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Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3350-3354 3350  
 

www.etasr.com Jayaswal & Palwalia: Performance Analysis of Non-Isolated DC-DC Buck Converter Using Resonant … 

 

Performance Analysis of Non-Isolated DC-DC Buck 

Converter Using Resonant Approach 
 

Kuldeep Jayaswal 

Department of Electrical Engineering 

Rajasthan Technical University  

Kota, India 

kuldeep12555@gmail.com 

Dheeraj Kumar Palwalia 

Department of Electrical Engineering 

Rajasthan Technical University  

Kota, India 

dheerajpalwalia@gmail.com 
 

 

Abstract—DC-DC converters preserve or control the output DC 

voltage. Due to parasitic constituents such as leakage capacitance 

of both diode and inductor, and transformer leakage inductance, 

DC-DC converters mostly operate on rigid switching conditions 

which result in high switching losses. These parasitic constituents 

affect the dc-dc converter’s operational reliability, instigate 

electromagnetic interference issues and limit the converter’s 

operation at higher frequency operations. In this paper, resonant 

or soft-switch approach has been employed to improve the 

operating performance and design-oriented principle 

investigations have been carried out for overcoming the issues of 

parasitic constituents in 24-12V DC-DC step-down (buck) 

converter. This paper divulges the analysis and Matlab 

Simulation results for 24-12V buck converter based on resonant 

or soft-switching approach. 

Keywords—operational reliability; DC-DC converter; resonant 

converter; Matlab simulation; step-down converter 

I. INTRODUCTION 

DC-DC conversion technologies are an important subject of 
research in the power engineering and drives area. These 
devices are electronic platforms used to customize DC electric 
voltage efficiently [1]. These converters are mostly used for 
changing the different voltage level [2-5]. Mainstream PWM 
converters do not work on soft-switch approach, they mostly 
operate on hard switching conditions. Semiconductor devices 
suffer from switching losses and electro-magnetic interference 
problems during switching-on and off which results in poor 
converter performance [5-6]. There are various factors which 
are accountable of switching loss like capacitance of both 
diode and switch [7-11]. This paper shows the soft-
switch/resonant approach based on null voltage switching 
operation for reduction of all uncertainties related to customary 
DC-DC buck converter. 

II. NON-ISOLATED DC-DC CONVERTER TOPOLOGIES AND 

RESONANT/SOFT-SWITCH APPROACH  

A. The Concept Behind the Requirment of Resonant Approach 

DC-DC semiconductor devices like BJT, MOSFET or 
IGBT work as a switch at required frequency (f) [12]. The 
elementary circuit topologies of non-isolated dc-dc converters 
are shown in Figure 1 [13-19]. The voltage and current 

waveforms of the switch may have different shapes. As the 
voltage and current across the switch are not zero during 
switching times, there will be switching losses. Due to this, the 
switching frequency is bounded in pulse-width modulating 
converters. If the frequency is increased, then high 
electromagnetic interference problems will occur [2]. High 
stress will be on device during switching times due to high 
spikes in switch voltage and current. That’s why such a 
switching results to low switching losses. 

 

 
Fig. 1.  Non-isolated DC-DC converter topologies without resonant/soft-
switch approach 

In this paper, the buck non-isolated topology has been used 
as a principal platform to revamp performance and operational 
reliability of the converter. For this purpose, zero voltage 
switch operational approach has been used via appropriate 
placement of resonant switches. MOSFETs and IGBTs are 
mostly used as a switch in electronic conversions where at a 
particular time period they have to operate either in fully on or 
off condition. Being a current controlled device, MOSFETs are 
much faster in switching operation in comparison to BJT [8]. 
Thus, these devices are most eligible to work at higher 
switching frequencies.  



Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3350-3354 3351  
 

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B. Switch Configuration Concept for ZVS Approach 

Switching losses are related to the switching frequency fs, 
and these losses limit the maximum switching frequency. The 
energy reserved in output capacitance Co of switch just before 
the transistor turns on is given as 

��� = ����� 	� 2⁄     (1) 
where ����=transistor voltage during off-instant.  

