Optimal Singular Perturbation-based Model Reduction for Heterogeneous Power Systems

TL;DR

This paper introduces two novel singular perturbation methods for optimal model reduction in complex, heterogeneous power systems, avoiding prior assumptions about system states and improving computational efficiency.

Contribution

It proposes two new singular perturbation techniques that identify fast states for reduction without prior physical knowledge, enhancing model simplification for modern power systems.

Findings

Methods accurately reduce models of complex power systems.

Approaches are generalizable to heterogeneous system components.

Numerical results demonstrate improved efficiency and accuracy.

Abstract

Power systems are globally experiencing an unprecedented growth in size and complexity due to the advent of nonconventional generation and consumption technologies. To navigate computational complexity, power system dynamic models are often reduced using techniques based on singular perturbation. However, several technical assumptions enabling traditional approaches are being challenged due to the heterogeneous, and often black-box, nature of modern power system component models. This work proposes two singular perturbation approaches that aim to optimally identify fast states that shall be reduced, without prior knowledge about the physical meaning of system states. After presenting a timescale-agnostic formulation for singular perturbation, the first approach uses greedy optimization to sequentially select states to be reduced. The second approach relies on a nonlinear optimization routine allowing state transformations while obtaining an optimally reduced model. Numerical studies on a test system featuring synchronous machines, inverters, and line dynamics demonstrate the generalizability and accuracy of the developed approaches.