From f685919879cbd8837da4f454a15417c04891550e Mon Sep 17 00:00:00 2001 From: Dane Sabo Date: Wed, 29 Jan 2025 12:19:46 -0500 Subject: [PATCH] vault backup: 2025-01-29 12:19:46 --- 201 Metadata/My Library.bib | 14 ++++++++++++++ 1 file changed, 14 insertions(+) diff --git a/201 Metadata/My Library.bib b/201 Metadata/My Library.bib index 6c4a41b3..14acb4e6 100644 --- a/201 Metadata/My Library.bib +++ b/201 Metadata/My Library.bib @@ -5345,6 +5345,20 @@ Regulatory Premises.pdf} keywords = {Coronavirus,COVID-19,Most Valuable Player Algorithm,Nonlinear system,Robust control algorithm,Variable Transformation Technique} } +@report{hahnAdvancedReactorCyber2023, + title = {Advanced {{Reactor Cyber Analysis}} and {{Development Environment}} ({{ARCADE}}) for {{System-Level Design Analysis}}}, + author = {Hahn, Andrew Stuart and Maccarone, Lee T. and Rowland, Michael Terence}, + date = {2023-09-01}, + number = {SAND-2023-09408}, + institution = {Sandia National Lab. (SNL-NM), Albuquerque, NM (United States)}, + doi = {10.2172/2430308}, + url = {https://www.osti.gov/biblio/2430308}, + urldate = {2025-01-29}, + abstract = {Cybersecurity is a persistent concern to the safety and security of Nuclear Power Plants (NPPs), but has lacked data-driven, evidence-based research. Rigorous cybersecurity analysis is critical for the licensing of advanced reactors using a performance-based approach. One tool that enables cybersecurity analysis is modeling and simulation. The nuclear industry makes extensive use of modeling and simulation throughout the decision process but lacks a method to incorporate cybersecurity analysis with existing models. To meet this need, the Advanced Reactor Cyber Analysis and Development Environment (ARCADE) was developed. ARCADE is a suite of publicly available tools that can be used to develop emulations of industrial control system devices and networks and integrate those emulations with physics simulators. This integration of cyber emulations and physics models enables rigorous cyber-physical analysis of cyber-attacks on NPP systems. This report provides an overview of key considerations for using ARCADE with existing physics models and demonstrates ARCADE’s capabilities for cybersecurity analysis. Using a model of the Small Modular Advanced High Temperature Reactor (SmAHTR), ARCADE was able to determine the sensitivity of the primary heat exchangers (PHX) to coordinated cyber-attacks. The analysis determined that while the PHX’s failures cause disruption to the reactor, they did not cause any safety limits to be exceeded because of the plant design, including passive safety features. Further development of ARCADE will enable rigorous, repeatable, and automated cyber-physical analysis of advanced reactor control systems. These efforts will also help reduce regulatory uncertainty by presenting similar types of cybersecurity analyses in a common format, driving standard approaches and reporting.}, + langid = {english}, + file = {/home/danesabo/Zotero/storage/NPKMTWW5/Hahn et al. - 2023 - Advanced Reactor Cyber Analysis and Development Environment (ARCADE) for System-Level Design Analysi.pdf} +} + @article{hahnAUTOMATEDCYBERSECURITY, title = {{{AUTOMATED CYBER SECURITY TESTING PLATFORM FOR INDUSTRIAL CONTROL SYSTEMS}}}, author = {Hahn, Andrew and Sandoval, Daniel R and Fasano, Raymond E and Lamb, Christopher},