An Efficient Regularity Lemma for Semi-Algebraic Hypergraphs
Abstract
We use the polynomial method of Guth and Katz to establish stronger and more efficient regularity and density theorems for such k-uniform hypergraphs H=(P,E), where P is a finite point set in Rd, and the edge set E is determined by a semi-algebraic relation of bounded description complexity. In particular, for any 0<ε≤ 1 we show that one can construct in O(n (1/ε)) time, an equitable partition P=U1 … UK into K=O(1/εd+1+δ) subsets, for any 0<δ, so that all but ε-fraction of the k-tuples Ui1,…,Uik are homogeneous: we have that either Ui1×…× Uik⊂eq E or (Ui1×…× Uik) E=. If the points of P can be perturbed in a general position, the bound improves to O(1/εd+1), and the partition is attained via a single partitioning polynomial (albeit, at expense of a possible increase in worst-case running time). In contrast to the previous such regularity lemmas which were established by Fox, Gromov, Lafforgue, Naor, and Pach and, subsequently, Fox, Pach and Suk, our partition of P does not depend on the edge set E provided its semi-algebraic description complexity does not exceed a certain constant. As a by-product, we show that in any k-partite k-uniform hypergraph (P1… Pk,E) of bounded semi-algebraic description complexity in Rd and with |E|≥ ε Πi=1k|Pi| edges, one can find, in expected time O(Σi=1k(|Pi|+1/ε)) (1/ε)), subsets Qi⊂eq Pi of cardinality |Qi|≥ |Pi|/εd+1+δ, so that Q1×…× Qk⊂eq E.
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