, c

− 15y

+ ··· + 54y −1

− 35y

+ ··· + 54y −1

, c

+ 35y

+ ··· − 23552y −4096

, c

− 46y

+ ··· − y −1

+ 38y

+ ··· + 419y −1

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.554966 + 0.821093I

a = 0.497003 − 1.229360I

b = −0.36616 + 1.39788I

−2.41826 − 3.80802I 3.60583 + 3.47707I

u = −0.554966 − 0.821093I

a = 0.497003 + 1.229360I

b = −0.36616 − 1.39788I

−2.41826 + 3.80802I 3.60583 − 3.47707I

u = −0.827605 + 0.515025I

a = −0.328705 + 0.303123I

b = −0.241607 + 0.924234I

1.70931 + 2.07723I 4.47890 − 3.71404I

u = −0.827605 − 0.515025I

a = −0.328705 − 0.303123I

b = −0.241607 − 0.924234I

1.70931 − 2.07723I 4.47890 + 3.71404I

u = 0.776023 + 0.578782I

a = 1.72542 + 0.58271I

b = −0.884835 + 0.226791I

1.60480 − 0.80076I 5.09218 − 0.58482I

u = 0.776023 − 0.578782I

a = 1.72542 − 0.58271I

b = −0.884835 − 0.226791I

1.60480 + 0.80076I 5.09218 + 0.58482I

u = −1.04869

a = 0.0572806

b = −1.17662

3.30786 2.08440

u = −0.613160 + 0.856728I

a = −0.94977 + 1.28570I

b = 0.59049 − 1.37882I

4.75528 − 6.89936I 6.92603 + 2.94505I

u = −0.613160 − 0.856728I

a = −0.94977 − 1.28570I

b = 0.59049 + 1.37882I

4.75528 + 6.89936I 6.92603 − 2.94505I

u = −0.851706 + 0.644533I

a = 0.208645 − 1.142410I

b = 0.123688 − 0.806905I

10.80640 + 2.51167I 3.89555 − 1.99801I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = −0.851706 − 0.644533I

a = 0.208645 + 1.142410I

b = 0.123688 + 0.806905I

10.80640 − 2.51167I 3.89555 + 1.99801I

u = 0.607006 + 0.678640I

a = −2.19270 − 0.14272I

b = 1.058510 − 0.256762I

8.39222 + 0.77239I 9.02070 + 0.54313I

u = 0.607006 − 0.678640I

a = −2.19270 + 0.14272I

b = 1.058510 + 0.256762I

8.39222 − 0.77239I 9.02070 − 0.54313I

u = −0.468903 + 0.772766I

a = 0.050516 + 1.153690I

b = 0.094850 − 1.373440I

−2.97142 + 0.55275I 2.30390 − 2.65158I

u = −0.468903 − 0.772766I

a = 0.050516 − 1.153690I

b = 0.094850 + 1.373440I

−2.97142 − 0.55275I 2.30390 + 2.65158I

u = 0.917493 + 0.603542I

a = −1.30840 − 0.95232I

b = 0.987613 − 0.046245I

1.14349 − 3.91148I 2.83783 + 7.19272I

u = 0.917493 − 0.603542I

a = −1.30840 + 0.95232I

b = 0.987613 + 0.046245I

1.14349 + 3.91148I 2.83783 − 7.19272I

u = 1.145870 + 0.098490I

a = 0.557107 + 1.022870I

b = −0.43743 + 1.53434I

−1.90305 − 5.90674I 0.65317 + 3.76442I

u = 1.145870 − 0.098490I

a = 0.557107 − 1.022870I

b = −0.43743 − 1.53434I

−1.90305 + 5.90674I 0.65317 − 3.76442I

u = 1.150510 + 0.030891I

a = −0.178270 − 1.012240I

b = 0.13939 − 1.59211I

−8.52969 − 2.39687I −2.76728 + 3.02467I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.150510 − 0.030891I

