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Article

A Soft-Switching SEPIC with Multi-Output Sources

1
Department of Electrical Engineering, National Chin-Yi University of Technology, Taichung 41170, Taiwan
2
Department of Electronic Engineering, National Chin-Yi University of Technology, Taichung 41170, Taiwan
*
Author to whom correspondence should be addressed.
Electronics 2017, 6(2), 35; https://doi.org/10.3390/electronics6020035
Submission received: 2 March 2017 / Revised: 18 April 2017 / Accepted: 3 May 2017 / Published: 6 May 2017

Abstract

:
In this paper, a soft-switching single-ended-primary-inductance converter (SEPIC) with multi-output sources is proposed. The proposed SEPIC has the following advantages: (1) The conversion efficiency can be increased. To incorporate a soft-switching cell with a flyback-type, the power switches can achieve zero-voltage-switching (ZVS) and zero-current-switching (ZCS) features under turn-on transitions, resulting in reducing the switching losses and electromagnetic interference (EMI); (2) The applicability can be maximized. To apply the voltage ratio of the transformers, the proposed SEPIC has multi-output sources with step-up/down voltage functions. Finally, a prototype of the soft-switching SEPIC with multi-output sources is built and implemented. Simulated and experimental results are presented to verify the performance and the feasibility of the proposed soft-switching SEPIC with multi-output sources.

1. Introduction

Industrial development and technological progress has resulted in fossil fuel energy shortages and serious air quality concerns. To overcome fossil fuel energy shortages, the demand for renewable energy sources has increased significantly. The typical renewable energy sources include Photovoltaic PV panels, wind energy, and fuel cells, which have the features of cleanliness and freedom [1]. However, renewable energy sources have instability and intermittent output power characteristics. Thus, they demand a switching-mode power converter to convert and regulate the energies into suitable utilization power to loads [2,3].
With the demands of lighter weight, higher efficiency, and smaller size, switching-mode power converters have been becoming essential parts of renewable energy systems. The voltage and current requirements of the renewable energy systems often differ radically from the forms in which the renewable energies are delivered or stored. Switching-mode power converters use power semiconductor devices to control the power flow in an efficient way. A number of non-isolated power converters have been developed and proposed; for example, Buck, Boost, ‘Cuk, Zeta, and single-ended-primary-inductance converters (SEPIC), which have simple constructions and are widely used in low and medium power applications [4,5,6]. To step-up/down voltage and non-isolated applications, the SEPIC is widely used, as shown in Figure 1. However, the SEPIC has only a set of output sources, resulting in low applicability [7,8,9]. Furthermore, the high-frequency hard-switching conditions of the power switch (Metal-oxide-semiconductor-field-effect transistor, MOSFET) are major contributors to switching losses and high-frequency ringing in the SEPIC, resulting in high power losses, serious electromagnetic interference (EMI), and low conversion efficiency [8,9,10]. Figure 2 shows the experimental results of SEPIC with hard-switching conditions. High-frequency hard-switching of the high di/dt and dv/dt results in EMI of the high-frequency voltage and current, as well as high switching losses across the power switch. The serious EMI and switching losses are considerable, which will damage the tolerance of the power switch [9,10,11]. Figure 3 shows the typical switching loci for a power switch without and with soft-switching techniques, respectively. To resolve these discussed problems, the SEPIC with soft-switching techniques and multi-output sources is a highly researched topic.
In general, the soft-switching techniques can be classified into zero-voltage-switching (ZVS) and zero-current-switching (ZCS) techniques [12,13,14,15,16,17]. The ZVS or ZCS techniques drive the voltage or current of the power switch to zero before any switching action, and avoids the concurrent high voltage and high current in the switching transition. The ZVS techniques include ZVS turn-on and ZVS turn-off transitions, as shown in Figure 4. As illustrated in Figure 4a, the ZVS turn-off technique is generally accomplished by slowing the voltage rising rate while the power switch is turning off. In order to reduce turn-off loss of the power switch, an extra capacitor is added to the power switch in parallel, as shown in Figure 5. However, the charge stored in the capacitor will be discharging through the power switch when the switch is turned on again, creating an extra conduction loss in the power switch. To release this loss, a zero-voltage turn-on technique is adopted. In general, the ZVS turn-on technique is without an added external capacitor on the power switch. Thus, the power switch has no extra conduction loss. Figure 4b illustrates the typical voltage and current of switches with the ZCS turn-on and turn-off operation. Power switches with ZCS have no current at the switch turn-on and turn-off transition to reduce the switching loss. To achieve ZCS turn-off conduction, the power switch must be incorporated as an external snubber circuit. The snubber circuit needs at least a capacitor, a diode, and an inductor, as shown in Figure 6. Thus, the complexity of the converter is increased. To resolve this disadvantage, the ZCS turn-on technique can be easily achieved by inserting an inductor in series with the power switch to limit the current rising rate at the switching transition. Comparing the ZVS/ZCS turn-on and ZVS/ZCS turn-off techniques, the ZVS/ZCS turn-on techniques have less components and are easily accomplished.
From the above description, power converters with ZVS/ZCS turn-on techniques are effective means for solving or alleviating switching losses and EMI problems [18,19,20,21,22]. In this paper, a soft-switching SEPIC with multi-output sources is proposed, as shown in Figure 7. The proposed soft-switching SEPIC has the following advantages: (1) The use of a simple flyback-type cell, which can achieve the ZVS turn-on condition of the main switch (M1) and the ZCS turn-on condition of the auxiliary switch (M2), resulting in low switching losses and EMI, and (2) To apply the voltage ratio of the transformers, the proposed SEPIC has the functions of multi-output sources with step-up/down voltage. In this paper, the power estimation of hard-switching SEPIC is described in Section 2. The operational principles of the proposed soft-switching SEPIC with multi-output sources are described in Section 3. Simulated and experimental results obtained from the proposed soft-switching SEPIC with multi-output sources are presented in Section 4. Finally, a conclusion is given in Section 5.

