In order to solve the cooperative control problem among multiple distributed units in a distributed DC microgrid, a distributed control based on a consensus algorithm is firstly proposed, which can re...
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To better adapt to the needs of the microgrid, it is considered to apply a distributed control algorithm based on finite time consistency to the hierarchical control of the microgrid. In the traditional microgrid control, to automatically realize the power distribution, the DC voltage control unit often adopts droop control.
Based on the principle of finite time consistency, the secondary control realizes the secondary adjustment of DC microgrid voltage. It avoids the problem that the active output cannot be allocated according to the power mapping factor due to the unbalanced node voltage. The control strategy is formulated as
Due to the diversity of microgrid equipment and the complexity of control optimization objectives, the hierarchical control strategy is generally adopted, to realize the stable parameter recovery and optimal economic operation of AC/DC hybrid microgrid groups [12, 13].
ii. In terms of microgrid intergroup control, the ILC control strategy with the average power mapping factor realizes the economic power distribution among AC/DC hybrid microgrids, and the application of finite-time consistency algorithm further speeds up the convergence of microgrids.
To address the above problems, a novel Narendra-based adaptive anti-disturbance control strategy for microgrid voltage source inverter is proposed in this paper. Firstly, a Narendra
At present, the microgrid mostly adopts the hierarchical control mode, in which the secondary control mainly realizes the accurate tracking of voltage and frequency. The agent consistency control
By leveraging the finite-time consistency algorithm, this strategy facilitates autonomous operation of sub-microgrids and enables mutual aid and assistance within the microgrid cluster. The
The microgrid structure is complex, the operating environment is diverse, and each subsystem is far away from other subsystems. At present, the microgrid mostly adopts the
To better adapt to the needs of the microgrid, it is considered to apply a distributed control algorithm based on finite time consistency to the hierarchical control of the microgrid. In the
To solve the problems of low power distribution efficiency and large voltage deviation of different energy storage units in microgrid hybrid energy storage, this paper proposes a flexible
Microgrids (MGs) play a crucial role in modern power distribution systems, particularly in ensuring reliable and efficient energy supply, integrating renewable energy sources, and enhancing
A distributed optimal control strategy based on finite time consistency is proposed in this paper, to improve the optimal regulation ability of AC/DC hybrid microgrid groups. The control
Simulation and experimental results indicate that utilizing the proposed control strategies, large-capacity HESS has stronger anti-interference ability, shorter regulation time, smaller switching
The improved inverter CP further enhances its anti-interference ability and stability. To simulate complex working conditions, a set of three-phase symmetrical loads was switched on and of
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