Planar Diagrams: Difference between revisions

Latest revision as of 18:08, 21 February 2013

KnotTheory`/Navigation

The Mathematica Package KnotTheory`

The PD notation

In the "Planar Diagrams" (PD) presentation we present every knot or link diagram by labeling its edges (with natural numbers, 1,...,n, and with increasing labels as we go around each component) and by a list crossings presented as symbols $X_{ijkl}$ where $i$ , $j$ , $k$ and $l$ are the labels of the edges around that crossing, starting from the incoming lower edge and proceeding counterclockwise. Thus for example, the PD presentation of the knot above is:

X_{1928}X_{3,10,4,11}X_{5362}X_{7,1,8,12}X_{9,4,10,5}X_{11,7,12,6}.

(This of course is the Miller Institute knot, the mirror image of the knot 6_2)

(For In[1] see Setup)

In[2]:=	?PD
PD[v1, v2, ...] represents a planar diagram whose vertices are v1, v2, .... PD also acts as a "type caster", so for example, PD[K] where K is a named knot (or link) returns the PD presentation of that knot.

In[3]:=	PD::about
The GaussCode to PD conversion was written by Siddarth Sankaran at the University of Toronto in the summer of 2005.

In[4]:=	?X
X[i,j,k,l] represents a crossing between the edges labeled i, j, k and l starting from the incoming lower strand i and going counterclockwise through j, k and l. The (sometimes ambiguous) orientation of the upper strand is determined by the ordering of {j,l}.

Thus, for example, let us compute the determinant of the above knot:

In[5]:= K = PD[ X[1,9,2,8], X[3,10,4,11], X[5,3,6,2], X[7,1,8,12], X[9,4,10,5], X[11,7,12,6] ];

`In[6]:=`	`Alexander[K][-1]`
`Out[6]=`	`-11`

Some further details

In[7]:=	?Xp
Xp[i,j,k,l] represents a positive (right handed) crossing between the edges labeled i, j, k and l starting from the incoming lower strand i and going counter clockwise through j, k and l. The upper strand is therefore oriented from l to j regardless of the ordering of {j,l}. Presently Xp is only lightly supported.

In[8]:=	?Xm
Xm[i,j,k,l] represents a negative (left handed) crossing between the edges labeled i, j, k and l starting from the incoming lower strand i and going counter clockwise through j, k and l. The upper strand is therefore oriented from j to l regardless of the ordering of {j,l}. Presently Xm is only lightly supported.

In[9]:=	?P
P[i,j] represents a bivalent vertex whose adjacent edges are i and j (i.e., a "Point" between the segment i and the segment j). Presently P is only lightly supported.

For example, we could add an extra "point" on the Miller Institute knot, splitting edge 12 into two pieces, labeled 12 and 13:

In[10]:= K1 = PD[ X[1,9,2,8], X[3,10,4,11], X[5,3,6,2], X[7,1,8,13], X[9,4,10,5], X[11,7,12,6], P[12,13] ];

At the moment, many of our routines do not know to ignore such "extra points". But some do:

`In[11]:=`	`Jones[K][q] == Jones[K1][q]`
`Out[11]=`	`True`

In[12]:=	?Loop
Loop[i] represents a crossingsless loop labeled i.

Hence we can verify that the A2 invariant of the unknot is $q^{-2}+1+q^{2}$ :

