What question did this study set out to answer?

The aim is to enhance power sharing stability and accuracy in islanded microgrids by addressing control strategy limitations.

April 25, 2026Open Access

Hierarchical Consistency-Based Cooperative Control Strategy Integrating Load-Observation-Based Dynamic Feedforward and Adaptive Particle Swarm Optimization

Puntos clave

The aim is to enhance power sharing stability and accuracy in islanded microgrids by addressing control strategy limitations.
Introduced improved adaptive virtual impedance (IAVI) strategy to stabilize microgrid control.
Implemented load-observation-based dynamic reference feedforward (LODRF) at secondary control for real-time power reconstruction.
Constructed adaptive particle swarm optimization (APSO) for optimizing controller parameters using integral of time-weighted absolute error.
Reduced maximum frequency dynamic deviation by 78.5% and voltage dynamic deviation by 53.3% under load disturbances.
Achieved 0.01 s shorter recovery time for frequency and 0.09 s for voltage with LODRF compared to traditional systems.
APSO-optimized system reduced frequency deviations by 3.1% and voltage deviations by 36.4% against standard PSO.

Resumen

In the parallel operation of islanded microgrids, line impedance mismatches and random load fluctuations, along with the dynamic response lag and difficulty in multidimensional parameter tuning of traditional control strategies, lead to power sharing imbalances and instability in frequency and voltage. To address these issues, this paper proposes a hierarchical cooperative control strategy based on consistency that integrates load-observation-based dynamic reference feedforward (LODRF) and adaptive particle swarm optimization (APSO). First, an improved adaptive virtual impedance (IAVI) strategy based on consistency is introduced into the virtual synchronous generator control framework. Second, an LODRF mechanism is applied at the secondary control layer to actively reconstruct the power baseline by observing the load status at the point of common coupling (PCC) in real time. Furthermore, an APSO algorithm utilizing the integral of time-weighted absolute error (ITAE) as a global performance index is constructed to optimize key proportional–integral controller parameters cooperatively. Simulation results from a four-unit heterogeneous parallel system in MATLAB/Simulink demonstrate that the IAVI strategy enables stable convergence of frequency and voltage and proportional power sharing. Compared with the system without LODRF, the proposed strategy reduces maximum frequency and voltage dynamic deviations under load disturbances by 78.5% and 53.3%, respectively, and shortens effective recovery times by 0.01 s and 0.09 s, respectively. Moreover, compared with the standard PSO algorithm, the APSO-optimized system reduces maximum frequency and voltage deviations by 3.1% and 36.4%, respectively. Additionally, average active and reactive power sharing errors in the steady state are kept below 0.9%, verifying the significant advantages of the strategy in improving dynamic disturbance rejection and steady-state precision.

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