Your search keyword '"Agamy, Mohammed"' showing total 4 results

1. Split Duty Cycle Coupled Multiphase Boost–Buck Converter.

Author

Khamis, Ahmed K., Agamy, Mohammed, and Ramabhadran, Ramanujam

Subjects

*DC-to-DC converters, *ENERGY storage, *ELECTROMAGNETIC coupling

Abstract

The classic cascaded boost–buck converter has inductors at the input and output ports of the converters, which makes it an ideal interface for bidirectional battery charging applications, where accurate current control and low ripple currents are required. This article proposes a split duty cycle coupled multiphase variant applied to the cascaded boost–buck converter and utilizes coupled inductor features to achieve very lower current ripples at the output, lower power losses, and reduction in magnetic component volume. Moreover, current sharing between each phase is inherently implemented, making it suitable for a high-conversion-ratio bidirectional operation in systematic energy storage applications, where the low-voltage port has very high current. This article covers a split duty cycle converter operation principle using coupled inductors between the input and the multiphase output. Magnetic component design and selection guidelines are presented. The proposed control method and the coupled inductor structure are validated by simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2021

2. An Efficient Partial Power Processing DC/DC Converter for Distributed PV Architectures.

Author

Agamy, Mohammed S., Harfman-Todorovic, Maja, Elasser, Ahmed, Chi, Song, Steigerwald, Robert L., Sabate, Juan A., McCann, Adam J., Zhang, Li, and Mueller, Frank J.

Subjects

*DC-to-DC converters, *MAXIMUM power point trackers, *PHOTOVOLTAIC power system design & construction, *ENERGY consumption, *STABILITY theory, *ELECTRIC charge

Abstract

In this paper, a dc/dc power converter for distributed photovoltaic (PV) plant architectures is presented. The proposed converter has the advantages of simplicity, high efficiency, and low cost. High efficiency is achieved by having a portion of the input PV power directly fed forward to the output without being processed by the converter. The operation of this converter allows for a simplified maximum power point tracker design using fewer measurements. The stability analysis of the distributed PV system comprised of the proposed dc/dc converters confirms the stable operation even with a large number of deployed converters. The experimental results show a composite weighted efficiency of 98.22% with very high maximum power point tracking efficiency. [ABSTRACT FROM AUTHOR]

Published

2014

3. A Three-Level Resonant Single-Stage Power Factor Correction Converter: Analysis, Design, and Implementation.

Author

Agamy, Mohammed S. and Jain, Praveen K.

Subjects

*DC-to-DC converters, *ELECTRIC current converters, *TOPOLOGY, *ELECTRIC potential, *INDUSTRIAL electronics, *ELECTRIC circuits, *ELECTRONIC modulation, *ELECTRIC controllers, *CONDUCTION electrons

Abstract

This paper presents a new single-stage power factor correction ac/dc converter based on a three-level half-bridge resonant converter topology. The proposed circuit integrates the operation of the boost power factor preregulator and the three-level resonant dc/dc converter. A variable-frequency asymmetrical pulsewidth modulation controller is proposed for this converter. This control technique is based on two integrated control loops: the output voltage is regulated by controlling the switching frequency of the resonant converter, whereas the dc-bus voltage and input current are regulated by means of duty cycle control of the boost part of the converter. This provides a regulated output voltage and a nearly constant dc-bus voltage regardless of the loading condition; this, in turn, allows using smaller switches and consequently having a lower on resistance helping to reduce conduction losses. Zero-voltage switching is also achieved for a wide range of loading and input voltage. The resulting circuit, therefore, has high conversion efficiency making it suitable for high-power wide-input-voltage-range applications. The effectiveness of this method is verified on a 2.3-kW 48-V converter with input voltage (90-265 Vrms). [ABSTRACT FROM AUTHOR]

Published

2009

4. A Variable Frequency Phase-Shift Modulated Three-Level Resonant Single-Stage Power Factor Correction Converter.

Author

Agamy, Mohammed S. and Jam, Praveen K.

Subjects

*ELECTRIC potential, *VOLTAGE-frequency converters, *ENERGY conversion, *FREQUENCY changers, *ELECTRIC power factor, *TOPOLOGY, *ELECTRICAL engineering, *DC-to-DC converters

Abstract

This paper presents a new single-stage three-level resonant power factor correction ac-dc converter suitable for high power applications (in the order of multiple kilowatts) with a universal input voltage range (90-265 Vrms). The proposed topology integrates the boost input power factor preregulator with a half-bridge three-level resonant dc-dc converter. The converter operation is controlled by means of a combination of phase-shift and variable frequency control. The phase-shift between the switch gate pulses is used to provide the required input current shaping and to regulate the dc-bus voltage to a set reference value for all loading conditions, whereas, variable frequency control is used to tightly regulate the output voltage. An auxiliary circuit is used in order to balance the voltage across the two dc-bus capacitors. Zero voltage switching (ZVS) is also achieved for a wide range of loading and input voltage by having a lagging resonant current in addition to the flowing of the boost inductor current through the body diodes of the upper pair of switches in the free wheeling mode. The resulting circuit, therefore, has high conversion efficiency and lower component stresses making it suitable for high power, wide input voltage range applications. The effectiveness of the proposed converter is verified by analysis, simulation, and experimental results. [ABSTRACT FROM AUTHOR]

Published

2008