English

Higher order Nielsen numbers

Geometric Topology 2007-05-23 v2 Algebraic Topology

Abstract

Suppose X,Y are manifolds, f,g:X->Y are maps. The well-known Coincidence Problem studies the coincidence set C={x:f(x)=g(x)}. The number m=dimX-dimY is called the codimension of the problem. More general is the Preimage Problem. For a map f:X->Z and a submanifold Y of Z, it studies the preimage set C={x:f(x) in Y}, and the codimension is m=dimX+dimY-dimZ. In case of codimension 0, the classical Nielsen number N(f,Y) is a lower estimate of the number of points in C changing under homotopies of f, and for an arbitrary codimension, of the number of components of C. We extend this theory to take into account other topological characteristics of C. The goal is to find a "lower estimate" of the bordism group Omega_{p}(C) of C. The answer is the Nielsen group S_{p}(f,Y) defined as follows. In the classical definition the Nielsen equivalence of points of C based on paths is replaced with an equivalence of singular submanifolds of C based on bordisms. We let S_{p}^{prime}(f,Y) be the quotient group of Omega_{p}(C) with respect to this equivalence relation, then the Nielsen group of order p is the part of this group preserved under homotopies of f. The Nielsen number N_{p}(f,Y) of order p is the rank of this group (then N(f,Y)=N_{0}(f,Y)). These numbers are new obstructions to removability of coincidences and preimages. Some examples and computations are provided.

Cite

@article{arxiv.math/0202113,
  title  = {Higher order Nielsen numbers},
  author = {Peter Saveliev},
  journal= {arXiv preprint arXiv:math/0202113},
  year   = {2007}
}

Comments

New version, 18 pages. Minor revisions throughout the paper