Design of a Buck-Boost DC-DC Converter
Added on 2023-06-15
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Design of a buck-boost DC-DC Converter 1
DESIGN OF A BUCK BOOST DC-DC CONVERTER
1
DESIGN OF A BUCK BOOST DC-DC CONVERTER
1
Design of a buck-boost DC-DC Converter 2
SUMMARY
For a switching power supply, it is composed of the control circuit and power stage. The
power stages carry out the key power conversion to the output voltage from the input supply and
this constitutes the filter at the output and switches. This design report will basically focus on the
design of buck-boost converter for switched mode power supply. The in-depth operation of this
DC-DC converter works in both discontinuous and continuous mode which will actually be
shown in this article.
2
SUMMARY
For a switching power supply, it is composed of the control circuit and power stage. The
power stages carry out the key power conversion to the output voltage from the input supply and
this constitutes the filter at the output and switches. This design report will basically focus on the
design of buck-boost converter for switched mode power supply. The in-depth operation of this
DC-DC converter works in both discontinuous and continuous mode which will actually be
shown in this article.
2
Design of a buck-boost DC-DC Converter 3
TABLE OF CONTENTS
ACKNOWLEDGMENTS...............................................................................................................2
SUMMARY.....................................................................................................................................2
INTRODUCTION...........................................................................................................................6
Buck-Boost Converters....................................................................................................................6
Schematic diagram of the buck-boost converter..........................................................................7
Buck-Boost Steady-State Continuous Conduction Mode Analysis...........................................11
Buck-Boost Steady-State discontinuous Conduction Mode Analysis.......................................13
SPECIFICATION..........................................................................................................................14
DESIGN PARAMETERS.............................................................................................................15
DESCRIPTION OF DESIGN........................................................................................................15
Calculation of the Duty Cycle....................................................................................................15
Buck mode.................................................................................................................................16
Boost mode................................................................................................................................16
Selection of input capacitor........................................................................................................17
Selection of output capacitor......................................................................................................17
Inductor Selection......................................................................................................................18
Buck Mode.................................................................................................................................18
Boost mode................................................................................................................................19
Calculation of maximum switching current...............................................................................19
Buck Mode.................................................................................................................................19
Boost Mode................................................................................................................................20
Output voltage setting................................................................................................................ 21
MOSFET selection for the Buck-boost converter......................................................................22
3
TABLE OF CONTENTS
ACKNOWLEDGMENTS...............................................................................................................2
SUMMARY.....................................................................................................................................2
INTRODUCTION...........................................................................................................................6
Buck-Boost Converters....................................................................................................................6
Schematic diagram of the buck-boost converter..........................................................................7
Buck-Boost Steady-State Continuous Conduction Mode Analysis...........................................11
Buck-Boost Steady-State discontinuous Conduction Mode Analysis.......................................13
SPECIFICATION..........................................................................................................................14
DESIGN PARAMETERS.............................................................................................................15
DESCRIPTION OF DESIGN........................................................................................................15
Calculation of the Duty Cycle....................................................................................................15
Buck mode.................................................................................................................................16
Boost mode................................................................................................................................16
Selection of input capacitor........................................................................................................17
Selection of output capacitor......................................................................................................17
Inductor Selection......................................................................................................................18
Buck Mode.................................................................................................................................18
Boost mode................................................................................................................................19
Calculation of maximum switching current...............................................................................19
Buck Mode.................................................................................................................................19
Boost Mode................................................................................................................................20
Output voltage setting................................................................................................................ 21
MOSFET selection for the Buck-boost converter......................................................................22
3
Design of a buck-boost DC-DC Converter 4
