核心概念
A novel control strategy for grid-connected modular multilevel converters (GC-MMCs) using a Fractional Order Fuzzy Type-II PI (FOFPI) controller optimized by the Whale Optimization Algorithm (WOA) to achieve improved performance and robustness under various operating conditions.
要約
This paper proposes a novel control strategy for grid-connected modular multilevel converters (GC-MMCs) using a Fractional Order Fuzzy Type-II PI (FOFPI) controller. The key highlights are:
- Design of a Fractional Order Proportional-Integral (FOPI) current controller to control GC-MMCs under unbalanced voltage conditions and model uncertainties.
- Development of a Type-II FOFPI current controller to further improve the control performance of GC-MMCs. The FOFPI controller utilizes a type-II Fuzzy Inference System (FIS) to adaptively adjust the proportional and integral gains during the control process, enabling effective control under diverse operating conditions.
- Optimization of the controller parameters, including the gains of proportional and integral terms, the order of integral in the FOPI controller, and the parameters of membership functions in the FOFPI controller, using the Whale Optimization Algorithm (WOA).
- Simulation study to validate the effectiveness of the proposed control strategy under normal and unbalanced fault conditions, demonstrating the potential of the recommended control strategy for GC-MMCs.
The results show that the FOFPI controller outperforms the FOPI controller, achieving a smoother output line-line voltage with reduced ripple and total harmonic distortion (THD). The FOFPI controller's adaptability to changing gains in response to faults and varying operating conditions enables it to surpass the FOPI controller's performance, ensuring system stability across different operating conditions, even in the presence of uncertainties and faults.
統計
The THD of the output voltage using the FOPI controller is 0.33 at 400 volts input and 0.31 at 500 volts input.
The THD of the output voltage using the FOFPI controller is 0.28 at 400 volts input and 0.26 at 500 volts input.
引用
"The FOFPI controller's adaptability to changing gains in response to faults and varying operating conditions enables it to surpass the FOPI controller's performance, ensuring system stability across different operating conditions, even in the presence of uncertainties and faults."
"The results show that the FOFPI controller outperforms the FOPI controller, achieving a smoother output line-line voltage with reduced ripple and total harmonic distortion (THD)."