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43 results on '"Davis, Katherine R."'

1. Cooperative Optimization of Grid-Edge Cyber and Physical Resources for Resilient Power System Operation

Author

Huo, Xiang, Sun, Shining, Haque, Khandaker Akramul, Homoud, Leen Al, Goulart, Ana E., and Davis, Katherine R.

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

The cooperative operation of grid-edge power and energy resources is crucial to improving the resilience of power systems during contingencies. However, given the complex cyber-physical nature of power grids, it is hard to respond timely with limited costs for deploying additional cyber and/or phyiscal resources, such as during a high-impact low-frequency cyber-physical event. Therefore, the paper examines the design of cooperative cyber-physical resource optimization solutions to control grid-tied cyber and physical resources. First, the operation of a cyber-physical power system is formulated into a constrained optimization problem, including the cyber and physical objectives and constraints. Then, a bi-level solution is provided to obtain optimal cyber and physical actions, including the reconfiguration of cyber topology (e.g., activation of communication links) in the cyber layer and the control of physical resources (e.g., energy storage systems) in the physical layer. The developed method improves grid resilience during cyberattacks and can provide guidance on the control of coupled physical side resources. Numerical simulation on a modified IEEE 14-bus system demonstrates the effectiveness of the proposed approach.

Published
2025

2. A Review of Scalable and Privacy-Preserving Multi-Agent Frameworks for Distributed Energy Resources

Author

Huo, Xiang, Huang, Hao, Davis, Katherine R., Poor, H. Vincent, and Liu, Mingxi

Subjects
Electrical Engineering and Systems Science - Systems and Control, Mathematics - Optimization and Control
Abstract

Distributed energy resources (DERs) are gaining prominence due to their advantages in improving energy efficiency, reducing carbon emissions, and enhancing grid resilience. Despite the increasing deployment, the potential of DERs has yet to be fully explored and exploited. A fundamental question restrains the management of numerous DERs in large-scale power systems, "How should DER data be securely processed and DER operations be efficiently optimized?" To address this question, this paper considers two critical issues, namely privacy for processing DER data and scalability in optimizing DER operations, then surveys existing and emerging solutions from a multi-agent framework perspective. In the context of scalability, this paper reviews state-of-the-art research that relies on parallel control, optimization, and learning within distributed and/or decentralized information exchange structures, while in the context of privacy, it identifies privacy preservation measures that can be synthesized into the aforementioned scalable structures. Despite research advances in these areas, challenges remain because these highly interdisciplinary studies blend a wide variety of scalable computing architectures and privacy preservation techniques from different fields, making them difficult to adapt in practice. To mitigate this issue, this paper provides a holistic review of trending strategies that orchestrate privacy and scalability for large-scale power system operations from a multi-agent perspective, particularly for DER control problems. Furthermore, this review extrapolates new approaches for future scalable, privacy-aware, and cybersecure pathways to unlock the full potential of DERs through controlling, optimizing, and learning generic multi-agent-based cyber-physical systems.

Published
2024

3. Tightening QC Relaxations of AC Optimal Power Flow through Improved Linear Convex Envelopes

Author

Narimani, Mohammad Rasoul, Molzahn, Daniel K., Davis, Katherine R., and Crow, Mariesa L.

Subjects
Mathematics - Optimization and Control
Abstract

AC optimal power flow (AC OPF) is a fundamental problem in power system operations. Accurately modeling the network physics via the AC power flow equations makes AC OPF a challenging nonconvex problem. To search for global optima, recent research has developed a variety of convex relaxations that bound the optimal objective values of AC OPF problems. The well-known QC relaxation convexifies the AC OPF problem by enclosing the non-convex terms (trigonometric functions and products) within convex envelopes. The accuracy of this method strongly depends on the tightness of these envelopes. This paper proposes two improvements for tightening QC relaxations of OPF problems. We first consider a particular nonlinear function whose projections are the nonlinear expressions appearing in the polar representation of the power flow equations. We construct a convex envelope around this nonlinear function that takes the form of a polytope and then use projections of this envelope to obtain convex expressions for the nonlinear terms. Second, we use certain characteristics of the sine and cosine expressions along with the changes in their curvature to tighten this convex envelope. We also propose a coordinate transformation that rotates the power flow equations by an angle specific to each bus in order to obtain a tighter envelope. We demonstrate these improvements relative to a state-of-the-art QC relaxation implementation using the PGLib-OPF test cases. The results show improved optimality gaps in 68% of these cases.

