Sparse Euclidean Spanners with Tiny Diameter: A Tight Lower Bound
Abstract
In STOC'95 [ADMSS'95] Arya et al. showed that any set of n points in Rd admits a (1+ε)-spanner with hop-diameter at most 2 (respectively, 3) and O(n n) edges (resp., O(n n) edges). They also gave a general upper bound tradeoff of hop-diameter at most k and O(n αk(n)) edges, for any k 2. The function αk is the inverse of a certain Ackermann-style function at the k/2 level of the primitive recursive hierarchy, where α0(n) = n/2 , α1(n) = n , α2(n) = n , α3(n) = n , α4(n) = * n, α5(n) = 12 *n , …. Roughly speaking, for k 2 the function αk is close to k-22 -iterated log-star function, i.e., with k-22 stars. Also, α2α(n)+4(n) 4, where α(n) is the one-parameter inverse Ackermann function, which is an extremely slowly growing function. Whether or not this tradeoff is tight has remained open, even for the cases k = 2 and k = 3. Two lower bounds are known: The first applies only to spanners with stretch 1 and the second is sub-optimal and applies only to sufficiently large (constant) values of k. In this paper we prove a tight lower bound for any constant k: For any fixed ε > 0, any (1+ε)-spanner for the uniform line metric with hop-diameter at most k must have at least (n αk(n)) edges.
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