Partitioning Theorems for Sets of Semi-Pfaffian Sets, with Applications
Abstract
We generalize the seminal polynomial partitioning theorems of Guth and Katz to a set of semi-Pfaffian sets. Specifically, given a set ⊂eq Rn of k-dimensional semi-Pfaffian sets, where each γ ∈ is defined by a fixed number of Pfaffian functions, and each Pfaffian function is in turn defined with respect to a Pfaffian chain q of length r, for any D 1, we prove the existence of a polynomial P ∈ R[X1, …, Xn] of degree at most D such that each connected component of Rn Z(P) intersects at most ||Dn - k - r elements of . Also, under some mild conditions on q, for any D 1, we prove the existence of a Pfaffian function P' of degree at most D defined with respect to q, such that each connected component of Rn Z(P') intersects at most ||Dn-k elements of . To do so, given a k-dimensional semi-Pfaffian set X ⊂eq Rn, and a polynomial P ∈ R[X1, …, Xn] of degree at most D, we establish a uniform bound on the number of connected components of Rn Z(P) that X intersects; that is, we prove that the number of connected components of (Rn Z(P)) X is at most Dk+r. Finally as applications, we derive Pfaffian versions of Szemer\'edi-Trotter type theorems, and also prove bounds on the number of joints between Pfaffian curves.
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