Published
2023

4. Federated Learning Based Distributed Localization of False Data Injection Attacks on Smart Grids

Author

Keçeci, Cihat, Davis, Katherine R., and Serpedin, Erchin

Subjects
Computer Science - Machine Learning, Computer Science - Cryptography and Security
Abstract

Data analysis and monitoring on smart grids are jeopardized by attacks on cyber-physical systems. False data injection attack (FDIA) is one of the classes of those attacks that target the smart measurement devices by injecting malicious data. The employment of machine learning techniques in the detection and localization of FDIA is proven to provide effective results. Training of such models requires centralized processing of sensitive user data that may not be plausible in a practical scenario. By employing federated learning for the detection of FDIA attacks, it is possible to train a model for the detection and localization of the attacks while preserving the privacy of sensitive user data. However, federated learning introduces new problems such as the personalization of the detectors in each node. In this paper, we propose a federated learning-based scheme combined with a hybrid deep neural network architecture that exploits the local correlations between the connected power buses by employing graph neural networks as well as the temporal patterns in the data by using LSTM layers. The proposed mechanism offers flexible and efficient training of an FDIA detector in a distributed setup while preserving the privacy of the clients. We validate the proposed architecture by extensive simulations on the IEEE 57, 118, and 300 bus systems and real electricity load data., Comment: 9 pages, 6 figures

Published
2023

5. An Extended Model for Ecological Robustness to Capture Power System Resilience

Author

Huang, Hao, Davis, Katherine R., and Poor, H. Vincent

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

The long-term resilient property of ecosystems has been quantified as ecological robustness (RECO) in terms of the energy transfer over food webs. The RECO of resilient ecosystems favors a balance of food webs' network efficiency and redundancy. By integrating RECO with power system constraints, the authors are able to optimize power systems' inherent resilience as ecosystems through network design and system operation. A previous model used on real power flows and aggregated redundant components for a rigorous mapping between ecosystems and power systems. However, the reactive power flows also determine power systems resilience; and the power components' redundancy is part of the global network redundancy. These characteristics should be considered for RECO-oriented evaluation and optimization for power systems. Thus, this paper extends the model for quantifying RECO in power systems using real, reactive, and apparent power flows with the consideration of redundant placement of generators. Recalling the performance of RECO-oriented optimal power flows under N-x contingencies, the analyses suggest reactive power flows and redundant components should be included for RECO to capture power systems' inherent resilience., Comment: Accepted By IEEE PES General Meeting 2023

Published
2023
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6. Graph Autoencoder-Based Detection of Unseen False Data Injection Attacks in Smart Grids

Author

Takiddin, Abdulrahman, Ismail, Muhammad, Atat, Rachad, Davis, Katherine R., Serpedin, Erchin, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, and Arai, Kohei, editor

Published
2024
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8. Toward Efficient Wide-Area Identification of Multiple Element Contingencies in Power Systems

Author

Huang, Hao, Mao, Zeyu, Narimani, Mohammad Rasoul, and Davis, Katherine R.