a = −0.178270 + 1.012240I

b = 0.13939 + 1.59211I

−8.52969 + 2.39687I −2.76728 − 3.02467I

u = 0.879522 + 0.766671I

a = 0.349468 − 0.635389I

b = −0.011712 + 0.469579I

3.60760 − 2.89390I −5.91956 + 4.41976I

u = 0.879522 − 0.766671I

a = 0.349468 + 0.635389I

b = −0.011712 − 0.469579I

3.60760 + 2.89390I −5.91956 − 4.41976I

u = −0.318016 + 0.760424I

a = −0.76042 − 1.22775I

b = 0.286457 + 1.371580I

3.09276 + 3.48744I 6.36068 − 3.00060I

u = −0.318016 − 0.760424I

a = −0.76042 + 1.22775I

b = 0.286457 − 1.371580I

3.09276 − 3.48744I 6.36068 + 3.00060I

u = −0.803311 + 0.150840I

a = 0.146401 − 0.020062I

b = 0.412782 − 0.447090I

−1.348790 + 0.350630I −5.34995 − 0.74571I

u = −0.803311 − 0.150840I

a = 0.146401 + 0.020062I

b = 0.412782 + 0.447090I

−1.348790 − 0.350630I −5.34995 + 0.74571I

u = −1.057040 + 0.554919I

a = −1.211900 − 0.182135I

b = −0.13020 + 1.48466I

0.94110 + 1.27702I 2.95191 − 1.84094I

u = −1.057040 − 0.554919I

a = −1.211900 + 0.182135I

b = −0.13020 − 1.48466I

0.94110 − 1.27702I 2.95191 + 1.84094I

u = 1.004470 + 0.646364I

a = 1.16107 + 1.33962I

b = −1.216110 − 0.239593I

7.24069 − 5.93073I 6.53956 + 5.01754I

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 1.004470 − 0.646364I

a = 1.16107 − 1.33962I

b = −1.216110 + 0.239593I

7.24069 + 5.93073I 6.53956 − 5.01754I

u = 0.891105 + 0.826186I

a = −0.68311 + 1.33083I

b = 0.038155 − 1.007650I

10.04850 − 3.07313I 5.86480 + 2.85684I

u = 0.891105 − 0.826186I

a = −0.68311 − 1.33083I

b = 0.038155 + 1.007650I

10.04850 + 3.07313I 5.86480 − 2.85684I

u = −1.066370 + 0.630817I

a = 1.70734 + 0.08552I

b = −0.22070 − 1.52920I

−4.70291 + 4.72137I 0. − 2.49884I

u = −1.066370 − 0.630817I

a = 1.70734 − 0.08552I

b = −0.22070 + 1.52920I

−4.70291 − 4.72137I 0. + 2.49884I

u = −1.067020 + 0.674301I

a = −2.03641 − 0.00933I

b = 0.45680 + 1.50432I

−3.95261 + 9.40997I 2.00000 − 7.76812I

u = −1.067020 − 0.674301I

a = −2.03641 + 0.00933I

b = 0.45680 − 1.50432I

−3.95261 − 9.40997I 2.00000 + 7.76812I

u = −1.061600 + 0.708976I

a = 2.31095 − 0.08552I

b = −0.65644 − 1.43319I

3.38790 + 12.73300I 5.12799 − 7.34194I

u = −1.061600 − 0.708976I

a = 2.31095 + 0.08552I

b = −0.65644 + 1.43319I

3.38790 − 12.73300I 5.12799 + 7.34194I

u = 0.530791

a = −3.58500

b = 0.511824

8.14249 16.8230

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.153263

a = 3.39924

b = −0.382289

0.765123 13.2670

II. I

= hb, a

− au − u

+ a + 2u − 1, u

− u

+ 1i

(i) Arc colorings















−u

+ u + 1





−u

+ 1













− 1

−u





−au

−u

a + au + a









− a − u

−u





au − u + 1

a − au − a



(ii) Obstruction class = 1

(iii) Cusp Shapes = u

a − 3u

+ a + 8u + 7

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

, c

− u

+ 2u − 1)

+ u

− 1)

, c

− u

+ 1)

+ u

+ 2u + 1)

, c

− 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

− 3y + 1)

(vi) Complex Volumes and Cusp Shapes

Solutions to I

√

−1(vol +

√

−1CS) Cusp shape

u = 0.877439 + 0.744862I

a = −0.198308 + 1.205210I

b = 0

11.90680 − 2.82812I 11.55793 + 3.24268I

u = 0.877439 + 0.744862I

a = 0.075747 − 0.460350I

b = 0

4.01109 − 2.82812I 14.0681 + 1.5771I

u = 0.877439 − 0.744862I

a = −0.198308 − 1.205210I

b = 0

11.90680 + 2.82812I 11.55793 − 3.24268I

u = 0.877439 − 0.744862I

a = 0.075747 + 0.460350I

b = 0

4.01109 + 2.82812I 14.0681 − 1.5771I

u = −0.754878

a = 1.08457

b = 0

−0.126494 0.954070

u = −0.754878

a = −2.83945

b = 0

7.76919 −5.20600

III. u-Polynomials

Crossings u-Polynomials at each crossing

((u

− u

+ 2u − 1)

)(u

+ 15u

+ ··· + 54u + 1)

((u

+ u

− 1)

)(u

+ 3u

+ ··· − 4u + 1)

((u

− u

+ 2u − 1)

)(u

− 3u

+ ··· + 2u + 1)

, c

− u

+ ··· + 32u + 64)

((u

− u

+ 1)

)(u

+ 3u

+ ··· − 4u + 1)

((u

+ u

+ 2u + 1)

)(u

+ 15u

+ ··· + 54u + 1)

, c

((u

− u − 1)

)(u

− 4u

+ ··· − u − 1)

((u

− u − 1)

)(u

+ 6u

+ ··· − 25u − 1)

, c

((u

+ u − 1)

)(u

− 4u

+ ··· − u − 1)

IV. Riley Polynomials

Crossings Riley Polynomials at each crossing

, c

((y

+ 3y

+ 2y −1)

)(y

+ 25y

+ ··· + 1814y −1)

, c

((y

− y

+ 2y −1)

)(y

− 15y

+ ··· + 54y −1)

((y

+ 3y

+ 2y −1)

)(y

− 35y

+ ··· + 54y −1)

, c

+ 35y

+ ··· − 23552y −4096)

, c

((y

− 3y + 1)

)(y

− 46y

+ ··· − y −1)

((y

− 3y + 1)

)(y

+ 38y

+ ··· + 419y −1)