Design evaluation.......................................................................................................................24
Explanation of the operation of the above design..................................................................24
DISCUSSION................................................................................................ 26
CONCLUSION.............................................................................................. 28
REFERENCES.............................................................................................. 29
APPENDICES.............................................................................................. 30
4
Design evaluation.......................................................................................................................24
Explanation of the operation of the above design..................................................................24
DISCUSSION................................................................................................ 26
CONCLUSION.............................................................................................. 28
REFERENCES.............................................................................................. 29
APPENDICES.............................................................................................. 30
4
Design of a buck-boost DC-DC Converter 5
List of Figures
Fig 1: Block diagram of DC/DC regulator.....................................................................................5
Fig 2: Buck-Boost Power Stage Schematic.....................................................................................6
Fig 3: Buck-Boost Power Stage Schematic from multism..............................................................6
Fig 3: Buck-Boost Power Stage Schematic from multism..............................................................7
Fig 4: Showing Continuous Mode Buck-Boost Power Stage Waveforms......................................8
Fig 5: Showing discontinuous Current Mode..................................................................................9
Fig 6: Showing the Buck-boost converter showing the output voltage.........................................16
Fig 7: Showing the Buck-boost converter showing the output current.........................................16
Fig 8: Showing the waveform of the buck-boost DC/DC converter.............................................17
5
List of Figures
Fig 1: Block diagram of DC/DC regulator.....................................................................................5
Fig 2: Buck-Boost Power Stage Schematic.....................................................................................6
Fig 3: Buck-Boost Power Stage Schematic from multism..............................................................6
Fig 3: Buck-Boost Power Stage Schematic from multism..............................................................7
Fig 4: Showing Continuous Mode Buck-Boost Power Stage Waveforms......................................8
Fig 5: Showing discontinuous Current Mode..................................................................................9
Fig 6: Showing the Buck-boost converter showing the output voltage.........................................16
Fig 7: Showing the Buck-boost converter showing the output current.........................................16
Fig 8: Showing the waveform of the buck-boost DC/DC converter.............................................17
5
Design of a buck-boost DC-DC Converter 6
INTRODUCTION
Buck-boost is a DC/ DC converter which is a topology which comprises the two
topologies (boost and buck). The boost DC regulator is a step up type which steps up voltage
and stepping down current from the supply to the load (output) at the same time. The buck DC –
to- DC converter is a step-down regulator which steps down the voltage and step up the current
from the supply to the output (load) at the same time. Therefore using buck-boost converters is
employed as a way of generating various voltage points from a sole DC voltage supply to be fed
to diverse sub-circuits in the device (Rogers, 2012).
Alternatively, DC voltage delivered by rectifier has relatively higher ripples voltage and
not stable enough, hence it is not appropriate in several devices. Buck-boost converters are used
for attenuation of the ripples irrespective of variation in the input voltage or load current. Figure
1 below shows a block diagram of a general DC/DC regulator that has two key blocks; power
processor part and feedback control (Loinovici, 2013). The feedback control part detects the
voltage from the output and amends the transfer of power through producing counteractive
control signals to stablalise the voltage at the output (Garcia, 2010).
Fig 1: Block diagram of DC/DC regulator
Buck-Boost Converters
The most common switching topography employed are the buck, boost and the buck-
boost regulator of where the trio are DC-DC regulator (Green, 2012). Nevertheless, lonely
sources of these non-lonely topologies. These topologies defines how the connection of output
6
INTRODUCTION
Buck-boost is a DC/ DC converter which is a topology which comprises the two
topologies (boost and buck). The boost DC regulator is a step up type which steps up voltage
and stepping down current from the supply to the load (output) at the same time. The buck DC –
to- DC converter is a step-down regulator which steps down the voltage and step up the current
from the supply to the output (load) at the same time. Therefore using buck-boost converters is
employed as a way of generating various voltage points from a sole DC voltage supply to be fed
to diverse sub-circuits in the device (Rogers, 2012).
Alternatively, DC voltage delivered by rectifier has relatively higher ripples voltage and
not stable enough, hence it is not appropriate in several devices. Buck-boost converters are used
for attenuation of the ripples irrespective of variation in the input voltage or load current. Figure
1 below shows a block diagram of a general DC/DC regulator that has two key blocks; power
processor part and feedback control (Loinovici, 2013). The feedback control part detects the
voltage from the output and amends the transfer of power through producing counteractive
control signals to stablalise the voltage at the output (Garcia, 2010).
Fig 1: Block diagram of DC/DC regulator
Buck-Boost Converters
The most common switching topography employed are the buck, boost and the buck-
boost regulator of where the trio are DC-DC regulator (Green, 2012). Nevertheless, lonely
sources of these non-lonely topologies. These topologies defines how the connection of output
6
Design of a buck-boost DC-DC Converter 7
inductor, switches, and output capacitor are done (Silva, 2016). Apiece topology has exceptional
stuffs. These comprise conversion the stable-state voltage ratios, the chatracter of the output and
input currents, and the properties of the output voltage ripple (Xi, 2012) . Electronic engineers
select the buck-boost power stage since the voltage at the output is reversed from the output and
input voltage can be either lower or higher than the voltage at the input (Kennedy, 2013). The
topology acquires its appellation from generating a voltage at the output which can be (buck
power stage) or lower (boost power stage) in amount than the voltage at the input (Siu, 2011).
