Performance metrics for droop-controlled microgrids with variable voltage dynamics

TL;DR

This paper analyzes how droop-controlled microgrids with variable voltages experience power losses during synchronization, revealing that network connectivity influences voltage-related losses and convergence rates.

Contribution

It introduces a novel input-output H2 norm framework to quantify transient power losses in droop-controlled microgrids with variable voltages and frequencies.

Findings

Losses scale with network size but weakly depend on connectivity.

Voltage control losses are higher in highly connected networks.

Higher connectivity leads to faster convergence but increased power losses.

Abstract

This paper investigates the performance of a microgrid with droop-controlled inverters in terms of the total power losses incurred in maintaining synchrony under persistent small disturbances. The inverters are modeled with variable frequencies and voltages under droop control. For small fluctuations from a steady state, these transient power losses can be quantified by an input-output H2 norm of a linear system subject to distributed disturbances. We evaluate this H2 norm under the assumption of a dominantly inductive network with identical inverters. The results indicate that while phase synchronization, in accordance with previous findings, produces losses that scale with a network's size but only weakly depend on its connectivity, the losses associated with the voltage control will be larger in a highly connected network than in a loosely connected one. The typically higher rate of convergence in a highly interconnected network thus comes at a cost of higher losses associated with the power flows used to reach the steady state.