2. Power Estimation of Hard-Switching SEPIC

Figure 2 shows that the SEPIC with hard switching techniques results in serious EMI and high switching losses. The illustrated switching waveforms of the power switches are shown in Figure 8. The average switching power and conduction power losses over one switching cycle from the waveforms of Figure 8 can be evaluated as follows:
P a v e = 1 T [ 0 T i s w v s w d t ] = P a v e , s w i t + P a v e , c o n d ,
where Pave,swit is the average switching losses, Pave,cond is the average conduction losses, and T is the switching cycle. The power losses of Pave,swit and Pave,cond can be expressed as follows:
P a v e , s w i t = 1 T [ 0 t o n i s w v s w d t + D T t o f f D T i s w v s w d t ] ,
P a v e , c o n d = 1 T [ t o n D T t o f f I o n V o f f d t + D T T I o f f V o n d t ] = I o n V o f f [ D ( t o n + t o f f ) T + I o f f V o n ( 1 D ) ] ,
where DT is the duty cycle and Ioff is the leakage current of the power switch. If the on and off times are small compared to T, then Equation (3) can be expressed as follows:
P a v e , c o n d = I o n V o f f D + I o f f V o n ( 1 D ) .
From Equation (2), it can be seen that the power losses of the power switch is operated at each cycle of the turn-on and turn-off transitions. Therefore, power converters with soft-switching techniques make them suitable for high-frequency operation. The benefits of power converters with ZVS and ZCS features can be summarized as follows:
(1)
Low switching losses and high conversion efficiency,
(2)
Low di/dt and dv/dt, and thus low voltage spikes and EMI emissions, and
(3)
High reliability and low cost.

