Small-signal analysis of the phase-shifted PWM converter
TL;DR: In this article, specific circuit effects in the phase-shifted PWM (PS-PWM) converter and their impact on the converter dynamics are analyzed, and the small-signal model is derived incorporating the effects of phase-shift control and the utilization of transformer leakage inductance and power FET junction capacitances to achieve zero-voltage resonant switching.
Abstract: The specific circuit effects in the phase-shifted PWM (PS-PWM) converter and their impact on the converter dynamics are analyzed. The small-signal model is derived incorporating the effects of phase-shift control and the utilization of transformer leakage inductance and power FET junction capacitances to achieve zero-voltage resonant switching. The differences in the dynamic characteristics of the PS-PWM converter and its PWM counterpart are explained. Model predictions are confirmed by experimental measurements. >
Citations
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02 Sep 2015
TL;DR: In this paper, a detailed design procedure is presented for a bidirectional CLLLC-type resonant converter for a battery charging application, and a 3.5kW converter is designed following the guidelines in the proposed methodology.
Abstract: In this paper, a detailed design procedure is presented for a bidirectional CLLLC-type resonant converter for a battery charging application. This converter is similar to an LLC-type resonant converter with an extra inductor and capacitor in the secondary side. Soft-switching can be ensured in all switches without additional snubber or clamp circuitry. Because of soft-switching in all switches, very high-frequency operation is possible; thus, the size of the magnetics and the filter capacitors can be made small. To reduce the size and cost of the converter, a CLLC-type resonant network is derived from the original CLLLC-type resonant network. First, in this paper, an equivalent model for the bidirectional converter is derived for the steady-state analysis. Then, the design methodology is presented for the CLLLC-type resonant converter. Design of this converter includes determining the transformer turns ratio, design of the magnetizing inductance based on ZVS condition, design of the resonant inductances and capacitances. Then, the CLLC-type resonant network is derived from the CLLLC-type resonant network. To validate the design procedure, a 3.5-kW converter was designed following the guidelines in the proposed methodology. A prototype was built and tested in the laboratory. Experimental results verified the design procedure presented.
230 citations
Cites background from "Small-signal analysis of the phase-..."
...This, however, results in duty cycle loss and it increases the reactive energy in the circuit for certain load conditions, which decreases converter efficiency [20]....
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TL;DR: In this article, a novel interleaved high step-up converter with WCCIs and voltage multiplier cells is proposed, which minimizes the peak current ripple of the power devices and makes low-voltage MOSFETs with high performance available in high output voltage applications.
Abstract: The concept of winding-cross-coupled inductors (WCCIs) and voltage multiplier cells is integrated to derive a novel interleaved high step-up converter in this paper. The voltage gain is extended and the switch voltage stress is reduced by the WCCIs and the voltage multiplier cells in the presented circuit, which minimizes the peak current ripple of the power devices and makes low-voltage MOSFETs with high performance available in high step-up and high output voltage applications. Moreover, the output diode reverse-recovery problem is alleviated by the leakage inductance of the WCCIs, which reduces the reverse-recovery losses. Zero current switching (ZCS) turn-on is realized for the power switches to reduce the switching losses. Furthermore, the voltage spikes on the MOSFETs are clamped and the leakage energy is recycled by the voltage multiplier cells, when the switch turns off. A 1 kW prototype with 35-45 V input and 380 V output operating at 50 kHz switching frequency is built and tested to verify the significant improvements of the proposed converter.
203 citations
TL;DR: A charge control with an input voltage feedforward is proposed for an input-series-output-parallel-connected converter configuration for the high-speed-train power system application that accomplishes the output current sharing and offers the robustness for the input voltage sharing control according to the component value mismatches among the modules.
Abstract: In this paper, a charge control with an input voltage feedforward is proposed for an input-series-output-parallel-connected converter configuration for the high-speed-train power system application. This control scheme accomplishes the output current sharing. For the output-parallel-connected modules as well as the input voltage sharing for the input-series-connected modules for all operating conditions including the transients. It also offers the robustness for the input voltage sharing control according to the component value mismatches among the modules. This configuration enables the usage of a MOSFET for a high-voltage system allowing a higher switching frequency for a lighter system weight and smaller size. The performance of the proposed scheme is verified through the experimental results.
198 citations
Cites background from "Small-signal analysis of the phase-..."
...In this figure, all switches are replaced with its small-signal pulsewidth modulation (PWM) model [7], [8]....
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TL;DR: The relationship between input voltage sharing (IVS) and output current sharing of the constituent modules of the ISOP converter is revealed and a novel IVS control strategy, which is decoupled with the output voltage regulation, is proposed.
Abstract: The input-series-output-parallel (ISOP) converter, which consists of multiple dc-dc converter modules connected in series at the input and in parallel at the output, is an attractive solution for high input voltage and high power applications. This paper reveals the relationship between input voltage sharing (IVS) and output current sharing of the constituent modules of the ISOP converter. A novel IVS control strategy, which is decoupled with the output voltage regulation, is proposed. This control allows IVS and output voltage regulation to be designed independently. An ISOP converter, which uses the phase-shifted full-bridge (PS-FB) converter as the basic module, is considered. Based on the proposed control strategy, this ISOP converter together with the control circuit can be decoupled from several independent single-input and single-output systems. An ISOP converter consisting of three PS-FB modules is used to illustrate the design procedure, and a 3-kW experimental prototype is fabricated and tested.
