Switch Mode Power Supply (SMPS) - Basics.ppt
UdayaShankarBK1
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Mar 01, 2025
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About This Presentation
Switch Mode Power Supplies
Slide Content
Switchmode Power Supplies
Power Supplies
– An Overview
Power Supplies
– An Overview
This presentation will discuss about Power
converters
•Power conversion from high voltage AC (input)
supplies to low voltage DC(output)
•
One DC voltage(input) to another DC voltage(ouput)
•Output > Input or Output < Input
but, Input Power > Output Power
(.... + losses in converter)
converters
•Power conversion from high voltage AC (input)
supplies to low voltage DC(output)
•
One DC voltage(input) to another DC voltage(ouput)
•Output > Input or Output < Input
but, Input Power > Output Power
(.... + losses in converter)
Types of Regulators
Linear Regulators
Switching Regulators
Linear Regulators
Switching Regulators
Linear Regulators
a simple, inexpensive circuit that produces a
quiet output voltage less than the input
voltage
Switching Regulators
more complex circuit that’s efficient,
compact, and versatile in its input/output
voltages
a simple, inexpensive circuit that produces a
quiet output voltage less than the input
voltage
Switching Regulators
more complex circuit that’s efficient,
compact, and versatile in its input/output
voltages
Linear Regulators
-Simple, inexpensive
+ Electrically “quiet” pure DC output
+ Vout < Vin
+ Poor Efficiency
-Can be physically large
Step Down
Or
Step Up
Transformer
Rectifier Linear
Regulator
DC o/p
AC i/p Vi
n
Vo
Classical Linear Regulator
-Simple, inexpensive
+ Electrically “quiet” pure DC output
+ Vout < Vin
+ Poor Efficiency
-Can be physically large
Step Down
Or
Step Up
Transformer
Rectifier Linear
Regulator
DC o/p
AC i/p Vi
n
Vo
Classical Linear Regulator
Switchmode Regulators
+Wide range of input voltages
+Multiple output voltages possible
+High Efficiency
+Compact
- Complex, more expensive
- Electrically “noisy” (not pure DC)
Rectifier Switching
Regulator
DC o/pAC i/p
Vi
n
Vo
Typical SMPS
+Wide range of input voltages
+Multiple output voltages possible
+High Efficiency
+Compact
- Complex, more expensive
- Electrically “noisy” (not pure DC)
Rectifier Switching
Regulator
DC o/pAC i/p
Vi
n
Vo
Typical SMPS
Switchmode Topologies
A few types…Non isolated
Buck :output DC< input DC
Application:
•To Produce a lower O/P voltage than DC I/P voltage
– Step down converter.
•Regulating DC power supplies.
•As a replacement for the Linear regulator – avoiding
high power dissipating series pass transistor
A few types…Non isolated
Buck :output DC< input DC
Application:
•To Produce a lower O/P voltage than DC I/P voltage
– Step down converter.
•Regulating DC power supplies.
•As a replacement for the Linear regulator – avoiding
high power dissipating series pass transistor
Topologies
Basic buck converter:Basic buck converter:
Vo = D * Vin
D = Ton / T
where T=Ton+Toff
Basic buck converter:Basic buck converter:
Vo = D * Vin
D = Ton / T
where T=Ton+Toff
Configuration depending on state of
switch (Buck)
switch (Buck)
Topologies
Boost : output DC > input DC
Application:
In battery operated devices, where the required
operational voltage is more than battery voltage
To achieve holdup time in critical embedded systems
Where high voltages are required e.g., TV picture
tubes, Cathode ray tube.
Boost : output DC > input DC
Application:
In battery operated devices, where the required
operational voltage is more than battery voltage
To achieve holdup time in critical embedded systems
Where high voltages are required e.g., TV picture
tubes, Cathode ray tube.
Topologies
Basic boost converter:Basic boost converter:
D = Ton / T
where T=Ton+Toff
Basic boost converter:Basic boost converter:
D = Ton / T
where T=Ton+Toff
Configuration depending on state of
switch (Boost)
switch (Boost)
Topologies
Buck-boost (Inverting)
- an output voltage is generated opposite in polarity to the
input.
D = Ton / T
where T=Ton+Toff
Buck-boost (Inverting)
- an output voltage is generated opposite in polarity to the
input.
D = Ton / T
where T=Ton+Toff
Configuration depending on state of
switch (Buck-Boost)
switch (Buck-Boost)
Isolated Converters - Requires
Transformer
The transformer functions as:
An isolation between the input and output
circuit.
Energy storage element.
Stepping up or down.
Providing Multiple outputs.
Transformer
The transformer functions as:
An isolation between the input and output
circuit.
Energy storage element.
Stepping up or down.
Providing Multiple outputs.