3. Operational Principles

As shown in Figure 7, the proposed soft-switching SEPIC with multi-output sources consists of the main switch (M1), auxiliary switch (M2), transformers (Tr1 and Tr2), free-wheeling diodes (Da, Db, and Dc), and filter capacitors (Ca, Co1, Co2, and Co3). The soft-switching cell is composed of an auxiliary switch (M2) and a transformer (Tr1) to achieve ZVS and ZCS features of the main and auxiliary switches (M1 and M2). Furthermore, to apply the voltage ratio of the transformers (Tr1 and Tr2), the proposed soft-switching SEPIC has multi-output sources with step-up/down voltage functions. Therefore, the utility of the proposed soft-switching SEPIC can be increased.
In Figure 7, the operational principles of the soft-switching SEPIC with multi-output sources over one switching cycle can be divided into seven major operating modes. Figure 9 shows the current and voltage waveforms of the key components and the driving signal switches (M1 and M2). Figure 10 shows the equivalent circuit modes of the soft-switching SEPIC with multi-output sources over a switching cycle. To simplify the description of the operational modes, the following assumptions are made.
(1)
Capacitances of Ca, Co1, Co2, and Co3 are large enough that the voltages across them are constant over a switching cycle.
(2)
All of the switching devices, MOSFETs, and diodes are ideal.
Mode 1 (Figure 10a, t0 < t < t1):
At time t0, the main switch (M1) is turned on and the auxiliary switch (M2) is turned off. The inductor current iLa flowing through the path of Vs-La-M1 linearly increases. The inductor current iLa can be expressed as follows:
i L a ( t ) = V s L s ( t t 0 ) .
While the capacitor (Ca) is discharged, the discharging current ica is flowing through the path of Ca-M1-Tr2. The current ica can be expressed as follows:
i c a ( t ) = V L m 2 L m 2 ( t t 0 ) .
At this time, the total current flowing through the main switch (M1) is iM1 = iLa + ica. During this mode, the freewheeling diodes (Da) and (Dc) are turned off, and (Db) is turned on. The magnetic inductance (Lm1) of the transformer (Tr1) delivers power to the first-set source, and the capacitors (Co2 and Co3) individually deliver power to the second-set and third-set output sources. The equivalent circuit is shown in Figure 10a.
Mode 2 (Figure 10b, t1 < t < t2):
At time t1, the main switch (M1) is turned off, and the auxiliary switch (M2) is kept off. While the freewheeling diode (Da) is turned on, the inductor current iLa begins discharging and flowing through the path of La-Ca-Da-Vo3-Vs to deliver power to the third-set output source. The inductor current iLa can be expressed as follows:
i L a ( t ) = i c a ( t ) = V c a + V o 3 V s L a ( t t 1 ) .
During this interval, the freewheeling diodes (Db) and (Dc) are turned on. The magnetic inductance (Lm1) and (Lm2) of transformers (Tr1 and Tr2) individually deliver power to the first-set and second-set sources. The equivalent circuit is shown in Figure 10b.
Mode 3 (Figure 10c, t2 < t < t3):
At time t2, the auxiliary switch (M2) is turned on under the ZCS condition and the main switch (M1) is maintained off. The inductor current iLa is divided into two-branched currents iM2 and ica. One is flowing through the path of La-Ca-Da-Vo3-Vs, and the other is flowing through the path of La-Tr1-M2-Vs. The currents of iLa, iM2, and ica can be expressed as follows:
i L a ( t ) = i M 2 ( t ) + i c a ( t ) ,
i M 2 ( t ) = ( V s + V L a ) L m 1 ( t t 2 ) ,
and
i c a ( t ) = ( V s + V L a V o 3 ) L a ( t t 2 ) .
During this interval, the freewheeling diode (Db) is turned off and (Da and Dc) are kept on. Capacitor (Co1) delivers power to the first-set source and the magnetic inductance (Lm2) of transformer (Tr2) delivers power to the second-set source. The equivalent circuit is shown in Figure 10c.
Mode 4 (Figure 10d, t3 < t < t4):
At time t3, when current iLa = iM2, the freewheeling diodes (Da and Dc) are turned off. Then, capacitor (Ca) begins discharging through the path of Ca-Tr1-M2-Tr2. The currents of iLa and ica can be expressed as follows:
i L a ( t ) = ( V s + V L a ) L m 1 ( t t 3 ) ,
and
i c a ( t ) = ( V s + V L a V L m 2 ) L m 1 + L m 2 ( t t 3 ) .
At this time, the current iM2 = iLa + ica. During this interval, the capacitors (Co1, Co2, and Co3) individually deliver power to the first-set, second-set, and third-set sources. The equivalent circuit is shown in Figure 10d.
Mode 5 (Figure 10e, t4 < t < t5):
At time t4, when the current iLa is less than iM2, the parasitic capacitance (C1) of the main switch (M1) is discharged. At this time, the current iM2 = iLa + iM1 + ica. The currents of iLa and ica can be expressed as follows:
i L a ( t ) = ( V s + V L a + V L m 1 ) L m 1 ( t t 4 ) ,
and
i c a ( t ) = ( V L m 1 + V L m 2 ) L m 1 + L m 2 ( t t 4 ) .
During this interval, the freewheeling diodes (Da, Db, and Dc) are kept off. The capacitors (Co1, Co2, and Co3) individually deliver power to the first-set, second-set, and third-set sources. The equivalent circuit is shown in Figure 10e.
Mode 6 (Figure 10f, t5 < t < t6):
At time t5, the voltage of the parasitic capacitor (C1) is dropped to zero, and the body diode of the main switch (M1) is conducting and creating a ZVS condition for the main switch (M1). At this time, the current iM2 = iLa + iM1 + ica. The currents of iLa and ica can be expressed as follows:
i L a ( t ) = V s L m 1 ( t t 5 ) ,
and
i c a ( t ) = ( V L m 1 + V L m 2 ) L m 1 + L m 2 ( t t 5 ) .
During this interval, the freewheeling diodes (Da, Db and Dc) are kept off. The capacitors (Co1, Co2, and Co3) individually deliver power to the first-set, second-set, and third-set sources. The equivalent circuit is shown in Figure 10f.
Mode 7 (Figure 10g, t6 < t < t7):
At time t6, the main switch (M1) is turned on under the ZVS conduction. At this time, the current of the main switch (M1) is reversed, and the current of the auxiliary switch (M2) is iM2 = iLa + icaiM1. The currents of iLa and ica can be expressed as follows:
i L a ( t ) = V s L m 1 ( t t 6 ) ,
and
i c a ( t ) = ( V L m 1 + V L m 2 ) L m 1 + L m 2 ( t t 6 ) .
During this interval, the freewheeling diodes (Da, Db, and Dc) are kept off. The capacitors (Co1, Co2, and Co3) individually deliver power to the first-set, second-set, and third-set sources. The operational mode of the soft-switching SEPIC over one switching cycle is completed. The equivalent circuit is shown in Figure 10g.

