- Poincaré–Hopf theorem
In
mathematics , the Poincaré–Hopf theorem (also known as the Poincaré–Hopf index formula, Poincaré–Hopf index theorem, or Hopf index theorem) is an important theorem indifferential topology . It is named afterHenri Poincaré andHeinz Hopf .The Poincaré–Hopf theorem is often illustrated by the special case of the
Hairy ball theorem , which simply states that there is no smooth vector field on a sphere having no sources or sinks.Formal Statement
Theorem. Let "M" be a compact orientable differentiable manifold. Let "v" be a
vector field on "M" with isolated zeroes. If "M" has boundary, then we insist that "v" be pointing in the outward normal direction along the boundary. Then we have the formula:
where the sum of the indices is over all the isolated zeroes of "v" and is the
Euler characteristic of "M".The theorem was proven for two dimensions by
Henri Poincaré and later generalized to higher dimensions byHeinz Hopf .ignificance
The Euler characteristic of a closed surface is a purely topological concept, whereas the index of a vector field is purely analytic. Thus, this theorem establishes a deep link between two seemingly unrelated areas of mathematics. It is perhaps as interesting that the proof of this theorem relies heavily on
integral , and, in particular,Stokes' theorem , which states that the integral of theexterior derivative of adifferential form is equal to the integral of that form over the boundary. In the special case of a manifold without boundary, this amounts to saying that the integral is 0. But by examining vector fields in a sufficiently small neighborhood of a source or sink, we see that sources and sinks contribute integral amounts (known as the index) to the total, and they must all sum to 0. This result may be considered one of the earliest of a whole series of theorems establishing deep relationships between geometric and analytical or physical concepts. They play an important role in the modern study of both fields.ketch of Proof
1. Embed "M" in some high-dimensional Euclidean space. (Use the
Whitney embedding theorem .)2. Take a small neighborhood of "M" in that Euclidean space, . Extend the vector field to this neighborhood so that it still has the same zeroes and the zeroes have the same indices. In addition, make sure that the extended vector field at the boundary of is directed outwards.
3. The sum of indices of the zeroes of the old (and new) vector field is equal to the degree of the
Gauss map from the boundary of to the "n-1"-dimensional sphere. Thus, the sum of the indices is independent of the actual vector field, and depends only on the manifold "M".Technique: cut away all zeroes of the vector field with small neighborhoods. Then use the fact that the boundary of an n-dimensional manifold to an n-1-dimensional sphere, that can be extended to the whole n-dimensional manifold, is zero.4. Finally, identify this sum of indices as the Euler characteristic of "M". To do that, construct a very specific vector field on "M" using a
triangulation of "M" for which it is clear that the sum of indices is equal to the Euler characteristic.
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