基于Mittag - Leffler多项式的神经网络控制UPQC性能分析

2022 IEEE 2nd International Symposium on Sustainable Energy, Signal Processing and Cyber Security (iSSSC) Pub Date : 2022-12-15 DOI:10.1109/iSSSC56467.2022.10051471

K. B. Rai, Narendra Kumar, Alka Singh

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引用次数: 1

摘要

本文研究了由并联和串联电压源变换器组成的统一电能质量调节器(UPQC)在电压跌落、电压膨胀和负载不平衡情况下的性能。UPQC集成了25kw额定功率的光伏(PV)电源。采用混合控制技术对UPQC进行控制。采用基于Mittag - Leffler多项式的神经网络(MiLeP)控制产生并联VSC的开关信号，采用MiLeP滤波控制产生串联VSC的门控信号。并联补偿器的开发是为了缓解与电流相关的PQ问题，而串联补偿器的开发是为了缓解与电压相关的PQ问题。源电流的THD低于5%，低于IEEE-1547规范。在电压下降和电压上升的情况下，负载电压都保持在预下降和预膨胀状态。在MATLAB Simulink中进行了仿真，并用所提出的控制算法对仿真结果进行了验证。结果表明，在稳态和动态运行下，PV- UPQC的性能都有所提高。

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Performance Analysis of UPQC using Mittag Leffler Polynomial based Neural Network Control

This paper investigates the performance of Unified Power Quality Conditioner (UPQC), which comprises of shunt and series voltage source converter (VSC) under voltage Sag, voltage swell, and load unbalancing. UPQC is integrated with 25 kW power rated Photo Voltaic (PV) source. A hybrid control technique is executed for UPQC. The Mittag Leffler Polynomial based Neural Network (MiLeP) control is executed for the generation of switching signals to shunt VSC and ‘d-q' with MiLeP filter control for the generation of gating signals to series VSC. The shunt compensator is developed to mitigate current related Power Quality (PQ) issues, and the series compensator is developed to alleviate voltage related PQ issues. The THD of the source current is below 5% which is under the IEEE-1547 norms. The load voltage is maintained at pre-sag and pre-swell conditions under both Voltage Sag and Voltage swell. In MATLAB Simulink, the simulation is executed and the results are examined with the proposed control algorithm. The results show improved performance of PV- UPQC under both steady-state and dynamic operation.

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来源期刊

2022 IEEE 2nd International Symposium on Sustainable Energy, Signal Processing and Cyber Security (iSSSC)

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