TY - GEN
T1 - A face cover perspective to ℓ1 embeddings of planar graphs
AU - Filtser, Arnold
N1 - Publisher Copyright:
Copyright © 2020 by SIAM
PY - 2020/1/1
Y1 - 2020/1/1
N2 - It was conjectured by Gupta et al. [Combinatorica04] that every planar graph can be embedded into ℓ1 with constant distortion. However, given an n-vertex weighted planar graph, the best upper bound on the distortion is only O(√log n), by Rao [SoCG99]. In this paper we study the case where there is a set K of terminals, and the goal is to embed only the terminals into ℓ1 with low distortion. In a seminal paper, Okamura and Seymour [J.Comb.Theory81] showed that if all the terminals lie on a single face, they can be embedded isometrically into ℓ1. The more general case, where the set of terminals can be covered by γ faces, was studied by Lee and Sidiropoulos [STOC09] and Chekuri et al. [J.Comb.Theory13]. The state of the art is an upper bound of O(log γ) by Krauthgamer, Lee and Rika [SODA19]. Our contribution is a further improvement on the upper bound to O(√log γ). Since every planar graph has at most O(n) faces, any further improvement on this result, will be a major breakthrough, directly improving upon Rao's long standing upper bound. Moreover, it is well known that the flow-cut gap equals to the distortion of the best embedding into ℓ1. Therefore, our result provides a polynomial time O(√log γ)approximation to the sparsest cut problem on planar graphs, for the case where all the demand pairs can be covered by γ faces.
AB - It was conjectured by Gupta et al. [Combinatorica04] that every planar graph can be embedded into ℓ1 with constant distortion. However, given an n-vertex weighted planar graph, the best upper bound on the distortion is only O(√log n), by Rao [SoCG99]. In this paper we study the case where there is a set K of terminals, and the goal is to embed only the terminals into ℓ1 with low distortion. In a seminal paper, Okamura and Seymour [J.Comb.Theory81] showed that if all the terminals lie on a single face, they can be embedded isometrically into ℓ1. The more general case, where the set of terminals can be covered by γ faces, was studied by Lee and Sidiropoulos [STOC09] and Chekuri et al. [J.Comb.Theory13]. The state of the art is an upper bound of O(log γ) by Krauthgamer, Lee and Rika [SODA19]. Our contribution is a further improvement on the upper bound to O(√log γ). Since every planar graph has at most O(n) faces, any further improvement on this result, will be a major breakthrough, directly improving upon Rao's long standing upper bound. Moreover, it is well known that the flow-cut gap equals to the distortion of the best embedding into ℓ1. Therefore, our result provides a polynomial time O(√log γ)approximation to the sparsest cut problem on planar graphs, for the case where all the demand pairs can be covered by γ faces.
UR - http://www.scopus.com/inward/record.url?scp=85084059285&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:85084059285
T3 - Proceedings of the Annual ACM-SIAM Symposium on Discrete Algorithms
SP - 1945
EP - 1954
BT - 31st Annual ACM-SIAM Symposium on Discrete Algorithms, SODA 2020
A2 - Chawla, Shuchi
PB - Association for Computing Machinery
T2 - 31st Annual ACM-SIAM Symposium on Discrete Algorithms, SODA 2020
Y2 - 5 January 2020 through 8 January 2020
ER -