Nonetheless, the voltage at the output is reversed in polarity from the input voltage (Hauke,
2011).
Schematic Diagram of the buck boost converter
The typical layout of the buck boost converter is shown in the below circuit. The
convertor acts as the regulating device. In this design, the configuration of the various
components was shown. Functional details for those components are calculated by using the
various formulas. The circuit consists of one master switch in it. It controls the current flow
through the converter. Then the inductor was placed parallel to the supply line. And also the
capacitor as well as the resistor in the convertor also arranged in the same configurations. Then,
in the below circuit the current direction for the current flow across the various components was
shown. In the inductor the current flow in the same direction of the supply current. But in the
capacitor and resistor, the current flows in opposite direction to the supply voltage. One diode is
connected in-between Inductor and capacitor. It acts as the one way switch.
Figure 1 the circuit layout of buck boost converter
7
inductor, switches, and output capacitor are done (Silva, 2016). Apiece topology has exceptional
stuffs. These comprise conversion the stable-state voltage ratios, the chatracter of the output and
input currents, and the properties of the output voltage ripple (Xi, 2012) . Electronic engineers
select the buck-boost power stage since the voltage at the output is reversed from the output and
input voltage can be either lower or higher than the voltage at the input (Kennedy, 2013). The
topology acquires its appellation from generating a voltage at the output which can be (buck
power stage) or lower (boost power stage) in amount than the voltage at the input (Siu, 2011).
Nonetheless, the voltage at the output is reversed in polarity from the input voltage (Hauke,
2011).
Schematic Diagram of the buck boost converter
The typical layout of the buck boost converter is shown in the below circuit. The
convertor acts as the regulating device. In this design, the configuration of the various
components was shown. Functional details for those components are calculated by using the
various formulas. The circuit consists of one master switch in it. It controls the current flow
through the converter. Then the inductor was placed parallel to the supply line. And also the
capacitor as well as the resistor in the convertor also arranged in the same configurations. Then,
in the below circuit the current direction for the current flow across the various components was
shown. In the inductor the current flow in the same direction of the supply current. But in the
capacitor and resistor, the current flows in opposite direction to the supply voltage. One diode is
connected in-between Inductor and capacitor. It acts as the one way switch.
Figure 1 the circuit layout of buck boost converter
7
Design of a buck-boost DC-DC Converter 8
Switch closed state
When the switch is closed, then the current will not flow directly to the diode. The
current first flows through the inductor L, then to the capacitor C, and Resistor R. In this stage
the diode is in reverse biased state. The current through the inductor is represented as iL, the
current through the capacitor is iC, and the output current Io is measured across resistor R. The
input voltage is represented as Vin and Output voltage is represented as Vo. When the switch is
in ON condition, the inductor voltage equals to the Input voltage. Then the energy is stored in an
Inductor gets increases. Then the capacitor maintains the constant voltage.
Here, q= 1 switch –ON = Diode Reverse biased.
Figure 2 the circuit in closed switch state
Switch open state
The below figure consists of a closed switch circuit of the buck-boost converter. When
the switch is in OFF condition, the inductor voltage equals to the negative value of Output
voltage. Then the energy is stored in an Inductor gets decreases. Then the capacitor maintains
the constant voltage. In the open state of the switch, the current flows through the Inductor,
capacitor, and resistor. The flow of current is shown in below circuit. In this stage, the diode is
forward biased.
Here q=0 switch – off = Diode forward biased
8
Switch closed state
When the switch is closed, then the current will not flow directly to the diode. The
current first flows through the inductor L, then to the capacitor C, and Resistor R. In this stage
the diode is in reverse biased state. The current through the inductor is represented as iL, the
current through the capacitor is iC, and the output current Io is measured across resistor R. The
input voltage is represented as Vin and Output voltage is represented as Vo. When the switch is
in ON condition, the inductor voltage equals to the Input voltage. Then the energy is stored in an
Inductor gets increases. Then the capacitor maintains the constant voltage.
Here, q= 1 switch –ON = Diode Reverse biased.
Figure 2 the circuit in closed switch state
Switch open state
The below figure consists of a closed switch circuit of the buck-boost converter. When
the switch is in OFF condition, the inductor voltage equals to the negative value of Output
voltage. Then the energy is stored in an Inductor gets decreases. Then the capacitor maintains
the constant voltage. In the open state of the switch, the current flows through the Inductor,
capacitor, and resistor. The flow of current is shown in below circuit. In this stage, the diode is
forward biased.
Here q=0 switch – off = Diode forward biased
8
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