(For In[1] see Setup)
| In[2]:=
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?SymmetryType
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| SymmetryType[K] returns the symmetry type of the knot K, if known to KnotTheory`. The possible types are: Reversible, FullyAmphicheiral, NegativeAmphicheiral and Chiral.
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| In[3]:=
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SymmetryType::about
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| The symmetry type data known to KnotTheory` is taken from Charles Livingston's "Table of Knot Invariants", http://www.indiana.edu/~knotinfo/.
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The inverse of a knot 
is the knot obtained from it by reversing its parametrization. The mirror of A knot is obtained from by reversing the orientation of the ambient space, or, alternatively, by flipping all the crossings of .
A knot is called "fully amphicheiral" if it is equal to its inverse and also to its mirror. The first knot with this property is
In[4]:=
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Select[AllKnots[], (SymmetryType[#] == FullyAmphicheiral) &, 1]
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Out[4]=
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{Knot[4, 1]}
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A knot is called "reversible" if it is equal to its inverse yet it different from its mirror (and hence also from the inverse of its mirror). Many knots have this property; indeed, the first one is:
In[5]:=
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Select[AllKnots[], (SymmetryType[#] == Reversible) &, 1]
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Out[5]=
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{Knot[3, 1]}
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A knot is called "positive amphicheiral" if it is different from its inverse but equal to its mirror. There are no such knots with up to 11 crossings.
A knot is called "negative amphicheiral" if it is different from its inverse and its mirror, yet it is equal to the inverse of its mirror. The first knot with this property is
In[6]:=
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Select[AllKnots[], (SymmetryType[#] == NegativeAmphicheiral) &, 1]
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Out[6]=
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{Knot[8, 17]}
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Finally, if a knot is different from its inverse, its mirror and from the inverse of its mirror, it is "chiral". The first such knot is
In[7]:=
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Select[AllKnots[], (SymmetryType[#] == Chiral) &, 1]
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Out[7]=
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{Knot[9, 32]}
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It is a amusing to take "symmetry type" statistics on all the prime knots with up to 11 crossings:
In[8]:=
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Plus @@ (SymmetryType /@ Rest[AllKnots[]])
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Out[8]=
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216 Chiral + 13 FullyAmphicheiral + 7 NegativeAmphicheiral +
565 Reversible
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The unknotting number of a knot is the minimal number of crossing changes needed in order to unknot .
| In[9]:=
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?UnknottingNumber
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| UnknottingNumber[K] returns the unknotting number of the knot K, if known to KnotTheory`. If only a range of possible values is known, a list of the form {min, max} is returned.
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| In[10]:=
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UnknottingNumber::about
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| The unknotting numbers of torus knots are due to ???. All other unknotting numbers known to KnotTheory` are taken from Charles Livingston's "Table of Knot Invariants", http://www.indiana.edu/~knotinfo/.
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Of the 512 knots whose unknotting number is known to KnotTheory`, 197 have unknotting number 1, 247 have unknotting number 2, 54 have unknotting number 3, 12 have unknotting number 4 and 1 has unknotting number 5:
In[11]:=
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Plus @@ u /@ Cases[UnknottingNumber /@ AllKnots[], _Integer]
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Out[11]=
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u[0] + 197 u[1] + 247 u[2] + 54 u[3] + 12 u[4] + u[5]
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There are 4 knots with up to 9 crossings whose unknotting number is unknown:
In[12]:=
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Select[AllKnots[],
Crossings[#] <= 9 && Head[UnknottingNumber[#]] === List &
]
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Out[12]=
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{Knot[9, 10], Knot[9, 13], Knot[9, 35], Knot[9, 38]}
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| In[13]:=
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?ThreeGenus
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| ThreeGenus[K] returns the 3-genus of the knot K, if known to KnotTheory`.
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| In[14]:=
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ThreeGenus::about
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| The 3-genus data known to KnotTheory` is taken from Charles Livingston's "Table of Knot Invariants", http://www.indiana.edu/~knotinfo/.
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The bridge index' of a knot is the minimal number of local maxima (or local minima) in a generic smooth embedding of in 
.
| In[15]:=
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?BridgeIndex
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| BridgeIndex[K] returns the bridge index of the knot K, if known to KnotTheory`.
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| In[16]:=
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BridgeIndex::about
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| The bridge index data known to KnotTheory` is taken from Charles Livingston's "Table of Knot Invariants", http://www.indiana.edu/~knotinfo/.
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An often studied class of knots is the class of 2-bridge knots, knots whose bridge index is 2. Of the 49 9-crossings knots, 24 are 2-bridge:
In[17]:=
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Select[AllKnots[], Crossings[#] == 9 && BridgeIndex[#] == 2 &]
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Out[17]=
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{Knot[9, 1], Knot[9, 2], Knot[9, 3], Knot[9, 4], Knot[9, 5],
Knot[9, 6], Knot[9, 7], Knot[9, 8], Knot[9, 9], Knot[9, 10],
Knot[9, 11], Knot[9, 12], Knot[9, 13], Knot[9, 14], Knot[9, 15],
Knot[9, 17], Knot[9, 18], Knot[9, 19], Knot[9, 20], Knot[9, 21],
Knot[9, 23], Knot[9, 26], Knot[9, 27], Knot[9, 31]}
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The super bridge index of a knot is the minimal number, in a generic smooth embedding of in , of the maximal number of local maxima (or local minima) in a rigid rotation of that projection.
| In[18]:=
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?SuperBridgeIndex
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| SuperBridgeIndex[K] returns the super bridge index of the knot K, if known to KnotTheory`. If only a range of possible values is known, a list of the form {min, max} is returned.
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| In[19]:=
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SuperBridgeIndex::about
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| The super bridge index data known to KnotTheory` is taken from Charles Livingston's "Table of Knot Invariants", http://www.indiana.edu/~knotinfo/.
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| In[20]:=
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?NakanishiIndex
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| NakanishiIndex[K] returns the Nakanishi index of the knot K, if known to KnotTheory`.
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| In[21]:=
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NakanishiIndex::about
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| The Nakanishi index data known to KnotTheory` is taken from Charles Livingston's "Table of Knot Invariants", http://www.indiana.edu/~knotinfo/.
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In[22]:=
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Profile[K_] := Profile[
SymmetryType[K], UnknottingNumber[K], ThreeGenus[K],
BridgeIndex[K], SuperBridgeIndex[K], NakanishiIndex[K]
]
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In[23]:=
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Profile[Knot[9,24]]
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Out[23]=
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Profile[Reversible, 1, 3, 3, {4, 6}, 1]
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In[24]:=
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Ks = Select[AllKnots[], (Crossings[#] == 9 && Profile[#]==Profile[Knot[9,24]])&]
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Out[24]=
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{Knot[9, 24], Knot[9, 28], Knot[9, 30], Knot[9, 34]}
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In[25]:=
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Alexander[#][t]& /@ Ks
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Out[25]=
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-3 5 10 2 3
{13 - t + -- - -- - 10 t + 5 t - t ,
2 t
t
-3 5 12 2 3
-15 + t - -- + -- + 12 t - 5 t + t ,
2 t
t
-3 5 12 2 3
17 - t + -- - -- - 12 t + 5 t - t ,
2 t
t
-3 6 16 2 3
23 - t + -- - -- - 16 t + 6 t - t }
2 t
t
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