Towards a collaborative framework to improve urban grid resilience

Jung, Oliver; Bessler, Sandford; Ceccarelli, Andrea; Zoppi, Tommaso; Vasenev, Alexandr; Montoya, Lorena; Clarke, Tony; Chappell, Keith J.

doi:10.1109/energycon.2016.7513887

Cited by 14 publications

(12 citation statements)

References 6 publications

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“…Based on the Smart Grid scenario, we show how the methodology can be applied to support threat analysis of an SoS. As reference threat and mitigation lists, we considered the work done in the context of the IRENE project [34]. Here the authors of the cyber-security analysis of smart grids [12] derived a list of 38 threats to the urban grid mainly due to cyber-security (i.e., 29 cybersecurity threats and 9 related either to environmental and accidental threats) based on the NIST 800-30 [10] guidelines.…”

Section: Applying the Methodology To The Smart Grid Scenariomentioning

confidence: 99%

“…Code, Language, and Interfaces. We chose Java as reference platform since it is not OS dependent and since other tools in the IRENE [34] toolset were developed with the same language. Nevertheless, the tool doesn't have a graphical interface since it is intended to be used in cooperation with other tools by the toolset above that offer a graphical user interface.…”

Section: Tool Characteristicsmentioning

confidence: 99%

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Threat Analysis in Systems-of-Systems

Ceccarelli

Zoppi

Vasenev

et al. 2018

ACM Trans. Cyber-Phys. Syst.

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Cyber-physical Systems of Systems (SoSs) are large-scale systems made of independent and autonomous cyber-physical Constituent Systems (CSs) which may interoperate to achieve high-level goals also with the intervention of humans. Providing security in such SoSs means, among other features, forecasting and anticipating evolving SoS functionalities, ultimately identifying possible detrimental phenomena that may result from the interactions of CSs and humans. Such phenomena, usually called emergent phenomena, are often complex and difficult to capture: the first appearance of an emergent phenomenon in a cyber-physical SoS is often a surprise to the observers. Adequate support to understand emergent phenomena will assist in reducing both the likelihood of design or operational flaws, and the time needed to analyze the relations amongst the CSs, which always has a key economic significance. This article presents a threat analysis methodology and a supporting tool aimed at (i) identifying (emerging) threats in evolving SoSs, (ii) reducing the cognitive load required to understand an SoS and the relations among CSs, and (iii) facilitating SoS risk management by proposing mitigation strategies for SoS administrators. The proposed methodology, as well as the tool, is empirically validated on Smart Grid case studies by submitting questionnaires to a user base composed of 3 stakeholders and 18 BSc and MSc students. CCS Concepts: • Software and its engineering → Risk management; • Security and privacy → Software security engineering; • Applied computing → IT architectures; • Computer systems organization → Embedded and cyber-physical systems;

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Section: Applying the Methodology To The Smart Grid Scenariomentioning

confidence: 99%

Section: Tool Characteristicsmentioning

confidence: 99%

Threat Analysis in Systems-of-Systems

Ceccarelli

Zoppi

Vasenev

et al. 2018

ACM Trans. Cyber-Phys. Syst.

Self Cite

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“…Methodologies for active engagement of communities in the introduction and management of local energy resources facilitate sustainable resource management in future power systems (Alvial-Palavicino et al 2011;Cai et al 2017;Jung et al 2016;Adu-Kankam and L. M. -Matos 2018;Katre et al 2019;Arentsen and Bellekom 2014;Hufen and Koppenjan 2015). Energy communities can potentially play an important role in facilitating energy interventions, because they enhance trust relationships, support behavioral changes and encourage other local benefits, such as lower energy bills, new local jobs, increase in the sense of ownership, but also reduction of carbon emissions (OVO Energy 2014; Šćepanović et al 2017).…”

Section: Introductionmentioning

confidence: 99%

Self-determined distribution of local energy resources for ensuring power supply during outages

2019

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Ensuring access to reliable and sustainable power supply is becoming more and more challenging due to a combination of factors such as more frequent power grid outages caused by extreme weather events, the large-scale introduction of renewable energy resources that increases the complexity of the power system, but also aging infrastructure, supply and demand imbalance and power theft in some areas. Combined, all these factors can cause outages and together they can make electricity supply unreliable. The implications of this are many, ranging from minor inconveniences to major failures of critical infrastructures. A potential solution to ensure power supply during outages is to use local generation in the form of renewable resources to supply energy. This paper proposes a community-based mechanism that demonstrates that when community members can determine for themselves how excess energy generation is distributed, the power supply of specific members can be ensured. Self-determination is achieved by prioritizing and differentiating between community members as well as automatically and continuously redistributing energy, thereby adapting to sudden changes in supply and demand. Simulation results show that the proposed mechanism can be used to empower local communities to decide for themselves how local resources are distributed during events such as outages, ensuring prolonged power supply for differentiated members of affected communities. Harnessing the potential of renewable resources and smart technologies for intelligent coordination through empowerment of consumers to become pro-active participants is a promising solution for the future power systems.

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“…As a result, there might be many threats falling into the same category. For example, even though the IRENE project [11] has refined a list of 102 threats (outlined in NIST 800−30 [12]) into a list of 38 potential smart grid cyber-threats, the analysis of these threats using FAIR can be difficult as FAIR provides little guidance on how to handle threats within the same class. Thus, finding a way to rank threats within a class, with respect to the input uncertainty, would be desirable.…”

Section: Introductionmentioning

confidence: 99%

Incorporating FAIR into Bayesian Network for Numerical Assessment of Loss Event Frequencies of Smart Grid Cyber Threats

Chen

Chai

et al. 2018

Mobile Netw Appl

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In today's cyber world, assessing security threats before implementing smart grids is essential to identify and mitigate the risks. Loss Event Frequency (LEF) is a concept provided by the well-known Factor Analysis of Information Risk (FAIR) framework to assess and categorize the cyber threats into five classes, based on their severity. As the number of threats is increasing, it is possible that many threats might fall under the same LEF category, but FAIR cannot provide any further mechanism to rank them. In this paper, we propose a method to incorporate the FAIR's LEF into Bayesian Network (BN) to derive the numerical assessments to rank the threat severity. The BN probabilistic relations are inferred from the FAIR lookup tables to reflect and conserve the FAIR appraisal. Our approach extends FAIR functionality by providing a more detailed ranking, allowing fuzzy inputs, enabling the illustration of input-output relations, and identifying the most influential element of a threat to improve the effectiveness of countermeasure investment. Such improvements are demonstrated by applying the method to assess cyber threats in a smart grid robustness research project (IRENE).

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Towards a collaborative framework to improve urban grid resilience

Cited by 14 publications

References 6 publications

Threat Analysis in Systems-of-Systems

Threat Analysis in Systems-of-Systems

Self-determined distribution of local energy resources for ensuring power supply during outages

Incorporating FAIR into Bayesian Network for Numerical Assessment of Loss Event Frequencies of Smart Grid Cyber Threats

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