A Quadratic high-step-up DC–DC converter architecture for renewable-energy applications

Thai Anh Au Tran; Xuan Khanh Ho; Duong Thach Pham; Thi Ngoc Anh Le; Kim Ánh Nguyễn

Authors

Thai Anh Au Tran University of Danang - University of Science and Technology
Xuan Khanh Ho University of Danang - University of Science and Technology
Duong Thach Pham University of Danang - University of Science and Technology
Thi Ngoc Anh Le University of Danang - University of Science and Technology
Kim Ánh Nguyễn 1

Keywords:

High step–up, Quadratic boost, Continuous input current, Low component count, Renewable energy

Abstract

This paper presents a new quadratic high step-up DC–DC converter featuring a high voltage-gain capability and an optimized component count, suitable for renewable-energy applications. Conventional boost converters achieve high gain only when the duty ratio approaches unity, which results in large conduction losses and reduced efficiency. Existing coupled-inductor solutions often suffer from high input-current ripple and severe voltage spikes, while switched-capacitor or switched-inductor structures require multiple stages, increasing cost and reducing efficiency. The proposed converter addresses these limitations by implementing a quadratic voltage-boost mechanism within a simple topology. It achieves an output voltage 10–13 times higher than the input at a moderate duty ratio of 0.60–0.65, while maintaining continuous input current with low ripple. The operating principles, voltage-gain characteristics, device voltage stresses, and loss mechanisms are analyzed in detail. Simulation results and comparisons with previously published converters confirm that the proposed design offers higher efficiency, reduced device stress, and fewer components, demonstrating its strong potential for practical deployment.

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Author Biography

Kim Ánh Nguyễn, 1

Engineer of Electrical Engineering with a specialization in Automation, The University of Danang - University of Science and Technology, 2004;
Master of Automation Engineering, The University of Danang, 2009;
Master of Industrial Systems Engineering, University of Technology of Troyes, France, 2012;
D. of Systems Optimization and Dependability (graduated in 2012) at Laboratory of Systems Modeling and Dependability (LM2S), Charles Delaunay Institute, University of Technology of Troyes, France, 2015;
Head of the Department of Automation, Faculty of Electrical Engineering, The University of Danang - University of Science and Technology, 2016–2020;
Currently a Lecturer in Control Engineering, Automation, and Electrical Engineering, Faculty of Electrical Engineering, The University of Danang - University of Science and Technology.