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Item A Single Source Quadruple Boost Nine-Level Switched-Capacitor Inverter with Reduced Components and Continuous Input Current(Institute of Electrical and Electronics Engineers Inc., 2024) Kumar, D.; Raushan, R.; Chakraborty, S.The multilevel inverter (MLI) serves as a pivotal class of power electronic converters, well-suited for high-power applications at medium voltage levels, ensuring superior power quality. While designing an MLI, there is a motif among the number of components, voltage stress on the semiconductor devices, and its voltage-boosting ability. A single source nine-level switched-capacitor based novel inverter with reduced components has been proposed in this paper. The proposed H-bridge based switched capacitor inverter topology employs nine switches, two capacitors, two diodes, and one DC source. The inverter has a quadruple voltage boost and the ability to draw continuous input current from the DC supply and self-voltage balance with a voltage ripple of less than 5%. A comprehensive study of performance parameters, design consideration, and loss analysis of the proposed inverter is also incorporated. A level-shifted pulse width modulation technique is implemented to operate the inverter for unity to 0.5 lagging load power factors and 1-0.2 modulation indices. The dynamic responses of the proposed switched capacitor inverter topology are obtained through MATLAB simulation for analysis and further validated by hardware prototype. © 2013 IEEE.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 An Inductorless Triple Boost 13-Level Switched Capacitor Inverter with Reduced Ripple Current(Institute of Electrical and Electronics Engineers Inc., 2024) Ahmed, M.S.; Raushan, R.; Ahmad, M.W.Switched capacitor (SC) multilevel inverter (SCMLI) is a promising alternative to traditional voltage source inverters for industrial and renewable energy applications. In SCMLI, capacitors are used in a specific sequence during charging and discharging either in parallel or series with the source for level generation. During the charging period of the capacitor, a large ripple current is generated. This ripple may cause an increase in the peak current and ripple voltage of the capacitors. The reliability and life expectancy of the inverter can be severely affected by this ripple current of the capacitor. This article proposes an inductorless self-balance single-phase 13-level inverter with triple boosting capability. It aims to reduce the ripple current in both the source and capacitors by arranging the switching sequence in a particular fashion to implement a partial charging technique in the capacitors. Furthermore, it results in better efficiency and reduced current stress without the need for any source inductance or a complicated control algorithm. The performance of the proposed inverter is verified through its laboratory prototype under dynamic load conditions and varying modulation indexes. © 1986-2012 IEEE.