Faculty Publications
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Publications by NITK Faculty
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Item Five-Level Switched Capacitor Inverter for Photovoltaic Applications(Taylor and Francis Ltd., 2022) Singh, A.K.; Mandal, R.K.; Raushan, R.; Anand, R.This paper proposes a switched-capacitor based single-phase five-level inverter configuration that operates under boost operation and generates a voltage that is more than the DC source voltage. The proposed five-level inverter uses a capacitor and boots the output voltage. In this proposed inverter, capacitor gets charged in parallel while it discharges in series connections so that output voltage may attain higher magnitude than the DC source voltage. Sinusoidal Pulse Width Modulation-based techniques are considered to produce the required gate pulses for operating the switching devices of the inverter. The five-level switched-capacitor inverter is combined with the PV system via DC–DC boost converters to extract the maximum power using MPPT algorithm. To verify its capability, the PV-based system is further integrated to the utility grid. The operation and performance of the suggested switched-capacitor inverter coupled with the grid-connected PV system are also analyzed by developing its model in MATLAB/Simulink environment. © 2022 IETE.Item A Reduced Component Count Self-Balance Quadruple Boost Seventeen-Level Switched Capacitor Inverter(Institute of Electrical and Electronics Engineers Inc., 2024) Ahmed, S.; Raushan, R.; Ahmad, M.W.A switched capacitor multilevel inverter (SCMLI) enables high-quality output voltage waveforms for various industrial and renewable energy applications. SCMLI uses a combination of capacitors and switches to generate multiple voltage levels from a single dc source, thereby reducing the overall cost and size of the system. This article proposes a novel configuration of a 17-level SCMLI. The proposed converter can boost four times the input voltage by exploiting the series-parallel connection of capacitors with the dc voltage source. With simple pulsewidth modulated (PWM) control, the capacitor voltages are inherently balanced under different loading conditions. Furthermore, for 11 switches, only seven independent switching signals are required. Loss analysis reveals that the proposed SCMLI has significantly reduced conduction losses, capacitor ripple voltage, voltage stress, and cost function (CF) when compared with other topologies available in the literature. Finally, the simulation results are obtained at different loads and modulation indexes. The results are experimentally validated with a scaled-down laboratory prototype. © 2024 Institute of Electrical and Electronics Engineers Inc.. All rights reserved.Item A Reduced Capacitance H-9 Five-Level Switched Boost Capacitor Transformerless Inverter(Institute of Electrical and Electronics Engineers Inc., 2025) Ahmed, Md.S.; Raushan, R.; Ahmad, Md.W.Transformerless switched capacitor-based multi-level inverters are well-known for their applications in industrial and renewable energy systems. The primary features of a switched capacitor-based transformerless inverter should be minimizing leakage current for safety and minimizing ripple current for efficiency and reliability. This brief proposes a new single-stage, single-phase, five-level H-9-based transformerless inverter for standalone PV systems. This H-9 inverter, utilizes nine switches to produce the desired output voltage levels. It achieves boost functionalities by combining the switched capacitor (SC) unit with the switched boost (SB) unit in a single design. This topology effectively mitigates the leakage current by virtually grounding the load terminal through the filter capacitor. Furthermore, the ripple current of the capacitors in the switched-capacitor unit is minimized, and it is inherently balanced. To this end, the feasibility of utilizing the modulation technique for control is demonstrated, and the relevant results are experimentally validated using a laboratory prototype of the proposed converter. © 2004-2012 IEEE.