Self-Supervised T-GCN for Detection of Disturbance and Propagation in Power Grid

Haoran Niu; Yang Chen; Moumita Samanta; Olufemi A. Omitaomu

doi:10.1145/3764926.3771948

Self-Supervised T-GCN for Detection of Disturbance and Propagation in Power Grid

Computational Urban Sciences

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Urban power systems increasingly rely on dense sensing to monitor grid reliability, yet disturbance labels are scarce and events are rare. We present a self-supervised spatio-temporal method that detects, localizes, and characterizes grid frequency disturbances across urban areas using only unlabeled data. Our approach trains a tiny Temporal Graph Convolutional Network (T-GCN) to forecast per-site frequency residuals (deviation from 60 Hz). The sensor graph is constructed directly from signals using pre-event Pearson correlation with a cross-correlation lag penalty without geocoding. At inference, node-level anomalies are the model's forecast errors; region-level alarms arise from connected components of high-score nodes. We estimate disturbance propagation by computing per-node arrival times (first persistent exceedance), then fit a planar or time-of-arrival model to obtain direction, speed, and an epicenter proxy. With only three real events collected at decisecond resolution across U.S. cities, we evaluate the T-GCN and report time-to-detect, footprint size, and propagation consistency. We further show that short-window embeddings from the T-GCN's hidden states enable few-shot event-vs-background recognition via a simple prototypical classifier. Despite minimal data and no labels, our system yields fast, spatially coherent detection and interpretable propagation maps, offering a practical, lightweight pathway to city-scale grid resilience analytics.

Original language	English
Title of host publication	URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI
Editors	Haoran Niu, Hao Xue, Liang Zhao, Femi Omitaomu
Publisher	Association for Computing Machinery, Inc
Pages	59-67
Number of pages	9
ISBN (Electronic)	9798400721892
DOIs	https://doi.org/10.1145/3764926.3771948
State	Published - Dec 2 2025
Event	3rd ACM SIGSPATIAL International Workshop on Advances in Urban AI, UrbanAI 2025 - Minneapolis, United States Duration: Nov 3 2025 → Nov 6 2025

Publication series

Name	URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI

Conference

Conference	3rd ACM SIGSPATIAL International Workshop on Advances in Urban AI, UrbanAI 2025
Country/Territory	United States
City	Minneapolis
Period	11/3/25 → 11/6/25

Funding

We thank the anonymous reviewers for their constructive feedback and appreciate the open-source community for libraries used in this work. We also thank Dr. Vladimir Protopopescu, Chief Scientist of Computational Sciences and Engineering Division, Oak Ridge National Laboratory, for his insightful comments and guidance that helped improve the clarity and technical rigor of this paper.

Keywords

Graph neural networks
propagation modeling
smart grid
spatio-temporal anomaly detection
urban sensing

Access to Document

10.1145/3764926.3771948

Cite this

Niu, H., Chen, Y., Samanta, M., & Omitaomu, O. A. (2025). Self-Supervised T-GCN for Detection of Disturbance and Propagation in Power Grid. In H. Niu, H. Xue, L. Zhao, & F. Omitaomu (Eds.), URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI (pp. 59-67). (URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI). Association for Computing Machinery, Inc. https://doi.org/10.1145/3764926.3771948

Niu, Haoran ; Chen, Yang ; Samanta, Moumita et al. / Self-Supervised T-GCN for Detection of Disturbance and Propagation in Power Grid. URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI. editor / Haoran Niu ; Hao Xue ; Liang Zhao ; Femi Omitaomu. Association for Computing Machinery, Inc, 2025. pp. 59-67 (URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI).

@inproceedings{269944c2721b48f88d444a7a5de63387,

title = "Self-Supervised T-GCN for Detection of Disturbance and Propagation in Power Grid",

abstract = "Urban power systems increasingly rely on dense sensing to monitor grid reliability, yet disturbance labels are scarce and events are rare. We present a self-supervised spatio-temporal method that detects, localizes, and characterizes grid frequency disturbances across urban areas using only unlabeled data. Our approach trains a tiny Temporal Graph Convolutional Network (T-GCN) to forecast per-site frequency residuals (deviation from 60 Hz). The sensor graph is constructed directly from signals using pre-event Pearson correlation with a cross-correlation lag penalty without geocoding. At inference, node-level anomalies are the model's forecast errors; region-level alarms arise from connected components of high-score nodes. We estimate disturbance propagation by computing per-node arrival times (first persistent exceedance), then fit a planar or time-of-arrival model to obtain direction, speed, and an epicenter proxy. With only three real events collected at decisecond resolution across U.S. cities, we evaluate the T-GCN and report time-to-detect, footprint size, and propagation consistency. We further show that short-window embeddings from the T-GCN's hidden states enable few-shot event-vs-background recognition via a simple prototypical classifier. Despite minimal data and no labels, our system yields fast, spatially coherent detection and interpretable propagation maps, offering a practical, lightweight pathway to city-scale grid resilience analytics.",

keywords = "Graph neural networks, propagation modeling, smart grid, spatio-temporal anomaly detection, urban sensing",

author = "Haoran Niu and Yang Chen and Moumita Samanta and Omitaomu, \{Olufemi A.\}",

