Abstract
Modular multilevel converters (MMCs), with their inherent features and advantages over other conventional converters, have gained popularity and remain an ongoing topic of research. Many scholars have solved issues related to the operation, control, protection, and reliability of MMCs using simulation software and small hardware prototypes. We propose a novel approach for an MMC controller design with real-time systems. By utilizing a key benefit of LabVIEW Multisim co-simulation, an MMC control algorithm that can be deployed on a field-programmable gate array (FPGA) was developed in LabVIEW. The complete circuit was designed in Multisim, and a co-simulation was performed to drive an MMC model. The benefit of this topology is that control algorithms can be designed in a LabVIEW FPGA and tested with the Multisim co-simulation circuit to obtain simulation results. Once the controller works and provides satisfactory results, the same algorithm can be deployed in any NI (National Instruments) FPGA-based controller, like a compact remote input/output (RIO), to control real-time MMCs designed in an NI PCI eXtensions for Instrumentation (PXI) system. This method saves time and provides flexibility for effectively designing control algorithms and implementing them in an FPGA for real-time model implementation.
Highlights
With increasing global warming, renewable energy sources are being used to generate power.Offshore wind turbines, because of the more linear wind velocity profile, are an example of a renewable energy source; they are located far away from load centers [1]
Simulation and allows the same program to be used for the control of the real-time Modular multilevel converters (MMCs) system system implemented in a National Instruments (NI) PCI eXtensions for Instrumentation (PXI)
A nearest level control (NLC) algorithm was developed in LabVIEW to control the MMC operation and was compatible for deployment in real-time NI controllers (i.e., compact reconfigurable input/output)
Summary
Renewable energy sources are being used to generate power. In steady and dynamic conditions while maintaining MMC currents and voltages by controlling Several researchers have developed small prototypes to verify their control algorithms. There is a need for a platform designed once and can be utilized for simulation and real-time implementation, saving time where control algorithms are designed once and can be utilized for simulation and real-time during the development and testing of the system. This study presents a development platform using a LabVIEW Multisim co-simulation 1) that can develop control algorithms in a graphical-language-based LabVIEW platform for MMC simulation and allows the same program to be used for the control of the real-time MMC simulation and allows the same program to be used for the control of the real-time MMC system system implemented in a National Instruments (NI) PCI eXtensions for Instrumentation (PXI).
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