基于高阶滑模观测器的直流微电网积分滑模MPPT控制的设计与实时验证

IF 2.1 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE IEEE Canadian Journal of Electrical and Computer Engineering Pub Date : 2022-12-13 DOI:10.1109/ICJECE.2022.3211470
Vijaya Kumar Dunna;Kumar Pakki Bharani Chandra;Pravat Kumar Rout;Binod Kumar Sahu
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引用次数: 1

摘要

在基于微电网的光伏系统中,最大功率点跟踪(MPPT)控制对提高效率和稳定性起着至关重要的作用。近年来,基于观测器的MPPT控制是提高微电网有效性的关键控制方案之一。本文提出了一种基于高阶滑模观测器(HOSMO)的积分滑模控制(ISMC),用于MPPT控制,以确保闭环直流微电网的有效运行。所提出的MPPT控制主要集中在从基于光伏系统的微电网获得无颤振的输出电压和稳定的输出功率,并进一步确保对不确定性的不敏感性和稳态误差的减少。ISMC用于在系统的整个响应过程中进行有限时间稳定。为了证明所提出方法的有效性,实时模拟了各种测试场景,并通过广泛的比较结果对其性能进行了研究。将MATLAB仿真与OPAL-RT实时仿真结果进行了比较。在不同的气象条件下,观察到所提出的方法在高效率、良好的精度和鲁棒性方面的优越性能。
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Design and Real-Time Validation of Higher Order Sliding Mode Observer-Based Integral Sliding Mode MPPT Control for a DC Microgrid
In a photovoltaic (PV) system-based microgrid, maximum power point tracking (MPPT) control plays a crucial role to improve the efficiency and stability. Since the past few years, one of the key control schemes to enhance the effectiveness of the microgrid is the observer-based MPPT control. This article proposes a higher order sliding mode observer (HOSMO)-based integral sliding mode control (ISMC) for MPPT control to ensure an efficient operation of a closed-loop dc microgrid. The proposed MPPT control is mainly focused on obtaining a chatter-free output voltage and stabilized output power from the PV-system-based microgrid and further ensure insensitivity to uncertainties and reduction in steady-state error. ISMC is applied to carry out finite-time stabilization throughout the entire response of the system. To justify the efficacy of the proposed approach, various test scenarios are simulated in real-time, and the performance is investigated through extensive comparative results. The MATLAB simulations and real-time simulation results achieved with OPAL-RT are compared. The superior performance of the proposed approach is observed in terms of high efficiency, good accuracy, and robust performance under varying meteorological conditions.
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