193 citations
Additional excerpts
...andthen substituting (13.2), ( 13 .3), (16) and(17) into it, yields...
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TL;DR: By employing the proposed method, families of FB and BDC-based MPCs (FB-BDC-MPCs), including some existing ones, are developed for renewable generation systems with the merits of simple topology, reduced devices, and single-stage power conversion.
Abstract: A systematic method for deriving multiport converters (MPCs) from the full bridge (FB) converter (FBC) and bidirectional dc-dc converters (BDCs) is proposed in this paper through sharing the parasitized switching legs by the BDCs and the FBC. By employing the proposed method, families of FB and BDC-based MPCs (FB-BDC-MPCs), including some existing ones, are developed for renewable generation systems with the merits of simple topology, reduced devices, and single-stage power conversion. Voltage regulations between any two ports can be achieved by employing pulsewidth modulation and phase-angle-shift control scheme. Furthermore, zero-voltage switching for all the switches can be realized in the proposed FB-BDC-MPCs. A typical four-port converter developed by the proposed method, named buck/boost four-port converter (BB-FPC), is analyzed in detail as an example in terms of operation principles, design considerations, and control strategy. Experiments have been carried out on a 500-W prototype of BB-FPC, which demonstrate the feasibility and effectiveness of the proposed topology derivation method.
189 citations
References
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11 Mar 1990
TL;DR: In this article, a steady-state analysis is presented with complete characterization of the converter operation and the design procedures based on the analysis are presented and the various losses in the circuit assessed.
Abstract: A steady-state analysis is presented with complete characterization of the converter operation. A small-signal model of the converter is established. The design procedures based on the analysis are presented and the various losses in the circuit assessed. Critical design considerations for a high-power, high-voltage application are analyzed. The results of the analysis are verified using a high-voltage. 2 kW prototype. >
875 citations
11 Jun 1990
TL;DR: In this article, the authors presented an improved soft-switching full-bridge converter which is especially suitable for high-power application (e.g. more than 1 kW output) because of its inherently high efficiency.
Abstract: The authors present an improved soft-switching full-bridge converter which is especially suitable for high-power application (e.g. more than 1 kW output) because of its inherently high efficiency. The addition of an external commutating inductor and two clamp diodes to the phase-shifted PWM (pulse width modulation) full-bridge DC-DC converter substantially reduced the switching losses of the transistors and the rectifier diodes, under all loading conditions. The authors analyze the conditions for lossless transitions, discuss the effect of the added components on the operation of the converter, and present practical considerations and test results for a 1.5 kW converter with 100 kHz clock frequency. The converter has an efficiency above 95% at 60 V output, is free from voltage overshoots, and exhibits well-controlled transitions for all switch and rectifier voltages and currents. >
426 citations
13 Mar 1989
TL;DR: In this paper, a prototype high power-density converter for distributed power supply systems is presented, which uses a phase-shifted pulse-width modulation technique to avoid primary-side switching losses.
Abstract: The analysis, design, and performance are discussed of a prototype high power-density converter suitable for use in the front-end of a distributed power supply system. The system delivers 1 kW to a regulated 40 V distribution bus from the rectified utility line. Its switching frequency is 500 kHz, and it uses a phase-shifted pulse-width modulation technique to avoid primary-side switching losses. The converter's topology is a standard power MOSFET H-bridge that drives a transformer. The output of this transformer is rectified by a full bridge of Schottky diodes. The switches of this forward converter are operated in a fixed-frequency PWM mode. The dominant parasitic elements are the transformer's leakage inductor, the MOSFETs' output capacitors, and the rectifiers' junction capacitors. Of these three groups of parasitic elements, only the leakage inductors do not result in a direct switching loss. To avoid MOSFET switching losses, the converter is controlled with a special gate-drive pattern that permits full recovery of the MOSFETs' capacitive energy. At the same time this drive scheme gives zero-voltage switching for the MOSFETs. The converter's efficiency at full load approaches 90%. >
353 citations
TL;DR: In this article, an equivalent circuit model of a three-terminal switching device describing the perturbations in the average terminal voltages and current is obtained, and the analysis of pulsewidth modulated and quasiresonant converters becomes analogous to transistor circuit analysis where the transistor is replaced by its equivalent circuit.
Abstract: The nonlinear switching mechanism in pulsewidth-modulated (PWM) and quasi-resonant converters is that of a three-terminal switching device which consists only of an active and a passive switch. An equivalent circuit model of this switching device describing the perturbations in the average terminal voltages and current is obtained. Through the use of this circuit model the analysis of pulsewidth modulated and quasiresonant converters becomes analogous to transistor circuit analysis where the transistor is replaced by its equivalent circuit model. The conversion ratio characteristics of various resonant converters and their relationship to a single function, called the quasi-resonant function, is easily obtained using the circuit model for the three-terminal switching device. The small-signal response of quasi-resonant converters to perturbations in the switching frequency and input voltage is determined by replacing the three-terminal switching device by its small-signal equivalent circuit model. >
157 citations
Proceedings Article•
01 Jan 1984
15 citations