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

Power system N-x contingency analysis has inherent challenges due to its combinatorial characteristic where outages grow exponentially with the increase of x and N. To address these challenges, this paper proposes a method that utilizes Line Outage Distribution Factors (LODFs) and group betweenness centrality to identify subsets of critical branches. The proposed LODF metrics are used to select the high-impact branches. Based on each selected branch, the approach constructs the subgraph with parameters of distance and search level, while using branches' LODF metrics as the weights. A key innovation of this work is the use of the distance and search level parameters, which allow the subgraph to identify the most coupled critical elements that may be far away from a selected branch. The proposed approach is validated using the 200- and 500-bus test cases, and results show that the proposed approach can identify multiple N-x contingencies that cause violations., Comment: Published in the 12th Conference on Innovative Smart Grid Technologies, North America (ISGT NA)

Published
2021
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9. Real-time Power System Simulation with Hardware Devices through DNP3 in Cyber-Physical Testbed

Author

Huang, Hao, Davis, C. Matthew, and Davis, Katherine R.

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

Modern power grids are dependent on communication systems for data collection, visualization, and control. Distributed Network Protocol 3 (DNP3) is commonly used in supervisory control and data acquisition (SCADA) systems in power systems to allow control system software and hardware to communicate. To study the dependencies between communication network security, power system data collection, and industrial hardware, it is important to enable communication capabilities with real-time power system simulation. In this paper, we present the integration of new functionality of a power systems dynamic simulation package into our cyber-physical power system testbed that supports real-time power system data transfer using DNP3, demonstrated with an industrial real-time automation controller (RTAC). The usage and configuration of DNP3 with real-world equipment in to achieve power system monitoring and control of a large-scale synthetic electric grid via this DNP3 communication is presented. Then, an exemplar of DNP3 data collection and control is achieved in software and hardware using the 2000-bus Texas synthetic grid., Comment: 6 pages, to be published in the 5th Texas Power and Energy Conference

Published
2021
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10. Mixed-Integer Optimization for Bio-Inspired Robust Power Network Design

Author

Huang, Hao, Panyam, Varuneswara, Narimani, Mohammad Rasoul, Layton, Astrid, and Davis, Katherine R.

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

Power systems are susceptible to natural threats including hurricanes and floods. Modern power grids are also increasingly threatened by cyber attacks. Existing approaches that help improve power system security and resilience may not be sufficient; this is evidenced by the continued challenge to supply energy to all customers during severe events. This paper presents an approach to address this challenge through bio-inspired power system network design to improve system reliability and resilience against disturbances. Inspired by naturally robust ecosystems, this paper considers the optimal ecological robustness that recognizes a unique balance between pathway efficiency and redundancy to ensure the survivability against disruptive events for given networks. This paper presents an approach that maximizes ecological robustness in transmission network design by formulating a mixed-integer nonlinear programming optimization problem with power system constraints. The results show the increase of the optimized power system's robustness and the improved reliability with less violations under N-x contingencies., Comment: Published in The 52nd North American Power Symposium

Published
2020
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11. Considerations in the Automatic Development of Electric Grid Restoration Plans

Author

Jang, Wonhyeok, Huang, Hao, Davis, Katherine R., and Overbye, Thomas J.

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

Power system restoration is a highly complex task that must be performed in a timely manner following a blackout. It is crucial to have the capability of developing a reliable restoration plan that can be adjusted quickly to different system conditions. This paper introduces a framework of an automated process that creates a restoration plan for a given power system. The required input includes the original system data under normal operating conditions and the status of the resources in the system that can be used for restoration. With a set of criteria to select as an option, the presented process can produce a restoration sequence in terms of which generator, load, branches, and breakers to close until a stopping criterion is met. The algorithm of the restoration process is described, and its application to a synthetic 200-bus case provides a restoration sequence from blackstart generating units to critical loads first and then to the rest of the system without violating any limits for frequency, voltage and branch loading., Comment: Published in The 52nd North American Power Symposium

Published
2020
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22. Validating an Emulation-Based Cybersecurity Model With a Physical Testbed

Author

Huang, Hao, Wlazlo, Patrick, Sahu, Abhijeet, Walker, Adele, Goulart, Ana E., Davis, Katherine R., Swiler, Laura, Tarman, Thomas D., and Vugrin, Eric

