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ECE101 – Week 01 and 02:

SEMICONDUCTOR
SWITCHES
DISCLAIMER
Fair use of a copyrighted work as defined in sec. 185 of RA 8293, which
states, “the fair use of a copyrighted work for criticism, comment, news reporting,
teaching including multiple copies for classroom use, scholarship, research, and
similar purposes is not an infringement of copyright.”

This PowerPoint Learning Material is prepared and compiled by Engr.
Raymart Mallari solely for students of Pamantasan ng Cabuyao (PnC) under the
College of Engineering enrolled in ECE101 for EcE course for AY 2023-24.
INTENDED LEARNING OUTCOMES
After this session, the students will be able to:
Differentiate semiconductor switches for specific applications
Describe characteristics of semiconductor switches and their
role in power supply systems
Explain the significance of passive components in power supply
circuits
SEMICONDUCTOR
SWITCHES
Semiconductor Switches
Solid-state devices are completely made from a solid material, and their
flow of charges is confined within it. The term “solid-state” is often used to
show the difference between the earlier technologies of vacuum and gas-
discharge tube devices and the exclusion of conventional electro-
mechanical devices (relays, switches, hard drives, and other devices with
moving parts).
TYPES
Power Diodes
A power diode has a P-I-N structure as compared to
the signal diode having a PN junction.
Structure - P-I-N structure, allowing for high reverse
voltage handling.
Forward Voltage Drop - Typically around 1V.
Reverse Recovery Time - Has a stored charge that
leads to a reverse recovery time when switching off.
Power Diodes
Applications
Used in rectifiers, voltage clampers, and voltage
multipliers.
Suitable for high-power applications due to their
ability to handle large currents and voltages.
MOSFET (Metal-Oxide-Semiconductor
Field-Effect Transistor)
Control - Voltage-controlled, operates
with majority carriers (unipolar).
Structure - Vertical channel structure
in power MOSFETs enhances power
handling.
Switching Speed - Fast switching
capabilities, affected by gate
capacitances.
MOSFET (Metal-Oxide-Semiconductor
Field-Effect Transistor)
Applications
Commonly used in power amplifiers,
switching power supplies, and
inverters.
Ideal for applications requiring high
efficiency and fast switching.
MOSFET (Metal-Oxide-Semiconductor
Field-Effect Transistor)
BJT (Bipolar Junction Transistor)
Structure - Three-layer, two-junction
device (NPN or PNP).
Performance - Lower input
capacitance compared to MOSFETs,
but slower response.
Saturation Voltage - Lower saturation
voltage over a wide temperature
range.
BJT (Bipolar Junction Transistor)
Applications
Used in high-voltage and high-current
applications, although less common
now due to the rise of IGBTs and
MOSFETs.
IGBT (Insulated Gate Bipolar
Transistor)
Combines the advantages of BJTs and
MOSFETs.
High Input Impedance - Like
MOSFETs, but can handle high
voltages like BJTs.
Switching Speed - Moderate switching
speed, slower than MOSFETs but
faster than BJTs.
IGBT (Insulated Gate Bipolar
Transistor)
Applications
Widely used in inverters, motor
drives, and power electronics
applications requiring high efficiency.
SCR (Silicon-Controlled Rectifier)
Control - Can only be turned on by a
gate signal; does not have a gate-
controlled turn-off capability.
Operation - Remains in the
conducting state until the anode
current falls below a certain threshold
(holding current).
Switching Speed - Typically operates
at low frequencies (around 60 Hz).
SCR (Silicon-Controlled Rectifier)
Applications
Commonly used in AC power control,
phase control, and rectification
applications.
GTO (Gate Turn-Off Thyristor):
Control - Can be turned on by a positive gate
current and turned off by a negative gate
current, allowing for more flexible control.
Switching Speed - Faster switching compared to
SCRs, typically operating at frequencies up to 5
kHz.
Voltage Drop - Generally has a higher voltage
drop than SCRs during operation.
GTO (Gate Turn-Off Thyristor):
Applications
Used in high-current and high-speed switching
applications, such as inverters and chopper
circuits.
MCT (MOS-Controlled Thyristor)
Control - Utilizes two MOSFETs for
turn-on and turn-off, allowing for
voltage-controlled operation.
Switching Speed - Comparable to
GTOs, with switching frequencies also
around 5 kHz.
Voltage Rating - Can handle high
voltage ratings, typically up to 4.5 kV.
MCT (MOS-Controlled Thyristor)
Suitable for capacitor discharge
applications, circuit breakers, and AC-
DC or AC-AC conversion, providing a
more efficient alternative to GTOs
due to simpler gate drive
requirements.
ECE101 – Week 03 and 04:

RECTIFIERS AND
PHASE-CONTROLLED
RECTIFIERS
DISCLAIMER
Fair use of a copyrighted work as defined in sec. 185 of RA 8293, which
states, “the fair use of a copyrighted work for criticism, comment, news reporting,
teaching including multiple copies for classroom use, scholarship, research, and
similar purposes is not an infringement of copyright.”

