Faculty Publications

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Author: search.filters.author.Diwakar Naik, M.Subject: search.filters.subject.Solar photovoltaics

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    A Novel Single-Switch High-Gain DC-DC Converter With Active Switched Inductor
    (Institute of Electrical and Electronics Engineers Inc., 2024) Diwakar Naik, M.; Vinatha Urundady, U.
    This brief presents a non-isolated, novel single-switch high-gain DC-DC converter with an active switched inductor (NSSHG-ASI) designed for fuel-cell and photovoltaic (PV) powered systems. It features a quadratic boost converter structure at the front end, followed by an active switched inductor that aids in boosting the voltage levels. This brief covers the steady-state analysis and dynamic modeling of the proposed converter. Furthermore, an effective control strategy has been developed, leveraging the K-factor method, to operate the converter in voltage control mode. This ensures stability, even in the event of significant variations in input voltage. To validate the efficacy of the proposed converter and controller, a practical 110W prototype was meticulously constructed and rigorously tested within a controlled laboratory environment. © 2004-2012 IEEE.
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    Investigation and Performance Evaluation of Novel Single-Switch High-Gain DC-DC Converters for DC Microgrid Applications
    (Institute of Electrical and Electronics Engineers Inc., 2025) Diwakar Naik, M.; Vinatha Urundady, U.; Naik, M.; Bonthagorla, P.K.
    This paper introduces a novel single-switch, non-isolated high-gain DC-DC converter for solar photovoltaic (PV) and fuel-cell (FC) applications. These energy sources typically provide a continuous supply of current, necessitating a high-gain DC-DC converter that operates in continuous conduction mode (CCM). This converter draws a continuous input current from the supply and delivers a continuous output current to the load. The performance of the converter is thoroughly analyzed through the development of a state-space model and the derivation of the small signal transfer function, which helps in understanding the converter’s dynamic behavior. Detailed comparisons with existing converters are also presented. Furthermore, an output voltage controller is designed using the k-factor method to effectively regulate the output voltage without requiring a current sensor, even in the presence of input voltage variations. To validate the effectiveness of the converter and its controller, a 150 W prototype was constructed and experimentally verified in a laboratory setting. © 2013 IEEE.