Resilient Controller Design with Exponential Reaching Law for Enhanced Load Frequency Stability in Multi-Area Interconnected Microgrids

TL;DR

This paper introduces a robust decentralized control method using exponential reaching law and sliding mode control to improve load frequency stability in interconnected microgrids with renewable energy uncertainties.

Contribution

It develops a novel global integral terminal sliding mode control with exponential reaching law for multi-area microgrids, enhancing dynamic performance and robustness against uncertainties.

Findings

94.9% improvement in ITSE

94.4% improvement in ISE

Superior accuracy and dynamic performance

Abstract

We present a load frequency control strategy deploying a decentralized robust global integral terminal sliding mode control (GITSMC) method to maintain stable frequency and tie-line power in multi-area interconnected microgrids with aggregated uncertainties. To achieve this, firstly, we have developed a mathematical model of the multi-area interconnected system incorporating disturbances from solar photovoltaic (PV), wind turbine (WT) generation and load demand, as aggregated uncertainties. Secondly, we have designed a global integral terminal sliding surface with an exponential reaching law for each area to enhance system dynamic performance and suppress chattering within a finite time. Thirdly, the overall stability of the closed-loop system is analyzed using the Lyapunov stability theorem. Finally, extensive simulations are conducted on the IEEE 10-generator New England 39-bus power system, including load disturbances and variable PV and WT generation. The results demonstrate the performance of the proposed GITSMC approach, achieving approximately 94.9% improvement in ITSE and 94.4% improvement in ISE, confirming its superior accuracy and dynamic performance compared to the existing controller.