Deep-Learning-Directed Preventive Dynamic Security Control via Coordinated Demand Response
- URL: http://arxiv.org/abs/2504.04059v1
- Date: Sat, 05 Apr 2025 04:46:36 GMT
- Title: Deep-Learning-Directed Preventive Dynamic Security Control via Coordinated Demand Response
- Authors: Amin Masoumi, Mert Korkali,
- Abstract summary: Three-phase short-circuit faults in power systems pose significant challenges.<n>These faults can lead to out-of-step (OOS) conditions and jeopardize the system's dynamic security.<n>This paper proposes an end-to-end deep-learning-based mechanism, namely, a convolutional neural network with an attention mechanism, to predict OOS conditions early and enhance the system's fault resilience.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Unlike common faults, three-phase short-circuit faults in power systems pose significant challenges. These faults can lead to out-of-step (OOS) conditions and jeopardize the system's dynamic security. The rapid dynamics of these faults often exceed the time of protection actions, thus limiting the effectiveness of corrective schemes. This paper proposes an end-to-end deep-learning-based mechanism, namely, a convolutional neural network with an attention mechanism, to predict OOS conditions early and enhance the system's fault resilience. The results of the study demonstrate the effectiveness of the proposed algorithm in terms of early prediction and robustness against such faults in various operating conditions.
Related papers
- Exploiting Efficiency Vulnerabilities in Dynamic Deep Learning Systems [3.5986950487788185]
This work investigates the security implications of dynamic behaviors in deep learning systems (DDLSs)<n>We show how current systems expose efficiency vulnerabilities exploitable by adversarial inputs.<n>We propose to examine the feasibility of efficiency attacks on modern DDLSs and develop targeted defenses.
arXiv Detail & Related papers (2025-06-21T07:13:14Z) - Efficiency Robustness of Dynamic Deep Learning Systems [11.688510012136968]
Dynamic Deep Learning Systems (DDLSs) adapt computation based on input complexity, reducing overhead.<n>This paper systematically explores efficiency of DDLSs, presenting the first comprehensive taxonomy of efficiency attacks.<n>We analyze adversarial strategies that target DDLSs efficiency and identify key challenges in securing these systems.
arXiv Detail & Related papers (2025-06-12T15:49:01Z) - Hybrid Temporal Differential Consistency Autoencoder for Efficient and Sustainable Anomaly Detection in Cyber-Physical Systems [0.0]
Cyberattacks on critical infrastructure, particularly water distribution systems, have increased due to rapid digitalization.
This study addresses key challenges in anomaly detection by leveraging time correlations in sensor data.
We propose a hybrid autoencoder-based approach, referred to as hybrid TDC-AE, which extends TDC by incorporating both deterministic nodes and conventional statistical nodes.
arXiv Detail & Related papers (2025-04-08T09:22:44Z) - Anomaly Detection in Complex Dynamical Systems: A Systematic Framework Using Embedding Theory and Physics-Inspired Consistency [0.0]
Anomaly detection in complex dynamical systems is essential for ensuring reliability, safety, and efficiency in industrial and cyber-physical infrastructures.<n>We propose a system-theoretic approach to anomaly detection, grounded in classical embedding theory and physics-inspired consistency principles.<n>Our findings support the hypothesis that anomalies disrupt stable system dynamics, providing a robust, interpretable signal for anomaly detection.
arXiv Detail & Related papers (2025-02-26T17:06:13Z) - Global-Decision-Focused Neural ODEs for Proactive Grid Resilience Management [50.34345101758248]
We propose predict-all-then-optimize-globally (PATOG), a framework that integrates outage prediction with globally optimized interventions.
Our approach ensures spatially and temporally coherent decision-making, improving both predictive accuracy and operational efficiency.
Experiments on synthetic and real-world datasets demonstrate significant improvements in outage prediction consistency and grid resilience.
arXiv Detail & Related papers (2025-02-25T16:15:35Z) - Improved deep learning of chaotic dynamical systems with multistep penalty losses [0.0]
Predicting the long-term behavior of chaotic systems remains a formidable challenge.
