Lefschetz fixed-point theorem

(Redirected from Lefschetz number)

In mathematics, the Lefschetz fixed-point theorem is a formula that counts the fixed points of a continuous mapping from a compact topological space to itself by means of traces of the induced mappings on the homology groups of . It is named after Solomon Lefschetz, who first stated it in 1926.

The counting is subject to an imputed multiplicity at a fixed point called the fixed-point index. A weak version of the theorem is enough to show that a mapping without any fixed point must have rather special topological properties (like a rotation of a circle).

Formal statement

edit

For a formal statement of the theorem, let

 

be a continuous map from a compact triangulable space   to itself. Define the Lefschetz number   of   by

 

the alternating (finite) sum of the matrix traces of the linear maps induced by   on  , the singular homology groups of   with rational coefficients.

A simple version of the Lefschetz fixed-point theorem states: if

 

then   has at least one fixed point, i.e., there exists at least one   in   such that  . In fact, since the Lefschetz number has been defined at the homology level, the conclusion can be extended to say that any map homotopic to   has a fixed point as well.

Note however that the converse is not true in general:   may be zero even if   has fixed points, as is the case for the identity map on odd-dimensional spheres.

Sketch of a proof

edit

First, by applying the simplicial approximation theorem, one shows that if   has no fixed points, then (possibly after subdividing  )   is homotopic to a fixed-point-free simplicial map (i.e., it sends each simplex to a different simplex). This means that the diagonal values of the matrices of the linear maps induced on the simplicial chain complex of   must be all be zero. Then one notes that, in general, the Lefschetz number can also be computed using the alternating sum of the matrix traces of the aforementioned linear maps (this is true for almost exactly the same reason that the Euler characteristic has a definition in terms of homology groups; see below for the relation to the Euler characteristic). In the particular case of a fixed-point-free simplicial map, all of the diagonal values are zero, and thus the traces are all zero.

Lefschetz–Hopf theorem

edit

A stronger form of the theorem, also known as the Lefschetz–Hopf theorem, states that, if   has only finitely many fixed points, then

 

where   is the set of fixed points of  , and   denotes the index of the fixed point  .[1] From this theorem one deduces the Poincaré–Hopf theorem for vector fields, since every vector field on compact differential manifold induce flow   in a natural way. For every     is continuous mapping homotopic to identity (thus have same Lefschetz number) and for small   indices of fixed points equals to indices of zeroes of vector field.

Relation to the Euler characteristic

edit

The Lefschetz number of the identity map on a finite CW complex can be easily computed by realizing that each   can be thought of as an identity matrix, and so each trace term is simply the dimension of the appropriate homology group. Thus the Lefschetz number of the identity map is equal to the alternating sum of the Betti numbers of the space, which in turn is equal to the Euler characteristic  . Thus we have

 

Relation to the Brouwer fixed-point theorem

edit

The Lefschetz fixed-point theorem generalizes the Brouwer fixed-point theorem, which states that every continuous map from the  -dimensional closed unit disk   to   must have at least one fixed point.

This can be seen as follows:   is compact and triangulable, all its homology groups except   are zero, and every continuous map   induces the identity map  , whose trace is one; all this together implies that   is non-zero for any continuous map  .

Historical context

edit

Lefschetz presented his fixed-point theorem in (Lefschetz 1926). Lefschetz's focus was not on fixed points of maps, but rather on what are now called coincidence points of maps.

Given two maps   and   from an orientable manifold   to an orientable manifold   of the same dimension, the Lefschetz coincidence number of   and   is defined as

 

where   is as above,   is the homomorphism induced by   on the cohomology groups with rational coefficients, and   and   are the Poincaré duality isomorphisms for   and  , respectively.

Lefschetz proved that if the coincidence number is nonzero, then   and   have a coincidence point. He noted in his paper that letting   and letting   be the identity map gives a simpler result, which we now know as the fixed-point theorem.

Frobenius

edit

Let   be a variety defined over the finite field   with   elements and let   be the base change of   to the algebraic closure of  . The Frobenius endomorphism of   (often the geometric Frobenius, or just the Frobenius), denoted by  , maps a point with coordinates   to the point with coordinates  . Thus the fixed points of   are exactly the points of   with coordinates in  ; the set of such points is denoted by  . The Lefschetz trace formula holds in this context, and reads:

 

This formula involves the trace of the Frobenius on the étale cohomology, with compact supports, of   with values in the field of  -adic numbers, where   is a prime coprime to  .

If   is smooth and equidimensional, this formula can be rewritten in terms of the arithmetic Frobenius  , which acts as the inverse of   on cohomology:

 

This formula involves usual cohomology, rather than cohomology with compact supports.

The Lefschetz trace formula can also be generalized to algebraic stacks over finite fields.

See also

edit

Notes

edit
  1. ^ Dold, Albrecht (1980). Lectures on algebraic topology. Vol. 200 (2nd ed.). Berlin, New York: Springer-Verlag. ISBN 978-3-540-10369-1. MR 0606196., Proposition VII.6.6.

References

edit
edit