oost dc–ac inverter, also known as Boost inverter, consists f two individual Boost converters, as shown in Fig. 1. In this topology, both individual Boosts are drive by two 180phase-shifted dc-biased sinusoidal references whose differential output is an ac output vol
DC/DC Boost converter. E is the power source, u 1 is the control that turns the transistor on/off Q 1, i 1 the current through the inductor L 1 and D the diode. While υ 1 is the output voltage of the converter; associated to the capacitor terminals C 1, and υ 1 the power supply of the full-bridge Buck inverter.
These drawbacks cause undesirable problems such as high power ripples, overshoot, and limited dynamic response. Therefore, this paper proposes a three-level quadratic DC-DC boost converter as a suitable solution to replace conventional inverters in photovoltaic systems, while combined with an advanced MPPT method.
In this work, a passivity-based control was presented to perform the task of tracking the trajectory of bipolar voltage for υ 2 in the DC/DC Boost converter–full-bridge Buck inverter system.
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A double-loop control strategy is proposed for the buck–boost DC–DC converter with a new inner control loop for the inductor current and also a new outer control loop for the …
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The application of passivity-based control strategies in Bipolar voltage tracking control for DC/DC Boost converter–full-bridge Buck inverter systems presents significant …
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Therefore, this paper proposes a three-level quadratic DC-DC boost converter as a suitable solution to replace conventional inverters in photovoltaic systems, while combined …
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This paper investigates the performance of different control algorithms for boost converters, focusing on the Adaptive Neuro-Fuzzy Inference System (ANFIS)-based boost …
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Abstract Currently, Z-source networks are widely employed to extend the output-voltage range of inverters operating at a low voltage DC source. However, these inverters are …
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Therefore, a straightforward and simple operation is possible. In addition, the Y-inverter allows for continuous output AC voltage waveforms, eliminating the need of additional …
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This paper presents a simple switched-coupled-inductor inverter (SCII), as well as completes the relevant analysis, design, and implementation, for efforts aimed at achieving …
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A single-phase, single-stage, differential boost inverter comprises two independently-controlled boost DC-DC converters, with the load connected between their outputs. The net …
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The buck-boost DC-AC inverter is a special topology consisting of two buck-boost DC-DC converters that generate an AC output voltage in a single stage. This is achieved by …
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MPPT control algorithm using TMS320F280049 MCU. 100kHz PWM frequency for the DC/DC boost stage. 50kHz sampling frequency for current and voltage loop control of the DC/DC …
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A single-phase, single-stage, differential boost inverter comprises two independently-controlled boost DC-DC converters, with the load connected between their outputs. The net …
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This paper proposes a new voltage source inverter referred to as a boost inverter or boost DC-AC converter. The main attribute of the new inverter topology is the fact that it generates an AC …
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Abstract In this study, an integrated control strategy is proposed which can be widely used in two-stage boost inverters, and an improved two-stage boost inverter is taken as …
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