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sa    2017, Vol. 3 Issue (5) : 580-582
News & Highlights |
Ben A. Wender1,M. Granger Morgan2,K. John Holmes1
1. Board on Energy and Environmental Systems, Division on Engineering and Physical Sciences, The National Academies of Sciences, Engineering, and Medicine, Washington, DC 20001, USA
2. Department of Engineering and Public Policy, Carnegie Mellon University, Pittsburgh, PA 15213, USA
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在线预览日期:    发布日期: 2017-11-08
Ben A. Wender
M. Granger Morgan
K. John Holmes
Ben A. Wender,M. Granger Morgan,K. John Holmes. Enhancing the Resilience of Electricity Systems[J]. Engineering, 2017, 3(5): 580-582.
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Fig.1  Large electricity outages can be caused by many diverse threats (shown in alphabetical order). (Reproduced from Ref. [1])
Fig.2  The resilience process involves not only preparing to prevent outages (Stage 1), but also minimizing the impacts of outages during events (Stage 2), recovering quickly after outages (Stage 3), and continually learning to improve performance during future events (Stage 4). The committee organized much of the report following these stages. (This figure was modified slightly from the original produced by the National Infrastructure Advisory Council [3])
1 National Academies of Sciences, Engineering, and Medicine. Enhancing the resilience of the nation’s electricity system.Washington, DC: The National Academies Press; 2017.
2 United States’ electric grid remains vulnerable to natural disasters, cyber and physical attacks; actions needed to improve resiliency of the power system [Internet]. Washington, DC: National Academy of Sciences; 2017 Jul 20 [cited 2017 Sep 28]. Available from:
3 Berkeley AR III, Wallace M. A framework for establishing critical infrastructure resilience goals: Final report and recommendations by the Council [Internet]. Washington, DC: National Infrastructure Advisory Council; 2010 Oct 19 [cited 2017 Sep 28]. Available from:
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