Multilayer GNN for predictive maintenance and clustering in power grids.
Muhammad Kazim, Harun Pirim, Chau Le, Trung Le, Om Prakash Yadav
Abstract
Open AccessUnplanned power outages create major economic costs. To better predict and manage these events, we present a multilayer graph neural network (GNN) framework that captures spatial, short-term co-occurrence, and statistically enriched co-failure patterns using 7 years of Oklahoma Gas & Electric data from 347 substations. These relations are encoded with weighted graph convolutions and fused by attention into a unified representation. For predictive maintenance, the model flags substations requiring near-term intervention across 30-, 60-, and 180-day horizons, achieving a peak 30-day F1 score of 0.8935. The same representation supports resilience planning by clustering substations into eight risk groups, each with distinct incident rates and recovery times. The highest-risk group has over six times higher incident rates than the low-risk groups. Combining prediction and clustering in a single framework provides utilities with an integrated basis for scheduling maintenance, prioritizing inspections, and targeting grid-hardening investments to minimize outage impacts and enhance reliability.