Online Euclidean Spanners

Abstract

In this paper, we study the online Euclidean spanners problem for points in Rd. Suppose we are given a sequence of n points (s1,s2,…, sn) in Rd, where point si is presented in step~i for i=1,…, n. The objective of an online algorithm is to maintain a geometric t-spanner on Si=\s1,…, si\ for each step~i. First, we establish a lower bound of (-1 n / -1) for the competitive ratio of any online (1+)-spanner algorithm, for a sequence of n points in 1-dimension. We show that this bound is tight, and there is an online algorithm that can maintain a (1+)-spanner with competitive ratio O(-1 n / -1). Next, we design online algorithms for sequences of points in Rd, for any constant d 2, under the L2 norm. We show that previously known incremental algorithms achieve a competitive ratio O(-(d+1) n). However, if the algorithm is allowed to use additional points (Steiner points), then it is possible to substantially improve the competitive ratio in terms of . We describe an online Steiner (1+)-spanner algorithm with competitive ratio O((1-d)/2 n). As a counterpart, we show that the dependence on n cannot be eliminated in dimensions d 2. In particular, we prove that any online spanner algorithm for a sequence of n points in Rd under the L2 norm has competitive ratio (f(n)), where n→ ∞f(n)=∞. Finally, we provide improved lower bounds under the L1 norm: (-2/ -1) in the plane and (-d) in Rd for d≥ 3.