This document provides an overview of power electronic devices. It discusses the basic concepts including classifications of devices as uncontrolled, half-controlled, or fully-controlled. Power diodes are introduced as an example uncontrolled device. Their structure and operation as a PN junction is explained. Construction details are provided for practical power diodes used in power electronics applications.
This document provides an overview of power electronic devices. It begins with an outline of topics to be covered, including an introductory overview of power electronic devices, uncontrolled devices like power diodes, half-controlled devices like thyristors, fully-controlled devices, and drive circuits. It then discusses the concept and features of power electronic devices, how they are used in power electronic systems, and classifications like uncontrolled, half-controlled, and fully-controlled. The document focuses on specific devices, providing details on their structure, operation, characteristics and applications. It covers power diodes and thyristors in more depth.
The document provides an overview of power electronic devices. It begins by defining power electronic devices as semiconductor devices used to convert or control electric power. It then discusses the key features of power electronic devices, including that they must handle large power levels and typically operate in switching states. The document outlines the basic configuration of a power electronic system and classifications of devices. It provides details on uncontrolled diodes, half-controlled thyristors, and fully-controlled devices. It also discusses characteristics, specifications, applications and history.
This document provides an overview of power electronic devices. It begins with an introduction to power electronic devices and their features. It then discusses uncontrolled devices like power diodes and their characteristics. It covers half-controlled devices like thyristors and their operation. Fully-controlled devices like IGBTs, MOSFETs, and GTOs are described next along with their structures and characteristics. The document concludes with emerging devices like SITs, SITHs, MCTs, and IGCTs.
This document provides an overview of power electronic devices. It begins with an introduction to power electronic devices and their features. It then discusses uncontrolled devices like power diodes and their characteristics. It covers half-controlled devices like thyristors and their operation. Fully-controlled devices like GTOs, IGBTs, MOSFETs are described along with their structures, characteristics and examples. The document concludes with emerging devices like SITs, SITHs, MCTs and IGCTs.
This document provides an overview of power electronic devices. It begins with an introduction to power electronic devices and their features. It then discusses uncontrolled devices like power diodes and their characteristics. It covers half-controlled devices like thyristors and their operation. Fully-controlled devices like IGBTs, MOSFETs, and GTOs are described next along with their structures and characteristics. The document concludes with emerging devices like SITs, SITHs, MCTs, and IGCTs.
This document provides an overview of power electronic devices. It begins with an introduction describing power electronic devices as electronic devices that can directly process electric power by converting or controlling it. It then discusses some key device types including uncontrolled diodes, half-controlled thyristors, and fully-controlled devices like GTOs, MOSFETs, and IGBTs. For each device type, the document covers topics like appearance, structure, operation principles, and characteristics. It provides examples of commercial power devices and their specifications.
Power electronics devices and their characteristicsKartickJana3
This document discusses power electronic devices and their characteristics. It describes several types of power devices including bipolar junction transistors (BJT), field effect transistors (FET), thyristors, Darlington transistors, and insulated gate bipolar transistors (IGBT). It covers the key characteristics, operating principles, and ratings of these devices. It also discusses how snubber circuits using inductors, resistors, and capacitors can be designed to protect power devices from high rates of change of current (di/dt) and voltage (dv/dt) during switching.
1. The document describes a three phase protection circuit that monitors the availability of three phase power supply and switches off connected appliances in the event of failure of one or two phases. It uses three 12V relays, a 555 timer IC, and a 230V coil contactor with four poles.
2. Key components of the protection circuit are described, including relays, contactors, 555 timer IC, diodes, zener diodes, transistors, capacitors, resistors, transformers, and optocoupler ICs. The operation of the three phase protection circuit is also explained.
3. The circuit automatically disconnects power to protected appliances through the contactor when any phase fails, and automatically restores
This document provides an overview of power electronic devices. It begins with an outline of topics to be covered, including an introductory overview of power electronic devices, uncontrolled devices like power diodes, half-controlled devices like thyristors, fully-controlled devices, and drive circuits. It then discusses the concept and features of power electronic devices, how they are used in power electronic systems, and classifications like uncontrolled, half-controlled, and fully-controlled. The document focuses on specific devices, providing details on their structure, operation, characteristics and applications. It covers power diodes and thyristors in more depth.
The document provides an overview of power electronic devices. It begins by defining power electronic devices as semiconductor devices used to convert or control electric power. It then discusses the key features of power electronic devices, including that they must handle large power levels and typically operate in switching states. The document outlines the basic configuration of a power electronic system and classifications of devices. It provides details on uncontrolled diodes, half-controlled thyristors, and fully-controlled devices. It also discusses characteristics, specifications, applications and history.
