Intrinsically resilient energy control systems

Authors:
Frederick Sheldon;Daniel Fetzer;David Manz;Jingshan Huang;Stuart Goose;Thomas Morris;Jiangbo Dang;Jonathan Kirsch;Dong Wei
Affiliations:
Oak Ridge National Laboratory, Oak Ridge, TN;Oak Ridge National Laboratory, Oak Ridge, TN;Pacific Northwest National Laboratory, Richland, WA;University of South Alabama, Mobile, AL;Siemens Corporation, Berkeley, CA;Mississippi State University, Mississippi State, MS;Siemens Corporation, Princeton, NJ;Siemens Corporation, Berkeley, CA;Siemens Corporation, Princeton, NJ
Venue:
Proceedings of the Eighth Annual Cyber Security and Information Intelligence Research Workshop
Year:
2013

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Abstract

To preserve critical energy control functions while under attack, it is necessary to perform comprehensive analysis on the root cause and impact of an ongoing cyber intrusion without sacrificing the availability of energy delivery. In this position paper, we present a proof of concept of an intrinsically resilient energy control system, with the ultimate goal of ensuring availability/resiliency of energy delivery functions, along with the capability to assess root causes and impacts of cyber intrusions.