Achievable Stability in Redundancy Systems-Reference-Cited by-同舟云学术

Achievable Stability in Redundancy Systems

Published:2020-11-30 Issue:3 Volume:4 Page:1-21
ISSN:2476-1249
Container-title:Proceedings of the ACM on Measurement and Analysis of Computing Systems
language:en
Short-container-title:Proc. ACM Meas. Anal. Comput. Syst.

Author:

Raaijmakers Youri¹,Borst Sem¹

Affiliation:

1. Eindhoven University of Technology, Eindhoven, Netherlands

Abstract

We consider a system with N~parallel servers where incoming jobs are immediately replicated to, say, d~servers. Each of the N servers has its own queue and follows a FCFS discipline. As soon as the first job replica is completed, the remaining replicas are abandoned. We investigate the achievable stability region for a quite general workload model with different job types and heterogeneous servers, reflecting job-server affinity relations which may arise from data locality issues and soft compatibility constraints. Under the assumption that job types are known beforehand we show for New-Better-than-Used (NBU) distributed speed variations that no replication $(d=1)$ gives a strictly larger stability region than replication $(d>1)$. Strikingly, this does not depend on the underlying distribution of the intrinsic job sizes, but observing the job types is essential for this statement to hold. In case of non-observable job types we show that for New-Worse-than-Used (NWU) distributed speed variations full replication ($d=N$) gives a larger stability region than no replication $(d=1)$.

Publisher

Association for Computing Machinery (ACM)

Subject

Computer Networks and Communications,Hardware and Architecture,Safety, Risk, Reliability and Quality,Computer Science (miscellaneous)

Link

https://dl.acm.org/doi/pdf/10.1145/3428331

Reference24 articles.

1. M. Aktas G. Joshi S. Kadhe F. Kazemi and E. Soljanin. 2020. Service rate region: A new aspect of coded distributed system design. ArXiv 2009.01598 (2020) 1--43. M. Aktas G. Joshi S. Kadhe F. Kazemi and E. Soljanin. 2020. Service rate region: A new aspect of coded distributed system design. ArXiv 2009.01598 (2020) 1--43.

2. E. Anton U. Ayesta M. Jonckheere and I.M. Verloop. 2019. On the stability of redudancy models. ArXiv 1903.04414 (2019). E. Anton U. Ayesta M. Jonckheere and I.M. Verloop. 2019. On the stability of redudancy models. ArXiv 1903.04414 (2019).

3. E. Anton U. Ayesta M. Jonckheere and I.M. Verloop. 2020. Improving the performance of heterogeneous data centers through redundancy. ArXiv 2003.01394 (2020). E. Anton U. Ayesta M. Jonckheere and I.M. Verloop. 2020. Improving the performance of heterogeneous data centers through redundancy. ArXiv 2003.01394 (2020).

4. Learning and hierarchies in service systems;Bimpikis K.;Management Science,2018

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