When the switch turns on, the energy imposed on the 
switch, causes transistor switching loss 

�
�(���) = ����� 	��
 2⁄    (2) 
In this approach, a special switch configuration has been 

used which is made up with combinations of two different 
resonant elements with an anti-parallel diode. Figure 2 shows 
the switch configuration for resonant or smooth switching [14-
19]. Here a capacitor is coupled in counterpart with SW and 
resonant inductor in series. In this paper, resonant or zero 
voltage, switch operational approach has been used for the 
analysis of 24-12V DC-DC step-down converter. According to 
this when the switch is on, the voltage at the switch becomes 
zero, and that’s why the energy reserved in the output 
capacitance of switch is null during turn this time. Hence, the 
switching on losses becomes zero, which provides smooth 
efficient operation at high frequencies and results in the 
reduction in the amplitude of the converters. During this 
period, the above mentioned switch configuration plays a 
crucial role. In this, the resonant capacitor will resonate to null 
voltage before SW is turned-on. On the other hand, when the 
switch is turned-off, a little time is required to charge the 
resonant capacitor and hence the voltage over the SW is not 
increased abruptly. So, there is a very small overlapping 
between the SW current and voltage. So, the zero voltage 
switch operation is achieved. The main idea behind this 
approach is the fact that these soft-switch converter topologies 
absorb different parasitic components, like transformer’s 
leakage inductance, output capacitance of both transistor and 
diode. Figure 3, exhibits the proposed topology for non-isolated 
buck (step-down) converter based on resonant technique. 
Initially the switch remains in off situation during this instant 
current across switch is null but the voltage is not.  

 
Fig. 2.  ZVS approach based on resonant switch configuration 

 
Fig. 3.  Topology for non-isolated buck converter based on zero voltage 

switch/resonant approach 

During the switch-on, the voltage is forced to be zero and 
the current is a little-bit delayed so that it will start to lift after 
the zero voltage as shown in Figure 4(b). In zero current switch 
approach, a switch is off during zero current. The voltage 
through it might be zero but the current across the device is not. 
Voltage is granted to lift after current becomes zero as 
illustrated in Figure 4(c). 

 
Fig. 4.  (a) Firm-switching converter incident, (b) zero or null Voltage 

switching case, (c) zero or null current switching case 

III. ANALYSIS OF DC-DC BUCK CONVERTER WITH AND 

WITHOUT SOFT SWITCH APPROACH 

Figure 5 shows the conventional buck or step-down 
converter without resonant or soft switch approach, which is a 
cheap electronic device used to obtain reduced voltage.  

 
Fig. 5.  DC-DC buck converter topology without resonant or soft switch 

approach 

The switch operation is regulated by a modulator and 
turned-on and off at duty ratio “D” and at required switching 
frequency �
 = 1/�. Closed loop control has been used for 
stable operation: 

�� = ��� ⇒ ��� ∕ (��� + ����) = ����
  (3) 
The operational strategy consists of two stages. At t=0, the 

switch is in ON state and the diode is in OFF state because VD 
=−VI. Further current across the inductor increases 
continuously due to voltage difference VL=VI–VO. At this time 
the current through the inductor and switch are both equal and 
energy is delivered to energy storage elements. In the second 
stage, at t=DT, the switch is in OFF state by gate driver, but 
during this time the inductor still has the previously stored 
current which turns the diode ON. During this instant, the 
voltage over the inductor is given as (–VO) and the voltage over 
the switch is given as (VI). That’s why IL decreases 
continuously with a slope of (–VO)/L. Input voltage is 
unplugged from the circuit and doesn’t transfer any energy to 
the storage elements. The average output voltage in the buck 
converter is given by (4), which does not depend on load [6]. 

�� ��⁄ = � ⇒ �� = ���   (4) 
The buck converter circuit based on the proposed approach 

is shown in Figure 8. 

Time  Time            Time 

(a)  (b)          (c) 

Power Loss 

Voltage Curve Voltage Curve 
Current Curve Current 

ZVS 

Switching 

Current 

ZCS Switching 

Conventional 
Conventional 

On 
Off 

Voltage 



Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3350-3354 3352  
 

www.etasr.com Jayaswal & Palwalia: Performance Analysis of Non-Isolated DC-DC Buck Converter Using Resonant … 

 

 

 

Fig. 6.  Circuit state & waveform for time interval 0 <t≤DT 

 

 

Fig. 7.  Circuit state for time interval DT<t≤T 

 

Fig. 8.  Buck topology based on resonant approach 

The current through the inductor L remains somewhat 
constant so energy storage element is modelled as current sink, 
 �. Table II, shows the analysis and operational process under 
four time segments, zero to t1, t1 to t2, t2 to t3 and finally t3 to T.. 
For simulating dc-dc converter with and without resonant 
approach, complete mathematical analysis has been done for 
the design of a 24V-12V converter through different parametric 
equations. The converter based on the proposed approach has 
been analyzed through parametric equations for 24V input and 
12V output for 100KHz and 1MHz. By considering the 
different level of currents, loss calculations have been made for 
both types of converter and final remarks have been obtained 
which are depicted in Figure15 that shows the reliable or 
efficient performance of the converter. 

