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Main Authors: Haider, Mohammad Zakaria, Podder, Amit Kumar, Mali, Prabin, Chakrabortty, Aranya, Paudyal, Sumit, Rahman, Mohammad Ashiqur
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.22381
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author Haider, Mohammad Zakaria
Podder, Amit Kumar
Mali, Prabin
Chakrabortty, Aranya
Paudyal, Sumit
Rahman, Mohammad Ashiqur
author_facet Haider, Mohammad Zakaria
Podder, Amit Kumar
Mali, Prabin
Chakrabortty, Aranya
Paudyal, Sumit
Rahman, Mohammad Ashiqur
contents The rapid deployment of electric vehicle charging stations (EVCS) within distribution networks necessitates intelligent and adaptive control to maintain the grid's resilience and reliability. In this work, we propose PHANTOM, a physics-aware adversarial network that is trained and optimized through a multi-agent reinforcement learning model. PHANTOM integrates a physics-informed neural network (PINN) enabled by federated learning (FL) that functions as a digital twin of EVCS-integrated systems, ensuring physically consistent modeling of operational dynamics and constraints. Building on this digital twin, we construct a multi-agent RL environment that utilizes deep Q-networks (DQN) and soft actor-critic (SAC) methods to derive adversarial false data injection (FDI) strategies capable of bypassing conventional detection mechanisms. To examine the broader grid-level consequences, a transmission and distribution (T and D) dual simulation platform is developed, allowing us to capture cascading interactions between EVCS disturbances at the distribution level and the operations of the bulk transmission system. Results demonstrate how learned attack policies disrupt load balancing and induce voltage instabilities that propagate across T and D boundaries. These findings highlight the critical need for physics-aware cybersecurity to ensure the resilience of large-scale vehicle-grid integration.
format Preprint
id arxiv_https___arxiv_org_abs_2512_22381
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle PHANTOM: Physics-Aware Adversarial Attacks against Federated Learning-Coordinated EV Charging Management System
Haider, Mohammad Zakaria
Podder, Amit Kumar
Mali, Prabin
Chakrabortty, Aranya
Paudyal, Sumit
Rahman, Mohammad Ashiqur
Emerging Technologies
Machine Learning
The rapid deployment of electric vehicle charging stations (EVCS) within distribution networks necessitates intelligent and adaptive control to maintain the grid's resilience and reliability. In this work, we propose PHANTOM, a physics-aware adversarial network that is trained and optimized through a multi-agent reinforcement learning model. PHANTOM integrates a physics-informed neural network (PINN) enabled by federated learning (FL) that functions as a digital twin of EVCS-integrated systems, ensuring physically consistent modeling of operational dynamics and constraints. Building on this digital twin, we construct a multi-agent RL environment that utilizes deep Q-networks (DQN) and soft actor-critic (SAC) methods to derive adversarial false data injection (FDI) strategies capable of bypassing conventional detection mechanisms. To examine the broader grid-level consequences, a transmission and distribution (T and D) dual simulation platform is developed, allowing us to capture cascading interactions between EVCS disturbances at the distribution level and the operations of the bulk transmission system. Results demonstrate how learned attack policies disrupt load balancing and induce voltage instabilities that propagate across T and D boundaries. These findings highlight the critical need for physics-aware cybersecurity to ensure the resilience of large-scale vehicle-grid integration.
title PHANTOM: Physics-Aware Adversarial Attacks against Federated Learning-Coordinated EV Charging Management System
topic Emerging Technologies
Machine Learning
url https://arxiv.org/abs/2512.22381