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Learning Power Flow with Confidence: A Probabilistic Guarantee Framework for Voltage Risk

Systems and Control 2025-10-16 v3 Machine Learning Systems and Control

Abstract

The absence of formal performance guarantees in machine learning (ML) has limited its adoption for safety-critical power system applications, where confidence and interpretability are as vital as accuracy. In this work, we present a probabilistic guarantee for power flow learning and voltage risk estimation, derived through the framework of Gaussian Process (GP) regression. Specifically, we establish a bound on the expected estimation error that connects the GP's predictive variance to confidence in voltage risk estimates, ensuring statistical equivalence with Monte Carlo-based ACPF risk quantification. To enhance model learnability in the low-data regime, we first design the Vertex-Degree Kernel (VDK), a topology-aware additive kernel that decomposes voltage-load interactions into local neighborhoods for efficient large-scale learning. Building on this, we introduce a network-swipe active learning (AL) algorithm that adaptively samples informative operating points and provides a principled stopping criterion without requiring out-of-sample validation. Together, these developments mitigate the principal bottleneck of ML-based power flow-its lack of guaranteed reliability-by combining data efficiency with analytical assurance. Empirical evaluations across IEEE 118-, 500-, and 1354-bus systems confirm that the proposed VDK-GP achieves mean absolute voltage errors below 1E-03 p.u., reproduces Monte Carlo-level voltage risk estimates with 15x fewer ACPF computations, and achieves over 120x reduction in evaluation time while conservatively bounding violation probabilities.

Keywords

Cite

@article{arxiv.2308.07867,
  title  = {Learning Power Flow with Confidence: A Probabilistic Guarantee Framework for Voltage Risk},
  author = {Parikshit Pareek and Sidhant Misra and Deepjyoti Deka},
  journal= {arXiv preprint arXiv:2308.07867},
  year   = {2025}
}

Comments

10 pages

R2 v1 2026-06-28T11:56:12.160Z