A semi-algebraic version of Zarankiewicz's problem

Abstract

A bipartite graph G is semi-algebraic in Rd if its vertices are represented by point sets P,Q ⊂ Rd and its edges are defined as pairs of points (p,q) ∈ P× Q that satisfy a Boolean combination of a fixed number of polynomial equations and inequalities in 2d coordinates. We show that for fixed k, the maximum number of edges in a Kk,k-free semi-algebraic bipartite graph G = (P,Q,E) in R2 with |P| = m and |Q| = n is at most O((mn)2/3 + m + n), and this bound is tight. In dimensions d ≥ 3, we show that all such semi-algebraic graphs have at most C((mn) dd+1 + + m + n) edges, where here is an arbitrarily small constant and C = C(d,k,t,). This result is a far-reaching generalization of the classical Szemer\'edi-Trotter incidence theorem. The proof combines tools from several fields: VC-dimension and shatter functions, polynomial partitioning, and Hilbert polynomials. We also present various applications of our theorem. For example, a general point-variety incidence bound in Rd, an improved bound for a d-dimensional variant of the Erdos unit distances problem, and more.