Switchmode Topologies
(Isolated)
Flyback:
- an output voltage that is less than or
greater than the input can be generated,
as well as multiple outputs.
(Isolated)
Flyback:
- an output voltage that is less than or
greater than the input can be generated,
as well as multiple outputs.
Topologies
Forward:
an output voltage that is less than the
input can be generated.
Forward:
an output voltage that is less than the
input can be generated.
Topologies
Push-Pull:
A two-transistor converter that is
especially efficient at low input voltages.
Push-Pull:
A two-transistor converter that is
especially efficient at low input voltages.
Topologies
Half-Bridge:
A two-transistor converter used in many
off-line applications.
Half-Bridge:
A two-transistor converter used in many
off-line applications.
Topologies
Full-Bridge:
A four-transistor converter (usually used in off-
line designs) that can generate the highest
output power of all the types listed.
Full-Bridge:
A four-transistor converter (usually used in off-
line designs) that can generate the highest
output power of all the types listed.
Modes of operation in converters:
Converters may be operated in two modes, according
to the current in its main magnetic component
[inductor or transformer]
Discontinuous mode:
- the current fluctuates during the cycle , goes down to
zero at the end of each cycle.
Continuous mode :
- the current fluctuates but never goes down to zero.
Converters may be operated in two modes, according
to the current in its main magnetic component
[inductor or transformer]
Discontinuous mode:
- the current fluctuates during the cycle , goes down to
zero at the end of each cycle.
Continuous mode :
- the current fluctuates but never goes down to zero.
Modes of operation in converters:
Discontinuous mode of operation:
Secondary peak currents are higher – I
2
R Losses, Skin effect
losses
Bigger I/P filter to reduce EMI problems
O/P capacitors to be large enough to handle larger ripple
current rating
Responds faster for the load variation and I/P voltage
variations
Discontinuous mode of operation:
Secondary peak currents are higher – I
2
R Losses, Skin effect
losses
Bigger I/P filter to reduce EMI problems
O/P capacitors to be large enough to handle larger ripple
current rating
Responds faster for the load variation and I/P voltage
variations
Modes of operation in converters:
Continuous mode of operation:
Low conduction losses due to lower currents.
Requires fast recovery O/P rectifier diodes – Higher cost
Continuous mode of operation:
Low conduction losses due to lower currents.
Requires fast recovery O/P rectifier diodes – Higher cost
Control techniques in converters:
Voltage Mode Control:
The difference between the desired and actual
output voltages (error) controls the voltage
applied across the inductor.
Current Mode Control:
The difference between the desired and actual
output voltages (error) controls the peak
inductor current.
Voltage Mode Control:
The difference between the desired and actual
output voltages (error) controls the voltage
applied across the inductor.
Current Mode Control:
The difference between the desired and actual
output voltages (error) controls the peak
inductor current.
Control techniques in converters:
Voltage Mode Control:
Advantages:
-A single feedback loop is easier to design and analyze.
-Less noise, Less power loss, More resolution.
-A low-impedance power output provides better cross-
regulation for multiple output supplies.
-
Provides Stable Operation.
Voltage Mode Control:
Advantages:
-A single feedback loop is easier to design and analyze.
-Less noise, Less power loss, More resolution.
-A low-impedance power output provides better cross-
regulation for multiple output supplies.
-
Provides Stable Operation.
Control techniques in converters:
Disadvantages:
- Any change in line or load must first be sensed as an
output change and then corrected by the feedback
loop. This usually means slow response.
- Compensation is further complicated by the fact that
the loop gain varies with input voltage
Disadvantages:
- Any change in line or load must first be sensed as an
output change and then corrected by the feedback
loop. This usually means slow response.
- Compensation is further complicated by the fact that
the loop gain varies with input voltage
Control techniques in converters:
Current Mode Control:
Advantages:
- Responds immediately to input voltage changes.
- Since the Error Amplifier is used to command an output
current rather than voltage, the effect of the output
inductor is minimized .This allows both simpler
compensation and a higher gain bandwidth over a
comparable voltage-mode circuit.
Current Mode Control:
Advantages:
- Responds immediately to input voltage changes.
- Since the Error Amplifier is used to command an output
current rather than voltage, the effect of the output
inductor is minimized .This allows both simpler
compensation and a higher gain bandwidth over a
comparable voltage-mode circuit.
Control techniques in converters:
-Additional benefits with current-mode circuits include
inherent pulse-by-pulse current limiting.
-Disadvantages:
- There are two feedback loops, making circuit analysis more
difficult.
- The control loop becomes unstable at duty cycles above
50%.
-Additional benefits with current-mode circuits include
inherent pulse-by-pulse current limiting.
-Disadvantages:
- There are two feedback loops, making circuit analysis more
difficult.
- The control loop becomes unstable at duty cycles above
50%.
ThanksThanks
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