Abstract

For researchers studying cyber-physical system security, working with realistic datasets is essential. To produce the datasets, the existing methodology is to emulate the cyber network. A challenge is that the industrial control systems (ICS) network consists of not just computers and communication equipment, but also field devices that collect data and execute controls. These devices play a significant role in the operation and the security of the system. However, in comparison to the cyber network, the research reproducibility and realism of the cyber-physical system emulation and its data has received far less attention. This article thus develops an approach to answer, ”How well can emulated devices replicate the behavior of physical intelligent electronics devices (IEDs) in a realistic cyber attack and defense environment?” To study this, we perform a comparison study based on an emulation experiment using the minimega testbed environment that is entirely virtual and a hardware-in-the-loop experiment using the Resilient Energy Systems Lab (RESLab) cyber-physical testbed featuring real industrial controllers and communications devices. Results show that under different reconnaissance attack scenarios, RESLab generates realistic datasets that validate the emulation-based cybersecurity model in minimega. The approach is generalizable toward validating the realism of other types of ICS devices in security studies.

Published
2024
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23. An Integrated Assessment of a G3 GMD Event on Large-Scale Power Grids: From Magnetometer Data to Geomagnetically Induced Current Analysis

Author

Dehghanian, Pooria, Zhang, Anna, Fatima, Rida, Snodgrass, Jonathan, Birchfield, Adam B., Davis, Katherine R., and Overbye, Thomas J.

Abstract

Solar activity can cause geomagnetic disturbances (GMDs) that give rise to geomagnetically induced currents (GICs) which may compromise the reliability of the electric grid.In order to build more reliable models representing GMD interactions with the power grid, the power system's detailed electrical model must be considered along with fluctuations in the earth’s magnetic and induced surface electric fields. This study investigates the impact of incorporating spatially varying magnetic fields into surface electric field models on GMD risk metrics. A spatially independent magnetic field model and a spatially varying model are compared through simulations. To perform this analysis, the earth’s magnetic field disturbances are transformed into surface electric fields using respective one-dimensional Earth conductivity models. Then, the modeling impact of these electric fields is studied using a 2,000-bus grid for Texas and a 25,000-bus grid for the northeast and mid-Atlantic regions of the United States. Simulation results reveal that the inclusion of spatially varying magnetic fields results in considerable differences in GMD risk metrics, highlighting the importance of accounting for spatial variability when assessing GMD risks in the power system.

Published
2024
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24. Toward Resilient Modern Power Systems: From Single-Domain to Cross-Domain Resilience Enhancement

Author

Huang, Hao, Vincent Poor, H., Davis, Katherine R., Overbye, Thomas J., Layton, Astrid, Goulart, Ana E., and Zonouz, Saman

Abstract

Modern power systems are the backbone of our society, supplying electric energy for daily activities. With the integration of communication networks and high penetration of renewable energy sources (RESs), modern power systems have evolved into a cross-domain multilayer complex system of systems with improved efficiency, controllability, and sustainability. However, increasing numbers of unexpected events, including natural disasters, extreme weather, and cyberattacks, are compromising the functionality of modern power systems and causing tremendous societal and economic losses. Resilience, a desirable property, is needed in modern power systems to ensure their capability to withstand all kinds of hazards while maintaining their functions. This article presents a systematic review of recent power system resilience enhancement techniques and proposes new directions for enhancing modern power systems’ resilience considering their cross-domain multilayer features. We first answer the question, “what is power system resilience?” from the perspectives of its definition, constituents, and categorization. It is important to recognize that power system resilience depends on two interdependent factors: network design and system operation. Following that, we present a review of articles published since 2016 that have developed innovative methodologies to improve power system resilience and categorize them into infrastructural resilience enhancement and operational resilience enhancement. We discuss their problem formulations and proposed quantifiable resilience measures, as well as point out their merits and limitations. Finally, we argue that it is paramount to leverage higher order subgraph studies and scientific machine learning (SciML) for modern power systems to capture the interdependence and interactions across heterogeneous networks and data for holistically enhancing their infrastructural and operational resilience.

Published
2024
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