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Scalable, Physical Effects Measureable Microgridfor Cyber Resilience Analysis

RESOURCE

Publicly Accessible Repository
https://github.com/idaholab/SPEMMCRA
https://doi.org/10.11578/dc.20210413.1

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Abstract

SPEMMCRA provides a low-cost simulated method to provide for testing of control theory and cybersecurity approaches to microgrid implementations. Specifically, this physics-based approach provides realistic responses to compare control strategies in simulation, but also to demonstrate actions that can or cannot be taken in taking cybersecurity actions . As communications interfaces or other actions are taken that affect the flow of data, SPEMMCRA can show whether the microgrid operation is adversely affected by what is intended to mitigate a cybersecurity event.
Developers:
Rieger, Craig [1] Ulrich, Jacob [1] McJunkin, Tiimothy [1] Springer, Edward [1] Runyon, Michael
  1. Idaho National Lab. (INL), Idaho Falls, ID (United States)
Release Date:
2021-02-23
Project Type:
Open Source, Publicly Available Repository
Software Type:
Scientific
Programming Languages:
Python
Licenses:
BSD 3-clause "New" or "Revised" License
Sponsoring Org.:
Code ID:
54139
Research Org.:
Idaho National Laboratory (INL), Idaho Falls, ID (United States)
Country of Origin:
United States
Keywords:
industrial control system; automated security; scalable Microgrid; cyber-physical system

RESOURCE

Publicly Accessible Repository
https://github.com/idaholab/SPEMMCRA
https://doi.org/10.11578/dc.20210413.1

SAVE / SHARE



INL Badge

Citation Formats

Rieger, Craig G., Ulrich, Jacob J., McJunkin, Tiimothy R., Springer, Edward E., and Runyon, Michael. Scalable, Physical Effects Measureable Microgridfor Cyber Resilience Analysis. Computer Software. https://github.com/idaholab/SPEMMCRA. USDOE Office of Nuclear Energy (NE). 23 Feb. 2021. Web. doi:10.11578/dc.20210413.1.
Rieger, Craig G., Ulrich, Jacob J., McJunkin, Tiimothy R., Springer, Edward E., & Runyon, Michael. (2021, February 23). Scalable, Physical Effects Measureable Microgridfor Cyber Resilience Analysis. [Computer software]. https://github.com/idaholab/SPEMMCRA. https://doi.org/10.11578/dc.20210413.1.
Rieger, Craig G., Ulrich, Jacob J., McJunkin, Tiimothy R., Springer, Edward E., and Runyon, Michael. "Scalable, Physical Effects Measureable Microgridfor Cyber Resilience Analysis." Computer software. February 23, 2021. https://github.com/idaholab/SPEMMCRA. https://doi.org/10.11578/dc.20210413.1.
@misc{ doecode_54139,
title = {Scalable, Physical Effects Measureable Microgridfor Cyber Resilience Analysis},
author = {Rieger, Craig G. and Ulrich, Jacob J. and McJunkin, Tiimothy R. and Springer, Edward E. and Runyon, Michael},
abstractNote = {SPEMMCRA provides a low-cost simulated method to provide for testing of control theory and cybersecurity approaches to microgrid implementations. Specifically, this physics-based approach provides realistic responses to compare control strategies in simulation, but also to demonstrate actions that can or cannot be taken in taking cybersecurity actions . As communications interfaces or other actions are taken that affect the flow of data, SPEMMCRA can show whether the microgrid operation is adversely affected by what is intended to mitigate a cybersecurity event.},
doi = {10.11578/dc.20210413.1},
url = {https://doi.org/10.11578/dc.20210413.1},
howpublished = {[Computer Software] \url{https://doi.org/10.11578/dc.20210413.1}},
year = {2021},
month = {feb}
}