Finite type invariant

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In the mathematical theory of knots, a finite type invariant is a knot invariant that can be extended (in a precise manner to be described) to an invariant of certain singular knots that vanishes on singular knots with m + 1 singularities. It is then said to be of type or order m. These invariants were first studied by Mikhail Goussarov and Victor Vassiliev, independently, and so are often called Goussarov-Vassiliev invariants or Vassiliev invariants.

We give the combinatorial definition of finite type invariant due to Goussarov, and (independently) Joan Birman and Xiao-Song Lin. Let V be a knot invariant. Define V1 to be defined on a knot with one transverse singularity.

Consider a knot K to be a smooth embedding of a circle into  \mathbb R^3. Let K' be a smooth immersion of a circle into  \mathbb R^3 with one transverse double point. Then V1(K') = V(K + ) − V(K ), where K + is obtained from K by resolving the double point by pushing up one strand above the other, and K_- is obtained similarly by pushing the opposite strand above the other. We can do this for maps with two transverse double points, three transverse double points, etc., by using the above relation. For V to be of finite type means precisely that there must be a positive integer m such that V vanishes on maps with m+1 transverse double points.

Furthermore, note that there is notion of equivalence of knots with singularities being transverse double points and V should respect this equivalence.

There is also a similar notion of finite type invariant for 3-manifolds.

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[edit] First example

The simplest nontrivial Vassiliev invariant of knots is given by the coefficient of the quadratic term of the Alexander-Conway polynomial. It is an invariant of order two. Modulo two, it is equal to the Arf invariant.

[edit] Invariants representation

Michael Polyak and Oleg Viro have proved that all Vassiliev invariants can be represented by chord diagrams. Using such diagrams, they gave a description of the first nontrivial invariants of order 2 and 3.

In addition to order 2 and 3, the order 4 invariant was shown by Polyak and Viro; later proven false, and that it isn't invariant at all - the formula given was wrong.

[edit] Order 4 invariant

after bad attempt by Polyak & Viro to write down order 4 invariant formula this work was made by Turaeva. nowadays it's proven that her formula was wrong too.

[edit] The universal Vassiliev invariant

In 1993, Maxim Kontsevich proved the following important theorem about Vassiliev invariants: For every knot one can compute an integral, now called the Kontsevich integral, which is a universal Vassiliev invariant, meaning that every Vassiliev invariant can be obtained from it by an appropriate evaluation.

Whether the Kontsevich integral, or the totality of Vassiliev invariants, is a complete knot invariant is not known at present.

Computation of the Kontsevich integral, which has values in an algebra of chord diagrams, turns out to be rather difficult and has been done only for a few classes of knots up to now.

[edit] References

  • Mikhail Goussarov,
  • Victor A. Vassiliev, Cohomology of knot spaces. Theory of singularities and its applications, 23--69, Adv. Soviet Math., 1, Amer. Math. Soc., Providence, RI, 1990.
  • J. Birman and X-S Lin, Knot polynomials and Vassiliev's invariants. Invent. Math., 111, 225--270 (1993)
  • Dror Bar-Natan, On the Vassiliev knot invariants. Topology 34 (1995), 423--472

[edit] External links