A Composite Control Strategy for Buck Converter Based on LESO and MPC

ABSTRACT For buck converters operating under variable load conditions, fast transient response characteristics and strong interference immunity are critical factors ensuring stable and reliable operation. To address the issues of response lag and insufficient interference immunity during load transients, this paper proposes a robust cascaded control scheme combining discrete‐time model predictive control (MPC) with an improved linear active disturbance rejection control (LADRC). To overcome the inherent bandwidth limitations and phase lag of conventional linear extended state observer (LESO), a differential feedforward path is introduced into the traditional LESO architecture. The improved LESO achieves faster load disturbance estimation while maintaining robust noise immunity. An efficient two‐step predictive MPC algorithm is employed in the inner loop to eliminate computational delays and ensure rapid current tracking. Rigorous discrete‐time stability analysis based on the Jury criterion and Lyapunov theory provides a theoretical foundation for parameter design. Experimental results validate that the proposed method significantly reduces voltage recovery time and overshoot under load transients, demonstrating superior robustness.