research-article

Power routing: dynamic power provisioning in the data center

Authors:

Pooya Zandevakili,

Thomas F. Wenisch,

Jack UnderwoodAuthors Info & Claims

ASPLOS XV: Proceedings of the fifteenth International Conference on Architectural support for programming languages and operating systems

Pages 231 - 242

https://doi.org/10.1145/1736020.1736047

Published: 13 March 2010 Publication History

Abstract

Data center power infrastructure incurs massive capital costs, which typically exceed energy costs over the life of the facility. To squeeze maximum value from the infrastructure, researchers have proposed over-subscribing power circuits, relying on the observation that peak loads are rare. To ensure availability, these proposals employ power capping, which throttles server performance during utilization spikes to enforce safe power budgets. However, because budgets must be enforced locally -- at each power distribution unit (PDU) -- local utilization spikes may force throttling even when power delivery capacity is available elsewhere. Moreover, the need to maintain reserve capacity for fault tolerance on power delivery paths magnifies the impact of utilization spikes.

In this paper, we develop mechanisms to better utilize installed power infrastructure, reducing reserve capacity margins and avoiding performance throttling. Unlike conventional high-availability data centers, where collocated servers share identical primary and secondary power feeds, we reorganize power feeds to create shuffled power distribution topologies. Shuffled topologies spread secondary power feeds over numerous PDUs, reducing reserve capacity requirements to tolerate a single PDU failure. Second, we propose Power Routing, which schedules IT load dynamically across redundant power feeds to: (1) shift slack to servers with growing power demands, and (2) balance power draw across AC phases to reduce heating and improve electrical stability. We describe efficient heuristics for scheduling servers to PDUs (an NP-complete problem). Using data collected from nearly 1000 servers in three production facilities, we demonstrate that these mechanisms can reduce the required power infrastructure capacity relative to conventional high-availability data centers by 32% without performance degradation.

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Cited By

Lee JMin DByun IJang HKim J(2023)Fast, Light-weight, and Accurate Performance Evaluation using Representative Datacenter BehaviorsProceedings of the 24th International Middleware Conference10.1145/3590140.3629117(220-233)Online publication date: 27-Nov-2023
https://dl.acm.org/doi/10.1145/3590140.3629117
Wu SChen YWang XJin HLiu FChen HYan C(2021)Precise Power Capping for Latency-Sensitive Applications in DatacenterIEEE Transactions on Sustainable Computing10.1109/TSUSC.2018.28818936:3(469-480)Online publication date: 1-Jul-2021
https://doi.org/10.1109/TSUSC.2018.2881893
Zhang CKumbhare AManousakis IZhang DMisra PAssis RWoolcock KMahalingam NWarrier BGauthier DKunnath LSolomon SMorales OFontoura MBianchini RMartínez JDuato JJohn L(2021)FlexProceedings of the 48th Annual International Symposium on Computer Architecture10.1109/ISCA52012.2021.00033(319-332)Online publication date: 14-Jun-2021
https://dl.acm.org/doi/10.1109/ISCA52012.2021.00033
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Index Terms

Power routing: dynamic power provisioning in the data center
1. Computer systems organization
  1. Architectures
    1. Distributed architectures
      1. Client-server architectures
2. Information systems
  1. Data management systems
    1. Middleware for databases
      1. Application servers
      2. Database web servers

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Power routing: dynamic power provisioning in the data center
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Power routing: dynamic power provisioning in the data center
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Published In

cover image ACM Conferences

ASPLOS XV: Proceedings of the fifteenth International Conference on Architectural support for programming languages and operating systems

March 2010

422 pages

ISBN:9781605588391

DOI:10.1145/1736020

General Chair:
James C. Hoe
Carnegie Mellon University, USA
,
Program Chair:
Vikram S. Adve
University of Illinois at Urbana-Champaign, USA

ACM SIGARCH Computer Architecture News Volume 38, Issue 1
ASPLOS '10
March 2010
399 pages
ISSN:0163-5964
DOI:10.1145/1735970
Issue’s Table of Contents
ACM SIGPLAN Notices Volume 45, Issue 3
ASPLOS '10
March 2010
399 pages
ISSN:0362-1340
EISSN:1558-1160
DOI:10.1145/1735971
Issue’s Table of Contents

Copyright © 2010 ACM.

