Three Dimensional Invariants

(For In[1] see Setup)

The unknotting number of a knot ${\displaystyle K}$ is the minimal number of crossing changes needed in order to unknot ${\displaystyle K}$.

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:

<*InOut@"Plus @@ u /@ Cases[UnknottingNumber /@ AllKnots[], _Integer]"*>

There are <*Length[

 Select[AllKnots[], Crossings[#] <= 9 && Head[UnknottingNumber[#]] === List &]

]*> knots with up to 9 crossings whose unknotting number is unknown:

<*InOut@"Select[AllKnots[], Crossings[#] <= 9 && Head[UnknottingNumber[#]] === L ist &]"*>

\index{Livingston, Charles} <* HelpBox[ThreeGenus] *>

\index{Bridge index} The {\em bridge index} of a knot $K$ is the minimal number of local maxima (or local minima) in a generic smooth embedding of $K$ in $\bbR^3$.

\index{Livingston, Charles} <* HelpBox[BridgeIndex] *>

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:

<*InOut@"Select[AllKnots[], Crossings[#] == 9 && BridgeIndex[#] == 2 &]"*>

\index{Super bridge index} The {\em super bridge index} of a knot $K$ is the minimal number, in a generic smooth embedding of $K$ in $\bbR^3$, of the maximal number of local maxima (or local minima) in a rigid rotation of that projection.

\index{Livingston, Charles} <* HelpBox[SuperBridgeIndex] *>

\index{Livingston, Charles} <* HelpBox[NakanishiIndex] *>

<*InOut@"Profile[K_] := Profile[\n

 SymmetryType[K], UnknottingNumber[K], ThreeGenus[K]\n
 BridgeIndex[K], SuperBridgeIndex[K], NakanishiIndex[K]\n

]"*> <*InOut@"Profile[Knot[9,24]]"*> <*InOut@"Ks = Select[\n

 AllKnots[],\n
 (Crossings[#] == 9 && Profile[#]==Profile[Knot[9,24]])&\n

]"*> <*InOut@"Alexander[#][t]& /@ Ks"*>