English

Kernel-Based Learning for Smart Inverter Control

Optimization and Control 2018-07-11 v1 Artificial Intelligence Machine Learning Systems and Control Machine Learning

Abstract

Distribution grids are currently challenged by frequent voltage excursions induced by intermittent solar generation. Smart inverters have been advocated as a fast-responding means to regulate voltage and minimize ohmic losses. Since optimal inverter coordination may be computationally challenging and preset local control rules are subpar, the approach of customized control rules designed in a quasi-static fashion features as a golden middle. Departing from affine control rules, this work puts forth non-linear inverter control policies. Drawing analogies to multi-task learning, reactive control is posed as a kernel-based regression task. Leveraging a linearized grid model and given anticipated data scenarios, inverter rules are jointly designed at the feeder level to minimize a convex combination of voltage deviations and ohmic losses via a linearly-constrained quadratic program. Numerical tests using real-world data on a benchmark feeder demonstrate that nonlinear control rules driven also by a few non-local readings can attain near-optimal performance.

Keywords

Cite

@article{arxiv.1807.03769,
  title  = {Kernel-Based Learning for Smart Inverter Control},
  author = {Aditie Garg and Mana Jalali and Vassilis Kekatos and Nikolaos Gatsis},
  journal= {arXiv preprint arXiv:1807.03769},
  year   = {2018}
}

Comments

Submitted to the 2018 IEEE Global Signal and Information Processing Conf., Symposium on Smart Energy Infrastructures

R2 v1 2026-06-23T02:56:44.253Z