Sign rank versus VC dimension

Abstract

This work studies the maximum possible sign rank of N × N sign matrices with a given VC dimension d. For d=1, this maximum is three. For d=2, this maximum is (N1/2). For d >2, similar but slightly less accurate statements hold. The lower bounds improve over previous ones by Ben-David et al., and the upper bounds are novel. The lower bounds are obtained by probabilistic constructions, using a theorem of Warren in real algebraic topology. The upper bounds are obtained using a result of Welzl about spanning trees with low stabbing number, and using the moment curve. The upper bound technique is also used to: (i) provide estimates on the number of classes of a given VC dimension, and the number of maximum classes of a given VC dimension -- answering a question of Frankl from '89, and (ii) design an efficient algorithm that provides an O(N/(N)) multiplicative approximation for the sign rank. We also observe a general connection between sign rank and spectral gaps which is based on Forster's argument. Consider the N × N adjacency matrix of a regular graph with a second eigenvalue of absolute value λ and ≤ N/2. We show that the sign rank of the signed version of this matrix is at least /λ. We use this connection to prove the existence of a maximum class C⊂eq\ 1\N with VC dimension 2 and sign rank (N1/2). This answers a question of Ben-David et al.~regarding the sign rank of large VC classes. We also describe limitations of this approach, in the spirit of the Alon-Boppana theorem. We further describe connections to communication complexity, geometry, learning theory, and combinatorics.