`In[13]:=`	`A2Invariant[Loop[1]][q]`
`Out[13]=`	`-2 2 1 + q + q`

@@ Line 15: / Line 15: @@
 <!--Robot Land, no human edits to "END"-->
 {{HelpAndAbout|
-n  = 1 |
+n  = 2 |
-n1 = 2 |
+n1 = 3 |
 in = <nowiki>PD</nowiki> |
-out= <nowiki>PD[v1, v2, ...] represents a planar diagram whose vertices are v1, v2, .... PD also acts as a "type caster", so for example, PD[K] where K is is a named knot (or link) returns the PD presentation of that knot.</nowiki> |
+out= <nowiki>PD[v1, v2, ...] represents a planar diagram whose vertices are v1, v2, .... PD also acts as a "type caster", so for example, PD[K] where K is a named knot (or link) returns the PD presentation of that knot.</nowiki> |
-about= <nowiki>The PD to GaussCode and to MorseLink conversions were written by Siddarth Sankaran at the University of Toronto in the summer of 2005.</nowiki>}}
+about= <nowiki>The GaussCode to PD conversion was written by Siddarth Sankaran at the University of Toronto in the summer of 2005.</nowiki>}}
 <!--END-->
@@ Line 25: / Line 25: @@
 <!--Robot Land, no human edits to "END"-->
 {{HelpLine|
-n  = 3 |
+n  = 4 |
 in = <nowiki>X</nowiki> |
 out= <nowiki>X[i,j,k,l] represents a crossing between the edges labeled i, j, k and l starting from the incoming lower strand i and going counterclockwise through j, k and l. The (sometimes ambiguous) orientation of the upper strand is determined by the ordering of {j,l}.</nowiki>}}
@@ Line 38: / Line 38: @@
 <!--Robot Land, no human edits to "END"-->
 {{In|
-n  = 4 |
+n  = 5 |
+in = <nowiki>K = PD[
-in = <nowiki>K = PD[X[1,9,2,8], X[3,10,4,11], X[5,3,6,2], X[7,1,8,12], X[9,4,10,5], X[11,7,12,6]];</nowiki>}}
+  X[1,9,2,8], X[3,10,4,11], X[5,3,6,2],
+  X[7,1,8,12], X[9,4,10,5], X[11,7,12,6]
+];</nowiki>}}
 <!--END-->
@@ Line 45: / Line 48: @@
 <!--Robot Land, no human edits to "END"-->
 {{InOut|
-n  = 5 |
+n  = 6 |
 in = <nowiki>Alexander[K][-1]</nowiki> |
 out= <nowiki>-11</nowiki>}}
@@ Line 57: / Line 60: @@
 <!--Robot Land, no human edits to "END"-->
 {{HelpLine|
-n  = 6 |
+n  = 7 |
 in = <nowiki>Xp</nowiki> |
 out= <nowiki>Xp[i,j,k,l] represents a positive (right handed) crossing between the edges labeled i, j, k and l starting from the incoming lower strand i and going counter clockwise through j, k and l. The upper strand is therefore oriented from l to j regardless of the ordering of {j,l}. Presently Xp is only lightly supported.</nowiki>}}
@@ Line 65: / Line 68: @@
 <!--Robot Land, no human edits to "END"-->
 {{HelpLine|
-n  = 7 |
+n  = 8 |
 in = <nowiki>Xm</nowiki> |
 out= <nowiki>Xm[i,j,k,l] represents a negative (left handed) crossing between the edges labeled i, j, k and l starting from the incoming lower strand i and going counter clockwise through j, k and l. The upper strand is therefore oriented from j to l regardless of the ordering of {j,l}. Presently Xm is only lightly supported.</nowiki>}}
@@ Line 73: / Line 76: @@
 <!--Robot Land, no human edits to "END"-->
 {{HelpLine|
-n  = 8 |
+n  = 9 |
 in = <nowiki>P</nowiki> |
 out= <nowiki>P[i,j] represents a bivalent vertex whose adjacent edges are i and j (i.e., a "Point" between the segment i and the segment j). Presently P is only lightly supported.</nowiki>}}
@@ Line 80: / Line 83: @@
 For example, we could add an extra "point" on the Miller Institute knot, splitting edge 12 into two pieces, labeled 12 and 13:
+<!--$$K1 = PD[
-<!--$$K1 = PD[X[1,9,2,8], X[3,10,4,11], X[5,3,6,2], X[7,1,8,13], X[9,4,10,5], X[11,7,12,6], P[12,13]];$$-->
+  X[1,9,2,8], X[3,10,4,11], X[5,3,6,2],
+  X[7,1,8,13], X[9,4,10,5], X[11,7,12,6],
+  P[12,13]
+];$$-->
 <!--Robot Land, no human edits to "END"-->
 {{In|
-n  = 9 |
+n  = 10 |
+in = <nowiki>K1 = PD[
-in = <nowiki>K1 = PD[X[1,9,2,8], X[3,10,4,11], X[5,3,6,2], X[7,1,8,13], X[9,4,10,5], X[11,7,12,6], P[12,13]];</nowiki>}}
+  X[1,9,2,8], X[3,10,4,11], X[5,3,6,2],
+  X[7,1,8,13], X[9,4,10,5], X[11,7,12,6],
+  P[12,13]
+];</nowiki>}}
 <!--END-->
@@ Line 92: / Line 103: @@
 <!--Robot Land, no human edits to "END"-->
 {{InOut|
-n  = 10 |
+n  = 11 |
 in = <nowiki>Jones[K][q] == Jones[K1][q]</nowiki> |
 out= <nowiki>True</nowiki>}}
@@ Line 100: / Line 111: @@
 <!--Robot Land, no human edits to "END"-->
 {{HelpLine|
-n  = 11 |
+n  = 12 |
 in = <nowiki>Loop</nowiki> |
 out= <nowiki>Loop[i] represents a crossingsless loop labeled i.</nowiki>}}
@@ Line 110: / Line 121: @@
 <!--Robot Land, no human edits to "END"-->
 {{InOut|
-n  = 12 |
+n  = 13 |
 in = <nowiki>A2Invariant[Loop[1]][q]</nowiki> |
 out= <nowiki>     -2    2

Planar Diagrams: Difference between revisions

Latest revision as of 18:08, 21 February 2013

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