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新冠疫情期间电力系统中负荷变化攻击的可行性研究

On the Feasibility of Load-Changing Attacks in Power Systems During the COVID-19 Pandemic.

作者信息

Ospina Juan, Liu Xiaorui, Konstantinou Charalambos, Dvorkin Yury

机构信息

Center for Advanced Power Systems, FAMU-FSU College of EngineeringFlorida State University Tallahassee FL 32310 USA.

Department of Electrical and Computer EngineeringCenter for Urban Science and ProgressNew York University Brooklyn NY 11201 USA.

出版信息

IEEE Access. 2020 Dec 25;9:2545-2563. doi: 10.1109/ACCESS.2020.3047374. eCollection 2021.

DOI:10.1109/ACCESS.2020.3047374
PMID:34812376
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8545244/
Abstract

The electric power grid is a complex cyberphysical energy system (CPES) in which information and communication technologies (ICT) are integrated into the operations and services of the power grid infrastructure. The growing number of Internet-of-things (IoT) high-wattage appliances, such as air conditioners and electric vehicles, being connected to the power grid, together with the high dependence of ICT and control interfaces, make CPES vulnerable to high-impact, low-probability load-changing cyberattacks. Moreover, the side-effects of the COVID-19 pandemic demonstrate a modification of electricity consumption patterns with utilities experiencing significant net-load and peak reductions. These unusual sustained low load demand conditions could be leveraged by adversaries to cause frequency instabilities in CPES by compromising hundreds of thousands of IoT-connected high-wattage loads. This article presents a feasibility study of the impacts of load-changing attacks on CPES during the low loading conditions caused by the lockdown measures implemented during the COVID-19 pandemic. The load demand reductions caused by the lockdown measures are analyzed using dynamic mode decomposition (DMD), focusing on the March-to-July 2020 period and the New York region as the most impacted time period and location in terms of load reduction due to the lockdowns being in full execution. Our feasibility study evaluates load-changing attack scenarios using real load consumption data from the New York Independent System Operator (NYISO) and shows that an attacker with sufficient knowledge and resources could be capable of producing frequency stability problems, with frequency excursions going up to 60.5 Hz and 63.4 Hz, when no mitigation measures are taken.

摘要

电网是一个复杂的信息物理能源系统(CPES),其中信息通信技术(ICT)被集成到电网基础设施的运营和服务中。越来越多的物联网(IoT)高功率电器,如空调和电动汽车,连接到电网,再加上ICT和控制接口的高度依赖性,使得CPES容易受到高影响、低概率的负载变化网络攻击。此外,COVID-19大流行的副作用表明,电力消费模式发生了变化,公用事业公司的净负载和峰值大幅下降。这些异常持续的低负载需求情况可能被对手利用,通过破坏数十万个连接物联网的高功率负载,在CPES中造成频率不稳定。本文介绍了一项可行性研究,研究在COVID-19大流行期间实施封锁措施导致的低负载条件下,负载变化攻击对CPES的影响。使用动态模式分解(DMD)分析封锁措施导致的负载需求减少情况,重点关注2020年3月至7月期间以及纽约地区,因为就封锁全面实施导致的负载减少而言,该时间段和地区受影响最大。我们的可行性研究使用来自纽约独立系统运营商(NYISO)的实际负载消耗数据评估负载变化攻击场景,结果表明,在不采取缓解措施的情况下,拥有足够知识和资源的攻击者可能会导致频率稳定性问题,频率偏移高达60.5赫兹和63.4赫兹。

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