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Published: 13 March 2010

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ASPLOS '10: Architectural Support for Programming Languages and Operating Systems

March 13 - 17, 2010

Pennsylvania, Pittsburgh, USA

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ASPLOS XV Paper Acceptance Rate 32 of 181 submissions, 18%;

Overall Acceptance Rate 535 of 2,713 submissions, 20%

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Cited By

Lee JMin DByun IJang HKim J(2023)Fast, Light-weight, and Accurate Performance Evaluation using Representative Datacenter BehaviorsProceedings of the 24th International Middleware Conference10.1145/3590140.3629117(220-233)Online publication date: 27-Nov-2023
https://dl.acm.org/doi/10.1145/3590140.3629117
Wu SChen YWang XJin HLiu FChen HYan C(2021)Precise Power Capping for Latency-Sensitive Applications in DatacenterIEEE Transactions on Sustainable Computing10.1109/TSUSC.2018.28818936:3(469-480)Online publication date: 1-Jul-2021
https://doi.org/10.1109/TSUSC.2018.2881893
Zhang CKumbhare AManousakis IZhang DMisra PAssis RWoolcock KMahalingam NWarrier BGauthier DKunnath LSolomon SMorales OFontoura MBianchini RMartínez JDuato JJohn L(2021)FlexProceedings of the 48th Annual International Symposium on Computer Architecture10.1109/ISCA52012.2021.00033(319-332)Online publication date: 14-Jun-2021
https://dl.acm.org/doi/10.1109/ISCA52012.2021.00033
Sakalkar VKontorinis VLandhuis DLi SDe Ronde DBlooming TRamesh AKennedy JMalone CClidaras JRanganathan PLarus JCeze LStrauss K(2020)Data Center Power Oversubscription with a Medium Voltage Power Plane and Priority-Aware CappingProceedings of the Twenty-Fifth International Conference on Architectural Support for Programming Languages and Operating Systems10.1145/3373376.3378533(497-511)Online publication date: 9-Mar-2020
https://dl.acm.org/doi/10.1145/3373376.3378533
Sun QRen SWu C(2020)Fair Online Power Capping for Emergency Handling in Multi-Tenant Cloud Data CentersIEEE Transactions on Cloud Computing10.1109/TCC.2017.27623118:1(152-166)Online publication date: 1-Jan-2020
https://doi.org/10.1109/TCC.2017.2762311
Barahman MCorreia LFerreira L(2020)A QoS-Demand-Aware Computing Resource Management Scheme in Cloud-RANIEEE Open Journal of the Communications Society10.1109/OJCOMS.2020.30342971(1850-1863)Online publication date: 2020
https://doi.org/10.1109/OJCOMS.2020.3034297
Narayanan ISivasubramaniam A(2020)Mediating Power Struggles on a Shared Server2020 IEEE International Symposium on Performance Analysis of Systems and Software (ISPASS)10.1109/ISPASS48437.2020.00030(149-159)Online publication date: Aug-2020
https://doi.org/10.1109/ISPASS48437.2020.00030
Patel TWagenhauser AEibel CHonig TZeiser TTiwari D(2020)What does Power Consumption Behavior of HPC Jobs Reveal? : Demystifying, Quantifying, and Predicting Power Consumption Characteristics2020 IEEE International Parallel and Distributed Processing Symposium (IPDPS)10.1109/IPDPS47924.2020.00087(799-809)Online publication date: May-2020
https://doi.org/10.1109/IPDPS47924.2020.00087
Lorincz JCapone AWu J(2019)Greener, Energy-Efficient and Sustainable Networks: State-Of-The-Art and New TrendsSensors10.3390/s1922486419:22(4864)Online publication date: 8-Nov-2019
https://doi.org/10.3390/s19224864
Funaro LBen-Yehuda OSchuster ASartor JNaik MRossbach C(2019)Stochastic resource allocationProceedings of the 15th ACM SIGPLAN/SIGOPS International Conference on Virtual Execution Environments10.1145/3313808.3313815(122-136)Online publication date: 14-Apr-2019
https://dl.acm.org/doi/10.1145/3313808.3313815
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