4. Analysis of the Proposed Converter

In this section, the soft-switching cell and voltage gain of the proposed SEPIC with multi-output sources will be analyzed in detail.

4.1. Derivations of a ZVS-ZCS Cell with Flyback-Type

In the literature, a number of power converters with soft-switching cells have been proposed [23,24,25,26,27,28,29,30,31]. All of them employ an auxiliary switch and passive components to form a soft-switching cell, which is used only to create a condition for achieving ZVS and ZCS at the power switches’ turn-on transition. Figure 11 shows an equivalent power converter with a soft-switching cell. The topology differs from a conventional power converter by an additional auxiliary switch (M2) and a resonant inductor (L1) which includes the parasitic capacitor (C1) of the main switch (M1) and a freewheeling diode (Da). This resonant branch L1-M2-C1 is active only during a short switching transition time to create a ZVS condition for the main switch (M1) and a ZCS condition for the auxiliary switch (M2). By incorporating this type of resonant network, the soft-switching concept can be extended to generate different ZVS-ZCS types of power converters.
Figure 12 shows a conventional SEPIC with a ZVS-ZCS inductor-type cell. The ZVS-ZCS inductor-type cell is composed of a resonant inductor (L1), an auxiliary switch (M2,) and a diode (Db), which operates at a fixed frequency and is controlled by a pulse-width-modulated (PWM) scheme. In Figure 12, to obtain multi-output sources and increase utility, the resonant inductor (L1) of the ZVS-ZCS cell and the inductor (Lb) can be replaced by transformers. Therefore, the ZVS-ZCS cell and the inductor (Lb) of Figure 13 can be modified to use two sets of flyback cell. Finally, a soft-switching SEPIC with multi-output sources is obtained, as shown in Figure 7.

