Near-Optimal Euclidean Locality-Sensitive Orderings
Abstract
R R X r E p q [1]#1 q [1]V #1 P [1][ #1 ] m [2][\!]#1(#2) polylog N Z p [2]\| #1 - #2 \| q s For a parameter ∈ (0,1), we present a new construction of -locality-sensitive orderings (<LSOs) in d of size M = O(d-1 ), where = 1/. This improves over previous work by a factor of , and is optimal up to a factor of . Such a set of LSOs has the property that for any two points, , ∈ [0,1]d, there exist an order in the set such that all the points between and in the order are -close to either or . The existence of such LSOs is a fundamental property of low dimensional Euclidean space, conceptually similar to the existence of well-separated pairs decomposition, so the question of how to compute (near) optimal construction of LSOs is quite natural. As a consequence we get a flotilla of improved dynamic geometric algorithms, such as maintaining bichromatic closest pair, and spanners, among others. In particular, for geometric dynamic spanners the new result matches (up to the aforementioned factor) the lower bound, Thus offering a near-optimal simple dynamic data-structure for maintaining spanners under insertions and deletions.
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