This paper introduces a novel framework that addresses these challenges by leveraging the recently proposed multi-step penalty operators.
arXiv Detail & Related papers (2024-10-08T00:13:57Z) - Causal Interventional Prediction System for Robust and Explainable Effect Forecasting [14.104665282086339]
We explore the robustness and explainability of AI-based forecasting systems.
We design a causal interventional prediction system (CIPS) based on a variational autoencoder and fully conditional specification of multiple imputations.
arXiv Detail & Related papers (2024-07-29T04:16:45Z) - Enhancing Functional Safety in Automotive AMS Circuits through Unsupervised Machine Learning [9.100418852199082]
We propose a novel framework based on unsupervised machine learning for early anomaly detection in AMS circuits.
The proposed approach involves injecting anomalies at various circuit locations and individual components to create a diverse and comprehensive anomaly dataset.
By monitoring the system behavior under these anomalous conditions, we capture the propagation of anomalies and their effects at different abstraction levels.
arXiv Detail & Related papers (2024-04-02T04:33:03Z) - FaultGuard: A Generative Approach to Resilient Fault Prediction in Smart Electrical Grids [53.2306792009435]
FaultGuard is the first framework for fault type and zone classification resilient to adversarial attacks.
We propose a low-complexity fault prediction model and an online adversarial training technique to enhance robustness.
Our model outclasses the state-of-the-art for resilient fault prediction benchmarking, with an accuracy of up to 0.958.
arXiv Detail & Related papers (2024-03-26T08:51:23Z) - Disentangling the Causes of Plasticity Loss in Neural Networks [55.23250269007988]
We show that loss of plasticity can be decomposed into multiple independent mechanisms.
We show that a combination of layer normalization and weight decay is highly effective at maintaining plasticity in a variety of synthetic nonstationary learning tasks.
arXiv Detail & Related papers (2024-02-29T00:02:33Z) - Ranking-Based Physics-Informed Line Failure Detection in Power Grids [66.0797334582536]
Real-time and accurate detecting of potential line failures is the first step to mitigating the extreme weather impact and activating emergency controls.
Power balance equations nonlinearity, increased uncertainty in generation during extreme events, and lack of grid observability compromise the efficiency of traditional data-driven failure detection methods.
This paper proposes a Physics-InformEd Line failure Detector (FIELD) that leverages grid topology information to reduce sample and time complexities and improve localization accuracy.
arXiv Detail & Related papers (2022-08-31T18:19:25Z) - Recursively Feasible Probabilistic Safe Online Learning with Control Barrier Functions [60.26921219698514]
We introduce a model-uncertainty-aware reformulation of CBF-based safety-critical controllers.
We then present the pointwise feasibility conditions of the resulting safety controller.
We use these conditions to devise an event-triggered online data collection strategy.
arXiv Detail & Related papers (2022-08-23T05:02:09Z) - Large-Scale Sequential Learning for Recommender and Engineering Systems [91.3755431537592]
In this thesis, we focus on the design of an automatic algorithms that provide personalized ranking by adapting to the current conditions.
For the former, we propose novel algorithm called SAROS that take into account both kinds of feedback for learning over the sequence of interactions.
The proposed idea of taking into account the neighbour lines shows statistically significant results in comparison with the initial approach for faults detection in power grid.
arXiv Detail & Related papers (2022-05-13T21:09:41Z) - Sparsity in Partially Controllable Linear Systems [56.142264865866636]
We study partially controllable linear dynamical systems specified by an underlying sparsity pattern.
Our results characterize those state variables which are irrelevant for optimal control.
arXiv Detail & Related papers (2021-10-12T16:41:47Z) - Robust Optimization and Validation of Echo State Networks for learning
chaotic dynamics [6.345523830122166]
An approach to the time-accurate prediction of chaotic solutions is by learning temporal patterns from data.
Existing studies showed that small changes in the hyper parameters may markedly affect the network's performance.
This paper aims to assess and improve the robustness of Echo State Networks for the time-accurate prediction of chaotic solutions.
arXiv Detail & Related papers (2021-02-09T22:24:00Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.