note = "Publisher Copyright: {\textcopyright} 2025 Copyright held by the owner/author(s).; 3rd ACM SIGSPATIAL International Workshop on Advances in Urban AI, UrbanAI 2025 ; Conference date: 03-11-2025 Through 06-11-2025",

year = "2025",

month = dec,

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doi = "10.1145/3764926.3771948",

language = "English",

series = "URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI",

publisher = "Association for Computing Machinery, Inc",

pages = "59--67",

editor = "Haoran Niu and Hao Xue and Liang Zhao and Femi Omitaomu",

booktitle = "URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI",

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Niu, H , Chen, Y, Samanta, M & Omitaomu, OA 2025, Self-Supervised T-GCN for Detection of Disturbance and Propagation in Power Grid. in H Niu, H Xue, L Zhao & F Omitaomu (eds), URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI. URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI, Association for Computing Machinery, Inc, pp. 59-67, 3rd ACM SIGSPATIAL International Workshop on Advances in Urban AI, UrbanAI 2025, Minneapolis, United States, 11/3/25. https://doi.org/10.1145/3764926.3771948

Self-Supervised T-GCN for Detection of Disturbance and Propagation in Power Grid. / Niu, Haoran ; Chen, Yang; Samanta, Moumita et al.
URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI. ed. / Haoran Niu; Hao Xue; Liang Zhao; Femi Omitaomu. Association for Computing Machinery, Inc, 2025. p. 59-67 (URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Self-Supervised T-GCN for Detection of Disturbance and Propagation in Power Grid

AU - Niu, Haoran

AU - Chen, Yang

AU - Samanta, Moumita

AU - Omitaomu, Olufemi A.

PY - 2025/12/2

Y1 - 2025/12/2

N2 - Urban power systems increasingly rely on dense sensing to monitor grid reliability, yet disturbance labels are scarce and events are rare. We present a self-supervised spatio-temporal method that detects, localizes, and characterizes grid frequency disturbances across urban areas using only unlabeled data. Our approach trains a tiny Temporal Graph Convolutional Network (T-GCN) to forecast per-site frequency residuals (deviation from 60 Hz). The sensor graph is constructed directly from signals using pre-event Pearson correlation with a cross-correlation lag penalty without geocoding. At inference, node-level anomalies are the model's forecast errors; region-level alarms arise from connected components of high-score nodes. We estimate disturbance propagation by computing per-node arrival times (first persistent exceedance), then fit a planar or time-of-arrival model to obtain direction, speed, and an epicenter proxy. With only three real events collected at decisecond resolution across U.S. cities, we evaluate the T-GCN and report time-to-detect, footprint size, and propagation consistency. We further show that short-window embeddings from the T-GCN's hidden states enable few-shot event-vs-background recognition via a simple prototypical classifier. Despite minimal data and no labels, our system yields fast, spatially coherent detection and interpretable propagation maps, offering a practical, lightweight pathway to city-scale grid resilience analytics.

AB - Urban power systems increasingly rely on dense sensing to monitor grid reliability, yet disturbance labels are scarce and events are rare. We present a self-supervised spatio-temporal method that detects, localizes, and characterizes grid frequency disturbances across urban areas using only unlabeled data. Our approach trains a tiny Temporal Graph Convolutional Network (T-GCN) to forecast per-site frequency residuals (deviation from 60 Hz). The sensor graph is constructed directly from signals using pre-event Pearson correlation with a cross-correlation lag penalty without geocoding. At inference, node-level anomalies are the model's forecast errors; region-level alarms arise from connected components of high-score nodes. We estimate disturbance propagation by computing per-node arrival times (first persistent exceedance), then fit a planar or time-of-arrival model to obtain direction, speed, and an epicenter proxy. With only three real events collected at decisecond resolution across U.S. cities, we evaluate the T-GCN and report time-to-detect, footprint size, and propagation consistency. We further show that short-window embeddings from the T-GCN's hidden states enable few-shot event-vs-background recognition via a simple prototypical classifier. Despite minimal data and no labels, our system yields fast, spatially coherent detection and interpretable propagation maps, offering a practical, lightweight pathway to city-scale grid resilience analytics.

KW - Graph neural networks

KW - propagation modeling

KW - smart grid

KW - spatio-temporal anomaly detection

KW - urban sensing

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U2 - 10.1145/3764926.3771948

DO - 10.1145/3764926.3771948

M3 - Conference contribution

AN - SCOPUS:105026298719

T3 - URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI

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BT - URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI

A2 - Niu, Haoran

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A2 - Omitaomu, Femi

PB - Association for Computing Machinery, Inc

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Y2 - 3 November 2025 through 6 November 2025

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Niu H , Chen Y, Samanta M, Omitaomu OA. Self-Supervised T-GCN for Detection of Disturbance and Propagation in Power Grid. In Niu H, Xue H, Zhao L, Omitaomu F, editors, URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI. Association for Computing Machinery, Inc. 2025. p. 59-67. (URBANAI 2025 - Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Advances in UrbanAI). doi: 10.1145/3764926.3771948

Self-Supervised T-GCN for Detection of Disturbance and Propagation in Power Grid

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