This PowerPoint Learning Material is prepared and compiled by Engr.
Raymart Mallari solely for students of Pamantasan ng Cabuyao (PnC) under the
College of Engineering enrolled in ECE101 for EcE course for AY 2023-24.
INTENDED LEARNING OUTCOMES
After this session, the students will be able to:
Determine ripple voltage impact on DC output quality
Describe phase control's role in output voltage regulation
Assess bridge rectifier efficiency and its effect on output ripple
DISCUSSION
Introduction
A rectifier is an electronic device that converts alternating current (AC) to
direct current (DC) by allowing current to flow in only one direction.
Introduction
Rectifiers are classified into two main types:
Uncontrolled Rectifiers: These rectifiers have a fixed output voltage that
cannot be controlled. They are further divided into half-wave and full-wave
rectifiers.
Controlled Rectifiers: These rectifiers have an adjustable output voltage
that can be controlled. They use devices like SCRs, MOSFETs, or IGBTs to
control the output. Controlled rectifiers are also classified as half-wave or
full-wave.
Introduction
Rectifiers are classified into two main types:
Uncontrolled Rectifiers: These rectifiers have a fixed output voltage that
cannot be controlled. They are further divided into half-wave and full-wave
rectifiers.
Controlled Rectifiers: These rectifiers have an adjustable output voltage
that can be controlled. They use devices like SCRs, MOSFETs, or IGBTs to
control the output. Controlled rectifiers are also classified as half-wave or
full-wave.
Half-wave Rectifiers
Use a single diode to convert only one half-cycle of the AC waveform to
DC
Output voltage is pulsating DC
Efficiency is low at around 40.6%
Ripple frequency is the same as the AC supply frequency
Half-wave Rectifiers
Full-wave Rectifiers
Use two diodes or a four-diode bridge configuration to convert both half-
cycles of the AC waveform to DC
Output voltage is also pulsating DC but with a higher frequency
Efficiency is higher at around 81.2%
Ripple frequency is twice the AC supply frequency
Full-wave Rectifiers
Full-wave Rectifiers
Filter Circuit
Ripple Factor (𝜸)
The ripple factor is the ratio between the RMS value of the AC voltage (on
the input side) and the DC voltage (on the output side) of the rectifier.

2
𝑉𝑟𝑚𝑠
𝛾= −1
𝑉𝑑𝑐
Efficiency (η)
Rectifier efficiency (η) is the ratio between the output DC power and the
input AC power.

𝑃𝑑𝑐
𝜂=
𝑃𝑎𝑐
Form Factor (FF)
The form factor is the ratio between RMS value and average value.

𝑅𝑀𝑆 𝑣𝑎𝑙𝑢𝑒
𝐹𝐹 =
𝐴𝑣𝑒𝑟𝑎𝑔𝑒 𝑣𝑎𝑙𝑢𝑒
Principles of Phase Control and Single-
Phase Phase-Controlled Rectifiers
Phase control is a technique used in controlled rectifiers to adjust the
output voltage by controlling the firing angle of the SCRs.
By varying the firing angle, the conduction period of the SCRs can be
controlled, allowing for a variable DC output.
Principles of Phase Control and Single-
Phase Phase-Controlled Rectifiers
ECE101 – Week 05:

SWITCH-MODE
POWER SUPPLY
DISCLAIMER
Fair use of a copyrighted work as defined in sec. 185 of RA 8293, which
states, “the fair use of a copyrighted work for criticism, comment, news reporting,
teaching including multiple copies for classroom use, scholarship, research, and
similar purposes is not an infringement of copyright.”

This PowerPoint Learning Material is prepared and compiled by Engr.
Raymart Mallari solely for students of Pamantasan ng Cabuyao (PnC) under the
College of Engineering enrolled in ECE101 for EcE course for AY 2023-24.
INTENDED LEARNING OUTCOMES
After this session, the students will be able to:
Create efficient SMPS circuits considering different topologies
Evaluate SMPS performance based on design considerations
and efficiency optimization.
Describe PWM techniques and their impact on inverter
waveform quality.
DISCUSSION
Introduction
A switch-mode power supply (SMPS) is an electronic power supply that
incorporates a switching regulator to efficiently convert electrical power.
It transfers power from a DC or AC source (often mains power) to a DC
load, such as a personal computer, while converting voltage and current
characteristics.
Typical Linear Power Supply Circuit
SMPS Circuit
Key Parts of an SMPS
1. Input Rectifier and Filter
Converts AC input voltage to DC and filters out noise and harmonics
2. High-Frequency Switching Element
A semiconductor switch like a MOSFET or IGBT rapidly switches the DC on
and off at high frequencies to regulate output power
3. Pulse Width Modulator (PWM) Controller
Controls the switching frequency and duty cycle of the switch to regulate
the output voltage and ensure stability.
Key Parts of an SMPS
4. Transformer (High-Frequency Transformer)
Steps up or steps down the voltage level depending on the design. High-
frequency operation allows smaller transformer size compared to
traditional power supplies.
5. Output Rectifier and Filter
Converts the high-frequency AC from the transformer back to DC and filters
it to provide a stable DC output.
Key Parts of an SMPS
6. Feedback Control Circuit
Monitors the output voltage and adjusts the PWM controller to maintain a
constant output voltage, even with varying input voltage or load conditions.
7. Output Rectifier and Filter
Includes components such as overvoltage protection (OVP), overcurrent
protection (OCP), and thermal protection to safeguard the power supply
and connected devices.
SMPS Topologies
Buck Converter
Boost Converter
Buck-Boost Converter
Buck Converter

The Buck switching regulator is a type of switch mode power
supply circuit that is designed to efficiently reduce DC voltage
from a higher voltage to a lower one, that is it subtracts or
“Bucks” the supply voltage, thereby reducing the voltage
available at the output terminals without changing the polarity.
Buck Converter
Boost Converter

The boost converter is designed to increase a DC voltage from
a lower voltage to a higher one, that is it adds too or “Boosts”
the supply voltage, thereby increasing the available voltage at
the output terminals without changing the polarity.
Boost Converter
Buck-Boost Converter

The Buck-Boost switching regulator is a combination of the
buck converter and the boost converter that produces an
inverted (negative) output voltage which can be greater or less
than the input voltage based on the duty cycle.
Buck-Boost Converter
Operation of each SMPS Topology

Please refer to the videos attached to the week topic on our
Google classroom to see operation of buck, boost, and buck-
boost converters.