The Lefschetz-Hopf theorem and axioms for the Lefschetz number

Abstract

The reduced Lefschetz number, that is, the Lefschetz number minus 1, is proved to be the unique integer-valued function L on selfmaps of compact polyhedra which is constant on homotopy classes such that (1) L(fg) = L(gf), for f:X -->Y and g:Y -->X; (2) if (f1, f2, f3) is a map of a cofiber sequence into itself, then L(f2) = L(f1) + L(f3); (3) L(f) = - (degree(p1 f e1) + ... + degree(pk f ek)), where f is a map of a wedge of k circles, er is the inclusion of a circle into the rth summand and pr is the projection onto the rth summand. If f:X -->X is a selfmap of a polyhedron and I(f) is the fixed point index of f on all of X, then we show that I minus 1 satisfies the above axioms. This gives a new proof of the Normalization Theorem: If f:X -->X is a selfmap of a polyhedron, then I(f) equals the Lefschetz number of f. This result is equivalent to the Lefschetz-Hopf Theorem: If f: X -->X is a selfmap of a finite simplicial complex with a finite number of fixed points, each lying in a maximal simplex, then the Lefschetz number of f is the sum of the indices of all the fixed points of f.

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