Unbounded lower bound for k-server against weak adversaries
November 05, 2019 Β· Declared Dead Β· π Symposium on the Theory of Computing
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Authors
Marcin Bienkowski, JarosΕaw Byrka, Christian Coester, Εukasz JeΕΌ
arXiv ID
1911.01592
Category
cs.DS: Data Structures & Algorithms
Citations
3
Venue
Symposium on the Theory of Computing
Last Checked
4 months ago
Abstract
We study the resource augmented version of the $k$-server problem, also known as the $k$-server problem against weak adversaries or the $(h,k)$-server problem. In this setting, an online algorithm using $k$ servers is compared to an offline algorithm using $h$ servers, where $h\le k$. For uniform metrics, it has been known since the seminal work of Sleator and Tarjan (1985) that for any $Ξ΅>0$, the competitive ratio drops to a constant if $k=(1+Ξ΅) \cdot h$. This result was later generalized to weighted stars (Young 1994) and trees of bounded depth (Bansal et al. 2017). The main open problem for this setting is whether a similar phenomenon occurs on general metrics. We resolve this question negatively. With a simple recursive construction, we show that the competitive ratio is at least $Ξ©(\log \log h)$, even as $k\to\infty$. Our lower bound holds for both deterministic and randomized algorithms. It also disproves the existence of a competitive algorithm for the infinite server problem on general metrics.
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