4.2. Analysis of the Voltage Gain

The proposed soft-switching SEPIC has three sets of output sources, as shown in Figure 7. In order to obtain a facile analysis, the proposed soft-switching SEPIC with multi-output sources can be divided into two topologies. One is the SEPIC-flyback topology, and the other is the flyback topology, as shown in Figure 13.
In Figure 13a, it can be seen that the SEPIC-flyback topology is a combination of a SEPIC and a flyback converter. In order to obtain a facile analysis, the currents of inductor (La) of the SEPIC are assumed to be continuous. When the switch (M1) is turned on and the diode (Da) is turned off, the voltage across the inductor (La) is expressed as:
V L a , ( s w i t c h   t u r n o n ) = V s .
When the switch (M1) is turned off and the diode (Da) is turned on, the voltage across the inductor (La) is expressed as:
V L a , ( s w i t c h   t u r n o f f ) = V c 1 + V o 3 V s .
In steady-state operation, the voltage (Vca) across capacitor (Ca) remains constant and can be expressed as:
V c 1 = V s .
Therefore, Equation (5) can be expressed as:
V L a , ( s w i t c h   t u r n o f f ) = V o 3 .
According to the volt-second balance principle of the inductor (La), the average voltage across an inductor is zero for a periodic operation. Equations (4) and (7) are combined to obtain the following:
V L a , ( s w i t c h   t u r n o n ) ( D T ) = V L a , ( s w i t c h   t u r n o f f ) ( 1 - D ) T ,
or
V s ( D T ) = V o 3 ( 1 - D ) T ,
where D is the duty ratio of the switch (M1), and the result of the voltage gain for the output source of the third set can be determined as:
V o 3 V s = D 1 D .
For the output source of the secondary, the voltage gain can be determined by the volt-second balance principle. When the switch (M1) is turned on and the diode (Da) is turned off, energy is stored in the magnetizing inductance (Lm2) of transformer (Tr2). The voltage of the magnetizing inductance (Lm2) is expressed as:
V L m 2 , ( s w i t c h   t u r n o n ) = V c 1 = V s .
When the switch (M1) is turned off and the diode (Da) is turned on, the current of the magnetizing inductance (Lm2) cannot change instantaneously. Therefore, the conduction path must be through the primary turns (Np2) of the transformer (Tr2). The current iLm2 enters the dotted terminal of the primary and must exit from the dotted terminal of the secondary. The secondary voltage Vs2 of the transformer (Tr2) becomes Vo2. The secondary voltage Vs2 of the transformer (Tr2) is sent back to the primary and establishes the voltage across the magnetizing inductance (Lm2), which is expressed as:
V L m 2 , ( s w i t c h   t u r n o f f ) = V o 2 ( N p 2 N s 2 ) ,
where Np2 is the primary turns and Ns2 is the secondary turns of transformer (Tr2). According to the volt-second balance principle of the magnetizing inductor (Lm2), the average voltage across the primary turns (Np2) and secondary turns (Ns2) is zero for a periodic operation. Equations (11) and (12) are combined to obtain the following:
V L m 2 , ( s w i t c h   t u r n o n ) ( D T ) = V L m 2 , ( s w i t c h   t u r n o f f ) ( 1 - D ) T ,
or
V s D T = V o 2 ( N p 2 N s 2 ) ( 1 D ) T .
The result of the voltage gain for the output source of the secondary set can be determined as:
V o 2 V L m 2 = ( N s 2 N p 2 ) ( D 1 D ) .
Similarly, Figure 13b is also a flyback topology. According to Equations (12)–(15), the result of the voltage gain for the output source of the first set can be determined as:
V o 1 V L m 1 = ( N s 1 N p 1 ) ( D 1 D ) ,
where Np1 is the primary turns and Ns1 is the secondary turns of transformer (Tr1).

4.3. Region of ZVS and ZCS

To reduce switching losses and increase the conversion efficiency, the proposed SEPIC is incorporated with a soft-switching cell to implement ZVS and ZCS features. In Figure 7, the voltage across the main switch (M1) is larger than that across the auxiliary switch (M2). Thus, the magnetizing inductance (Lm1) of the transformer (Tr1) has enough energy to achieve the ZVS and ZCS features for the main switch (M1) and auxiliary switch (M2).To achieve the ZVS and ZCS features, the magnetizing inductance (Lm1) of the transformer (Tr1) needs to meet the following inequality:
L m 1 C 1 ( V s + V L a ) 2 ( I o 1 / n ) 2 ,
where n = Ns1/Np1 is the turns ratio of the transformer (Tr1), Io1 is the average output current of the first-set source, and C1 is the parasitic capacitance of the main switch (M1). The ZVS and ZCS features for the main switch (M1) and auxiliary switch (M2) depend on C1, Lm1, Vs, and Io1. Therefore, we can plot the curves, showing the relationships between the magnetizing inductance (Lm1) and the output current Io1 for different values of input voltage Vs, as illustrated in Figure 14. For achieving the ZVS and ZCS features, the magnetizing inductance (Lm1) should be selected from the area above the grid surface, as shown in Figure 14.

