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Game Theoretic Resilience Recommendation Framework for CyberPhysical Microgrids Using Hypergraph MetaLearning

ai-safety › robustness

📄 Abstract

Abstract: This paper presents a physics-aware cyberphysical resilience framework for radial microgrids under coordinated cyberattacks. The proposed approach models the attacker through a hypergraph neural network (HGNN) enhanced with model agnostic metalearning (MAML) to rapidly adapt to evolving defense strategies and predict high-impact contingencies. The defender is modeled via a bi-level Stackelberg game, where the upper level selects optimal tie-line switching and distributed energy resource (DER) dispatch using an Alternating Direction Method of Multipliers (ADMM) coordinator embedded within the Non-dominated Sorting Genetic Algorithm II (NSGA-II). The framework simultaneously optimizes load served, operational cost, and voltage stability, ensuring all post-defense states satisfy network physics constraints. The methodology is first validated on the IEEE 69-bus distribution test system with 12 DERs, 8 critical loads, and 5 tie-lines, and then extended to higher bus systems including the IEEE 123-bus feeder and a synthetic 300-bus distribution system. Results show that the proposed defense strategy restores nearly full service for 90% of top-ranked attacks, mitigates voltage violations, and identifies Feeder 2 as the principal vulnerability corridor. Actionable operating rules are derived, recommending pre-arming of specific tie-lines to enhance resilience, while higher bus system studies confirm scalability of the framework on the IEEE 123-bus and 300-bus systems.

Authors (4)

S Krishna Niketh

Prasanta K Panigrahi

V Vignesh

Mayukha Pal

Submitted

August 30, 2025

arXiv Category

eess.SY

arXiv PDF

Key Contributions

This paper proposes a physics-aware cyberphysical resilience framework for radial microgrids against coordinated cyberattacks. It models attackers using HGNN+MAML for adaptation and defenders using a bi-level Stackelberg game with ADMM and NSGA-II to optimize switching and DER dispatch, ensuring network physics constraints are met.

Business Value

Enhances the security and reliability of critical energy infrastructure, preventing costly outages and ensuring continuous power supply, which is vital for economic stability.

Paper Metadata

Innovation Type

Framework Development

Deployment Feasibility

Moderate to High. Requires integration with existing grid control systems and significant computational resources for real-time optimization.

Limitations Addressed

Lack of integrated frameworks for cyber-physical resilience in microgrids, difficulty in adapting to evolving cyberattack strategies, and ensuring physical constraints are met during defense.

Technical Tags

Cyberphysical SystemsMicrogridsResilienceCyberattacksHypergraph Neural NetworksMeta-LearningBi-level OptimizationStackelberg GameADMMNSGA-IIDistributed Energy ResourcesTie-line Switching

Research Topics

Cybersecurity of Critical InfrastructureResilience EngineeringGame Theory in SecurityMeta-Learning for AdaptationOptimization in Power Systems

Methods & Architectures

Hypergraph Neural Networks (HGNN)Model-Agnostic Meta-Learning (MAML)Bi-level Stackelberg GameAlternating Direction Method of Multipliers (ADMM)Non-dominated Sorting Genetic Algorithm II (NSGA-II) Hypergraph Neural Network

Applications & Tasks

Power Systems Smart Grids Cybersecurity Critical Infrastructure Protection Cyberattack DefenseResilience OptimizationSystem Stability under Attack Resilience RecommendationContingency PredictionOptimal Control

Datasets & Benchmarks

Datasets

IEEE 69-bus distribution test system

Load ServedOperational CostVoltage StabilityResilience

Related Fields

CybersecurityPower Systems EngineeringControl TheoryOperations ResearchMachine Learning

Keywords

MicrogridResilienceCybersecurityCyberattacksHypergraph Neural NetworksMeta-LearningGame TheoryOptimizationPower SystemsSmart GridADMMNSGA-II

Academic Context

#Cybersecurity of Critical Infrastructure#Resilience Engineering#Game Theory in Security#Meta-Learning for Adaptation#Optimization in Power Systems

Technology Stack

Frameworks & Libraries

MAMLADMMNSGA-II

Commercial Potential

Potential Products

Advanced grid security and control softwareReal-time threat detection and response systems for microgrids

Target Industries

EnergyUtilitiesCritical Infrastructure

Use Case Examples

Protecting a university campus microgrid from coordinated cyberattacksEnsuring grid stability during a large-scale cyber incident

Competitive Edge

Offers a more integrated and adaptive approach to microgrid resilience compared to traditional security measures or isolated optimization techniques.

Market Opportunity

Growing market for grid modernization and cybersecurity solutions.

Revenue Models

Software licensingconsulting services for implementation and operation.

Resource Requirements

Compute Needs

High, especially for real-time optimization and meta-learning.

Data Requirements

Detailed network topology, operational data, and simulated attack scenarios.

Deployment Constraints

Integration complexity with existing SCADA systems, real-time processing demands.

Scalability

Scalability to larger, more complex microgrid systems needs further investigation.

Regulatory Considerations

Cybersecurity standards for critical infrastructureGrid operation regulations

Production Readiness

Maturity Level

Research

Time to Market

3-5 years for full integration and validation.

Patent Potential

Moderate, for novel algorithmic combinations and framework design.

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