English

Optimal Electrical Oblivious Routing on Expanders

Data Structures and Algorithms 2024-06-12 v1

Abstract

In this paper, we investigate the question of whether the electrical flow routing is a good oblivious routing scheme on an mm-edge graph G=(V,E)G = (V, E) that is a Φ\Phi-expander, i.e. where SΦvol(S)\lvert \partial S \rvert \geq \Phi \cdot \mathrm{vol}(S) for every SV,vol(S)vol(V)/2S \subseteq V, \mathrm{vol}(S) \leq \mathrm{vol}(V)/2. Beyond its simplicity and structural importance, this question is well-motivated by the current state-of-the-art of fast algorithms for \ell_{\infty} oblivious routings that reduce to the expander-case which is in turn solved by electrical flow routing. Our main result proves that the electrical routing is an O(Φ1logm)O(\Phi^{-1} \log m)-competitive oblivious routing in the 1\ell_1- and \ell_\infty-norms. We further observe that the oblivious routing is O(log2m)O(\log^2 m)-competitive in the 2\ell_2-norm and, in fact, O(logm)O(\log m)-competitive if 2\ell_2-localization is O(logm)O(\log m) which is widely believed. Using these three upper bounds, we can smoothly interpolate to obtain upper bounds for every p[2,]p \in [2, \infty] and qq given by 1/p+1/q=11/p + 1/q = 1. Assuming 2\ell_2-localization in O(logm)O(\log m), we obtain that in p\ell_p and q\ell_q, the electrical oblivious routing is O(Φ(12/p)logm)O(\Phi^{-(1-2/p)}\log m) competitive. Using the currently known result for 2\ell_2-localization, this ratio deteriorates by at most a sublogarithmic factor for every p,q2p, q \neq 2. We complement our upper bounds with lower bounds that show that the electrical routing for any such pp and qq is Ω(Φ(12/p)logm)\Omega(\Phi^{-(1-2/p)}\log m)-competitive. This renders our results in 1\ell_1 and \ell_{\infty} unconditionally tight up to constants, and the result in any p\ell_p- and q\ell_q-norm to be tight in case of 2\ell_2-localization in O(logm)O(\log m).

Cite

@article{arxiv.2406.07252,
  title  = {Optimal Electrical Oblivious Routing on Expanders},
  author = {Cella Florescu and Rasmus Kyng and Maximilian Probst Gutenberg and Sushant Sachdeva},
  journal= {arXiv preprint arXiv:2406.07252},
  year   = {2024}
}

Comments

To appear in ICALP 2024

R2 v1 2026-06-28T17:01:29.858Z