Metric embeddings with relaxed guarantees

T. H.Hubert Chan, Kedar Dhamdhere, Anupam Gupta, Jon Kleinberg, Aleksandrs Slivkins

Research output: Contribution to journalArticlepeer-review

Abstract

We consider the problem of embedding finite metrics with slack: We seek to produce embeddings with small dimension and distortion while allowing a (small) constant fraction of all distances to be arbitrarily distorted. This definition is motivated by recent research in the networking community, which achieved striking empirical success at embedding Internet latencies with low distortion into low-dimensional Euclidean space, provided that some small slack is allowed. Answering an open question of Kleinberg, Slivkins, and Wexler [in Proceedings of the 45th IEEE Symposium on Foundations of Computer Science, 2004], we show that provable guarantees of this type can in fact be achieved in general: Any finite metric space can be embedded, with constant slack and constant distortion, into constant-dimensional Euclidean space. We then show that there exist stronger embeddings into l 1 which exhibit gracefully degrading distortion: There is a single embedding into l 1 that achieves distortion at most O (log 1/∈) on all but at most an ∈ fraction of distances simultaneously for all ∈ > 0. We extend this with distortion O (log 1/∈) 1/p to maps into general l p, p ≥ 1, for several classes of metrics, including those with bounded doubling dimension and those arising from the shortest-path metric of a graph with an excluded minor. Finally, we show that many of our constructions are tight and give a general technique to obtain lower bounds for ∈-slack embeddings from lower bounds for low-distortion embeddings.

Original languageEnglish (US)
Pages (from-to)2303-2329
Number of pages27
JournalSIAM Journal on Computing
Volume38
Issue number6
DOIs
StatePublished - 2009

Keywords

  • Low-distortion embeddings
  • Metric decompositions
  • Metric embeddings
  • Metric spaces
  • Randomized algorithms

ASJC Scopus subject areas

  • General Computer Science
  • General Mathematics

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