tutorial

Safety-Assured Collaborative Load Management in Smart Grids

Authors:

Hoang Hai Nguyen,

David K. Y. YauAuthors Info & Claims

ICCPS '14: ICCPS '14: ACM/IEEE 5th International Conference on Cyber-Physical Systems (with CPS Week 2014)

Pages 151 - 162

https://doi.org/10.1109/ICCPS.2014.6843719

Published: 15 April 2014 Publication History

Abstract

When a power grid is overloaded, load shedding is a conventional way to combat the imbalance between supply and demand that may jeopardize the grid's safety. However, disconnected customers may be excessively inconvenienced or even endangered. With the emergence of demand-response based on cyber-enabled smart meters and appliances, customers may participate in solving the imbalance by curtailing their demands collaboratively, such that no single customers will have to bear a disproportionate burden of reduced usage. However, compliance or commitment to curtailment requests by untrusted users is uncertain, which causes an important safety concern. This paper proposes a two-phase load management scheme that (i) gives customers a chance to curtail their demands and correct a grid's undersupply when there are no immediate safety concerns, but (ii) falls back to conventional load shedding to ensure safety once the grid enters a vulnerable state. Extensive simulations based on a 37-bus electrical grid and traces of real electrical load demonstrate the effectiveness of this scheme. In particular, if customers are, as expected, sufficiently committed to the load curtailment, overloads can be resolved in real time by collaborative and graceful usage degradation among them, thereby avoiding unpleasant blackouts in existing practice.

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Cited By

Chhokra AKulkarni AHasan SDubey AMahadevan NKarsai G(2017)A Systematic Approach of Identifying Optimal Load Control Actions for Arresting Cascading Failures in Power SystemsProceedings of the 2nd Workshop on Cyber-Physical Security and Resilience in Smart Grids10.1145/3055386.3055395(41-46)Online publication date: 18-Apr-2017
https://dl.acm.org/doi/10.1145/3055386.3055395
Ghosh UDong XTan RKalbarczyk ZYau DIyer RZhou JLopez J(2016)A Simulation Study on Smart Grid Resilience under Software-Defined Networking Controller FailuresProceedings of the 2nd ACM International Workshop on Cyber-Physical System Security10.1145/2899015.2899020(52-58)Online publication date: 30-May-2016
https://dl.acm.org/doi/10.1145/2899015.2899020
Dong XLin HTan RIyer RKalbarczyk ZZhou JZhou JJones D(2015)Software-Defined Networking for Smart Grid ResilienceProceedings of the 1st ACM Workshop on Cyber-Physical System Security10.1145/2732198.2732203(61-68)Online publication date: 14-Apr-2015
https://dl.acm.org/doi/10.1145/2732198.2732203

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Information

Published In

cover image ACM Conferences

ICCPS '14: ICCPS '14: ACM/IEEE 5th International Conference on Cyber-Physical Systems (with CPS Week 2014)

April 2014

245 pages

ISBN:9781479949304

General Chairs:
P. R. Kumar
Texas A&M University, USA
,
Radu Stoleru
Texas A&M University, USA
,
Program Chairs:
Alexandre Bayen
University of California, Berkeley, USA
,
Michael Branicky
University of Kansas, USA
,
Publications Chair:
Michael Branicky
University of Kansas, USA

Sponsors

IEEE-CS\TCRT: TC on Real-Time Systems
SIGBED: ACM Special Interest Group on Embedded Systems

Publisher

IEEE Computer Society

United States

Publication History

Published: 15 April 2014

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ICCPS '14

Sponsor:

IEEE-CS\TCRT
SIGBED

ICCPS '14: ACM/IEEE 5th International Conference on Cyber-Physical Systems

April 15 - 17, 2014

Berlin, Germany

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Overall Acceptance Rate 25 of 91 submissions, 27%

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Citations

Cited By

Chhokra AKulkarni AHasan SDubey AMahadevan NKarsai G(2017)A Systematic Approach of Identifying Optimal Load Control Actions for Arresting Cascading Failures in Power SystemsProceedings of the 2nd Workshop on Cyber-Physical Security and Resilience in Smart Grids10.1145/3055386.3055395(41-46)Online publication date: 18-Apr-2017
https://dl.acm.org/doi/10.1145/3055386.3055395
Ghosh UDong XTan RKalbarczyk ZYau DIyer RZhou JLopez J(2016)A Simulation Study on Smart Grid Resilience under Software-Defined Networking Controller FailuresProceedings of the 2nd ACM International Workshop on Cyber-Physical System Security10.1145/2899015.2899020(52-58)Online publication date: 30-May-2016
https://dl.acm.org/doi/10.1145/2899015.2899020
Dong XLin HTan RIyer RKalbarczyk ZZhou JZhou JJones D(2015)Software-Defined Networking for Smart Grid ResilienceProceedings of the 1st ACM Workshop on Cyber-Physical System Security10.1145/2732198.2732203(61-68)Online publication date: 14-Apr-2015
https://dl.acm.org/doi/10.1145/2732198.2732203

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