5. Simulated and Experimental Results

To verify the feasibility of the design, a 150 W prototype of the proposed soft-switching SEPIC with multi-output sources is implemented. Its specifications are listed as follows:
  • input voltage: Vs = 60 Vdc,
  • first-set output voltage: Vo1 = 12 Vdc,
  • second-set output voltage: Vo2 = 24 Vdc,
  • third-set output voltage: Vo3 = 100 Vdc,
  • total output power: 150 W, and
  • switching frequency: f = 55 kHz.
Figure 15 shows the simulated and experimental voltage and current waveforms of the main switch (M1) at the turn-on transition for the proposed soft-switching SEPIC. From Figure 15, it can be seen that the main switch (M1) has a ZVS feature and low EMI noise. Figure 16 shows the simulated and experimental voltage and current waveforms of the auxiliary switch (M2) at the turn-on transition for the proposed soft-switching SEPIC. From Figure 16, it can be seen that the auxiliary switch (M2) also has a ZCS feature and low EMI noise. The experimental efficiency of the proposed multi-output sources SEPIC with soft-switching and hard-switching techniques are obtained in Figure 17. From which it can be seen that the maximum efficiency with soft-switching techniques can be as high as 90%. Compared with the hard-switching techniques, the proposed multi-output sources SEPIC with soft-switching techniques has low switching losses, low EMI, and high conversion efficiency.

6. Conclusions

In this paper, the proposed soft-switching SEPIC with multi-output sources has been built and implemented. It uses a soft-switching cell with flyback-type to implement the features of ZVS and ZCS under turn-on transitions for the main switch (M1) and the auxiliary switch (M2). Therefore, the switching losses and EMI of the main and auxiliary switches can be reduced, and the efficiency can be increased. In addition, to apply the voltage ratios of the transformers (Tr1 and Tr2), the proposed soft-switching SEPIC has multi-output sources with step-up/down voltage functions. Therefore, the utility of the proposed soft-switching SEPIC can be increased. The simulated and experimental results have verified that the proposed soft-switching SEPIC with multi-output sources is relatively suitable for renewable energy systems.

Acknowledgments

This work was supported by the Ministry of Science and Technology, Taiwan, under Grant No. MOST 105-2221-E-167-023.

