Vertex Fault-Tolerant Emulators
Abstract
A -spanner of a graph is a sparse subgraph that preserves its shortest path distances up to a multiplicative stretch factor of , and a -emulator is similar but not required to be a subgraph of . A classic theorem by Thorup and Zwick [JACM '05] shows that, despite the extra flexibility available to emulators, the size/stretch tradeoffs for spanners and emulators are equivalent. Our main result is that this equivalence in tradeoffs no longer holds in the commonly-studied setting of graphs with vertex failures. That is: we introduce a natural definition of vertex fault-tolerant emulators, and then we show a three-way tradeoff between size, stretch, and fault-tolerance for these emulators that polynomially surpasses the tradeoff known to be optimal for spanners. We complement our emulator upper bound with a lower bound construction that is essentially tight (within factors of the upper bound) when the stretch is and is either a fixed odd integer or . We also show constructions of fault-tolerant emulators with additive error, demonstrating that these also enjoy significantly improved tradeoffs over those available for fault-tolerant additive spanners.
Cite
@article{arxiv.2109.08042,
title = {Vertex Fault-Tolerant Emulators},
author = {Greg Bodwin and Michael Dinitz and Yasamin Nazari},
journal= {arXiv preprint arXiv:2109.08042},
year = {2021}
}
Comments
To appear in ITCS 2022