A Colorful Extension of VC-dimension and Geometric Applications

Abstract

The VC-dimension is a fundamental measure of the complexity of a set system. In this paper, we introduce and study a colorful variant of VC-dimension that captures the behavior of set systems on colored ground sets. By studying this new notion, we obtain a variety of geometric results. First, we prove that separable abstract convexity spaces with Radon number D admit a Tverberg theorem with Tverberg number O(D2 r r). This bound significantly improves the O(Dr2 r) bound of Alon and Smorodinsky from SODA'26 and is the first quasi-linear bound in r, in which the dependence on D is not super-exponential. Second, we prove the first colorful k-wise Tverberg theorem for separable abstract convexity spaces. Using this theorem, we obtain a colorful selection lemma with O(D3) colors, an uncolored selection lemma for subsets of size O(D3), a weak -net theorem with nets of size OD(-O(D3)), and a (p,q)-theorem with exponent of poly(D). All these quantitative bounds are significantly better than the best previously known general bounds for abstract convexity spaces. Finally, we extend our method to obtain a colorful Tverberg theorem for unions of convex sets, generalizing the uncolored theorem of Alon and Smorodinsky (SODA'26).

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