Author Contributions

All of the authors contributed to the publication of this paper. Cheng-Tao Tsai wrote the paper; Jye-Chau Su edited the manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Topology of conventional SEPIC (single-ended-primary-inductance converter).
Figure 1. Topology of conventional SEPIC (single-ended-primary-inductance converter).
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Figure 2. Experimental results of the power switch (Metal-oxide-semiconductor-field-effect transistor, MOSFET) with hard-switching conditions: (a) at turn-on and turn-off transitions; (b) extended waveforms of high turn-on loss and high electromagnetic interference (EMI); (c) extended waveforms of high turn-off loss and high EMI.
Figure 2. Experimental results of the power switch (Metal-oxide-semiconductor-field-effect transistor, MOSFET) with hard-switching conditions: (a) at turn-on and turn-off transitions; (b) extended waveforms of high turn-on loss and high electromagnetic interference (EMI); (c) extended waveforms of high turn-off loss and high EMI.
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Figure 3. Switching loci of hard switching and soft switching for a power switch.
Figure 3. Switching loci of hard switching and soft switching for a power switch.
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Figure 4. Illustration of ZVS (zero-voltage-switching) and ZCS (zero-current-switching) for a power switch: (a) ZVS turn-on and turn-off transitions; (b) ZCS turn-on and turn-off transitions.
Figure 4. Illustration of ZVS (zero-voltage-switching) and ZCS (zero-current-switching) for a power switch: (a) ZVS turn-on and turn-off transitions; (b) ZCS turn-on and turn-off transitions.
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Figure 5. Illustration of the power switch in parallel with an extra capacitor.
Figure 5. Illustration of the power switch in parallel with an extra capacitor.
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Figure 6. Illustration of the ZCS turn-off with an external snubber circuit.
Figure 6. Illustration of the ZCS turn-off with an external snubber circuit.
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Figure 7. Topology of the soft-switching SEPIC with multi-output sources.
Figure 7. Topology of the soft-switching SEPIC with multi-output sources.
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Figure 8. Illustration of the switch current, voltage, and power waveforms.
Figure 8. Illustration of the switch current, voltage, and power waveforms.
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Figure 9. Current and voltage waveforms of the key components and the driving signal switches (M1 and M2) for the proposed soft-switching SEPIC.
Figure 9. Current and voltage waveforms of the key components and the driving signal switches (M1 and M2) for the proposed soft-switching SEPIC.
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Figure 10. Equivalent circuits of the soft-switching SEPIC with multi-output sources. (a) Mode 1; (b) Mode 2; (c) Mode 3; (d) Mode 4; (e) Mode 5; (f) Mode 6; (g) Mode 7.
Figure 10. Equivalent circuits of the soft-switching SEPIC with multi-output sources. (a) Mode 1; (b) Mode 2; (c) Mode 3; (d) Mode 4; (e) Mode 5; (f) Mode 6; (g) Mode 7.
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Figure 11. Topology of an equivalent power converter with a soft-switching cell.
Figure 11. Topology of an equivalent power converter with a soft-switching cell.
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Figure 12. Topology of a conventional SEPIC with an inductor-type ZVS-ZCS cell.
Figure 12. Topology of a conventional SEPIC with an inductor-type ZVS-ZCS cell.
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Figure 13. Illustration of two topologies for the proposed converter: (a) SEPIC-flyback topology; (b) flyback topology.
Figure 13. Illustration of two topologies for the proposed converter: (a) SEPIC-flyback topology; (b) flyback topology.
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Figure 14. (a) 3-D plots of the minimum magnetizing inductance (Lm1) of the transformer (Tr1) as a function of the output current (Io1) under different input voltages for achieving ZVS and ZCS features; (b) a partial plot showing the ZVS and ZCS region versus the output current (Io1) at VS = 60 V.
Figure 14. (a) 3-D plots of the minimum magnetizing inductance (Lm1) of the transformer (Tr1) as a function of the output current (Io1) under different input voltages for achieving ZVS and ZCS features; (b) a partial plot showing the ZVS and ZCS region versus the output current (Io1) at VS = 60 V.
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Figure 15. Voltage and current waveforms of the main switch (M1): (a) simulated results (VDS: 50 V/div; iDS: 1 A/div; Time: 5 μs/div); (b) experimental results (VDS: 100 V/div; iDS: 1 A/div; Time: 2 μs/div).
Figure 15. Voltage and current waveforms of the main switch (M1): (a) simulated results (VDS: 50 V/div; iDS: 1 A/div; Time: 5 μs/div); (b) experimental results (VDS: 100 V/div; iDS: 1 A/div; Time: 2 μs/div).
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Figure 16. Voltage and current waveforms of the auxiliary switch (M2): (a) simulated results (VDS: 100 V/div; iDS: 0.5 A/div; Time: 5 μs/div); (b) experimental results (VDS: 100 V/div; iDS: 0.5 A/div; Time: 2 μs/div).
Figure 16. Voltage and current waveforms of the auxiliary switch (M2): (a) simulated results (VDS: 100 V/div; iDS: 0.5 A/div; Time: 5 μs/div); (b) experimental results (VDS: 100 V/div; iDS: 0.5 A/div; Time: 2 μs/div).
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Figure 17. Efficiency of the proposed multi-output sources SEPIC with soft-switching and hard-switching techniques under full load condition.
Figure 17. Efficiency of the proposed multi-output sources SEPIC with soft-switching and hard-switching techniques under full load condition.
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Tsai, C.-T.; Su, J.-C. A Soft-Switching SEPIC with Multi-Output Sources. Electronics 2017, 6, 35. https://doi.org/10.3390/electronics6020035

AMA Style

Tsai C-T, Su J-C. A Soft-Switching SEPIC with Multi-Output Sources. Electronics. 2017; 6(2):35. https://doi.org/10.3390/electronics6020035

Chicago/Turabian Style

Tsai, Cheng-Tao, and Jye-Chau Su. 2017. "A Soft-Switching SEPIC with Multi-Output Sources" Electronics 6, no. 2: 35. https://doi.org/10.3390/electronics6020035

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