Delay-Robust Secondary Frequency Control via Passive Interconnection and Randomized Block Updates

TL;DR

This paper presents a delay-robust, passivity-based secondary frequency control framework for transmission networks that incorporates randomized updates and interface filtering to handle communication delays and computational constraints.

Contribution

It introduces a passivity-based control scheme with randomized block-coordinate updates and a wave-domain interface filter to enhance delay robustness and computational efficiency.

Findings

The proposed control preserves the target equilibrium despite delays.

Randomized updates achieve local mean-square geometric convergence.

Simulations demonstrate accurate behavior reproduction and reduced computational cost.

Abstract

This paper studies secondary frequency control in transmission networks subject to communication delays at the cyber-physical interface and limited per-update computation at the control center. The regulation objective is formulated as a constrained economic dispatch problem incorporating generation capacity constraints, nodal power balance, transmission-flow limits, and scheduled tie-line power exchanges. Based on this formulation, we develop a passivity-based control framework in which an augmented projected primal-dual controller restores nominal frequency and drives the closed-loop system to the solution set of the constrained economic dispatch problem. Two-way communication delays between the physical network and the control center are modeled as scattering-based passive channels for the measurement uplink and the control-command downlink. This construction preserves the target equilibrium and enables a delay-robust passivity analysis of the delayed closed loop. To reduce the computational burden at the control center, we develop a randomized block-coordinate implementation of the augmented projected primal-dual controller. The resulting sampled-data closed loop preserves the target solution set and achieves local mean-square geometric convergence under suitable step-size and regularity conditions. Finally, a multivariable wave-domain interface filter is introduced to inject additional dissipation and improve the damping of the delayed interface without altering the steady-state interconnection. Simulations on the IEEE 14-bus system indicate that the proposed digital implementation accurately reproduces the delayed closed-loop behavior while reducing the per-update computational cost.