TABLE I. PARAMETERIC EQUATIONS  

Parameters Used Expressions 

Transfer function for DC voltage !"	$� ≡ ��/�� = 1 − '
0.90
��

+ �, 
Characteristics impedance (Z0) -./ 	/⁄  or (0)1�=(1/./	/) 

Max. current across switch from 0 to DT 	 
2 = (∆45)/2	+	4� 
Quality factor (Q) 65/./0� 

Resonant frequency ‘f0’ 0.909*�,/(1-D) or �
/�� 
Device stress for ‘S’ and ‘D’ 

(	�
278) = 2	� 	&		 :;<= =  1	
	 $278 = 2	 1	 & 

	�$278 = 	��/	�� = 1/� 
Calculation of inductor’s value .> 65./?0�. 
Calculation of capacitor’s value 	> ?/650�. 
Max. voltage across switch 	�
2 (1 + !@AB ?⁄ ) 

 

IV. SIMULATION RESULTS 
 

A. Without Resonant/Soft-Switch Approach 

 

 

Fig. 9.  Current across inductor 

 
Fig. 10.  Output current of buck converter (current versus time) 

 

Fig. 11.  Output voltage (12V) of buck converter (voltage versus time) 



Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3350-3354 3353  
 

www.etasr.com Jayaswal & Palwalia: Performance Analysis of Non-Isolated DC-DC Buck Converter Using Resonant … 

 

TABLE II. OPERATIONAL PROCESS FOR NON-ISOLATED DC-DC BUCK CONVERTER USING RESONANT OR SOFT-SWITCH APPROACH 

Time 

interval 
Circuit models/States Response/Behavior Waveforms 

0<t≤t1 

(inductor 
charging 

time ) 

 

• Diode and Switch both are ON. 

• The Voltage over the switch, voltage over diode and 
current over the capacitor are zero. 

• Only voltage across resonant inductor is equal to input 
supply i.e. vLr=VI 

 

t1<t≤t2 

 

• Switch is ON and diode becomes OFF. 

• At this instant diode is reverse biased because 	@$ = −�� 
• In this duration switch and resonant inductor’s current 
become equal to output current. 

t2<t≤t3 

 

• Diode and switch are both OFF. 

• Switch current and diode current will be zero. 

• Further voltage across resonant inductor will also be 
zero. 

t3<t≤T 

 

• Diode is ON state and switch is OFF 

• Switch and diode current will be zero. 

• Further current across resonant inductor will be equal to 
the output current and voltage across resonant capacitor and 

switch voltage will be equal to supply voltage. 

 

B. With Resonant/Soft-Switch Approach 

 

Fig. 12.  Output current of buck converter via resonant/soft-switch approach 

 

 

Fig. 13.  Output voltage (12V) of buck converter via resonant/soft-switch 

 

 

Fig. 14.  Outputs of proposed buck converter using resonant/soft-switch approach 



Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3350-3354 3354  
 

www.etasr.com Jayaswal & Palwalia: Performance Analysis of Non-Isolated DC-DC Buck Converter Using Resonant … 

 

 

Fig. 15.  Plot between efficiency and output current  

IV. CONCLUSIONS 

In this paper, analysis has been done for transformer-less 
dc-dc buck converter topology with and without resonant 
approach. Pulse width modulating dc-dc converters operate on 
rigid switching conditions where voltages and currents show 
their rapid change from high to low value and vice-versa. 
Because of this, semiconductor devices cause switching loss 
problems during on and off states which affect the overall 
system performance. Basically these losses are caused by the 
capacitance of both diode and transistor. In this research paper, 
24-12V transformer-less dc-dc buck converter has been 
analyzed. Simulation results acquired for the proposed 
topology justified the soft-switch or resonant approach. This 
paper shows that if a capacitor is connected in counterpart with 
switch and a resonant inductor is connected in series with the 
switch, it absorbs the parasitic elements which provide smooth 
operation of conversion even on higher switching frequencies. 
Due to this topology, voltage is zero through the switch during 
switch-on. That’s why, the accumulated energy in output 
capacitance Co is reduced to zero. Hence, the switching on 
losses becomes zero, which improves the operational reliability 
of the dc-dc converter. It has been shown that resonant or zero 
voltage switch approach makes the buck converter more 
efficient in comparison to the conventional buck converter. It is 
also evident that as the current increases, efficiency decreases. 
So the resonant or soft switch approach plays a crucial role in 
improving the buck converter efficiency over custom switching 
buck converter which ultimately improves the performance of 
the converter. 

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88

90

92

94

96

98

100

1 2 3 4 5 6 7 8 9 10 11

ŋ
%

Output current

Efficency

Conventional Buck converter efficency

Proposed Buck converter efficency