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Design Optimization for Weighted Conduction Loss Minimization in a Dual-Active-Bridge-Based PV Microinverter

Michael D’Antonio, Shiladri Chakraborty, Alireza Khaligh

202017 citationsDOIOpen Access PDF

Abstract

This manuscript presents a harmonic-superposition-based frequency-domain approach for analysis and optimal design of a single-stage DAB-based DC-AC converter used in low-voltage DC to high voltage AC applications, such as PV microinverter. Specifically, two topological variations and correspondingly different modulation strategies involving up to four control variables (three phase shifts and switching frequency) are analyzed. Optimal trajectories of control variables are determined that result in minimized transformer RMS current at a given average power, while enforcing near-uniform ZVS. To make the design process holistic, an outer optimization loop is used to determine optimal values for the power transfer inductance (integrated as the transformer's leakage inductance) and turns ratio, which minimize the weighted-average conduction loss contribution to the microinverter's CEC efficiency. Based on the optimization analyses, a 400 W microinverter prototype is built and experimental results at one operating point are presented, achieving a measured efficiency of 92.8%.

Topics & Concepts

Solar micro-inverterInductanceLeakage inductanceTransformerOperating pointControl theory (sociology)VoltageSuperposition principleElectronic engineeringTopology (electrical circuits)Computer scienceEngineeringElectrical engineeringMathematicsMaximum power point trackingInverterArtificial intelligenceMathematical analysisControl (management)Advanced DC-DC ConvertersMultilevel Inverters and ConvertersSilicon Carbide Semiconductor Technologies
Design Optimization for Weighted Conduction Loss Minimization in a Dual-Active-Bridge-Based PV Microinverter | Litcius