This document provides an overview of power electronic devices. It begins with an introduction to power electronic devices and their features. It then discusses uncontrolled devices like power diodes and their characteristics. It covers half-controlled devices like thyristors and their operation. Fully-controlled devices like IGBTs, MOSFETs, and GTOs are described next along with their structures and characteristics. The document concludes with emerging devices like SITs, SITHs, MCTs, and IGCTs.
This document provides an overview of power electronic devices. It begins with an introduction to power electronic devices and their features. It then discusses uncontrolled devices like power diodes and their characteristics. It covers half-controlled devices like thyristors and their operation. Fully-controlled devices like GTOs, IGBTs, MOSFETs are described along with their structures, characteristics and examples. The document concludes with emerging devices like SITs, SITHs, MCTs and IGCTs.
This document provides an overview of power electronic devices. It begins with an introduction to power electronic devices and their features. It then discusses uncontrolled devices like power diodes and their characteristics. It covers half-controlled devices like thyristors and their operation. Fully-controlled devices like IGBTs, MOSFETs, and GTOs are described next along with their structures and characteristics. The document concludes with emerging devices like SITs, SITHs, MCTs, and IGCTs.
This document provides an overview of power electronic devices. It begins with an introduction describing power electronic devices as electronic devices that can directly process electric power by converting or controlling it. It then discusses some key device types including uncontrolled diodes, half-controlled thyristors, and fully-controlled devices like GTOs, MOSFETs, and IGBTs. For each device type, the document covers topics like appearance, structure, operation principles, and characteristics. It provides examples of commercial power devices and their specifications.
Power electronics devices and their characteristicsKartickJana3
This document discusses power electronic devices and their characteristics. It describes several types of power devices including bipolar junction transistors (BJT), field effect transistors (FET), thyristors, Darlington transistors, and insulated gate bipolar transistors (IGBT). It covers the key characteristics, operating principles, and ratings of these devices. It also discusses how snubber circuits using inductors, resistors, and capacitors can be designed to protect power devices from high rates of change of current (di/dt) and voltage (dv/dt) during switching.
1. The document describes a three phase protection circuit that monitors the availability of three phase power supply and switches off connected appliances in the event of failure of one or two phases. It uses three 12V relays, a 555 timer IC, and a 230V coil contactor with four poles.
2. Key components of the protection circuit are described, including relays, contactors, 555 timer IC, diodes, zener diodes, transistors, capacitors, resistors, transformers, and optocoupler ICs. The operation of the three phase protection circuit is also explained.
3. The circuit automatically disconnects power to protected appliances through the contactor when any phase fails, and automatically restores
Chapter 1 Introduction to power Electronic Devices.pdfLiewChiaPing
The document provides an introduction to power electronics. It discusses power electronic systems and various types of electronic converters including AC-DC, DC-DC, DC-AC, and AC-AC converters. It also describes common power semiconductor devices such as power diodes, thyristors, MOSFETs, IGBTs, and IGCTs. Applications of power electronics in areas like power supplies, motor drives, renewable energy and power transmission are also highlighted. Gate drive circuits, switching losses, and heat dissipation in power switches are some other topics covered in the document.
This document outlines the syllabus for a Power System Protection course, including 5 units: introduction, relay operating principles and characteristics, apparatus protection, theory of circuit interruption, and circuit breakers. It provides an overview of key concepts like faults and fault currents in power systems, the importance of protective schemes, and components of protection systems like relays, circuit breakers, and batteries. The document also shares diagrams to illustrate power system configurations and protective devices.
chapter_1 Intro. to electonic Devices.pptLiewChiaPing
The document discusses power electronics concepts and devices. It begins with an introduction to power electronics and outlines various power electronic converters including controlled rectifiers, choppers, inverters, cycloconverters, and AC voltage controllers. It then discusses applications of power electronic converters in various industries. The document also describes several power semiconductor devices used in power electronics, such as power diodes, transistors, MOSFETs, IGBTs, thyristors, GTOs, and IGCTs. It covers the characteristics, ratings, and drive circuits of these devices.
Week1&2 comm., for engineering techniciansTriza Kamel
This document provides guidance for engineering technicians on interpreting engineering drawings for electronic, electrical, and communication circuits. It begins with an overview of the steps to interpret engineering information, which are to identify components, understand their purpose, and determine the overall circuit purpose. It then details the standard symbols and functions of common circuit components for electronic circuits like wires, power supplies, switches and resistors. The same is done for electrical circuits covering logic gates. Finally, communication circuit components are explained including routers, switches, hubs and network diagrams. Activities are included to have technicians interpret sample circuit diagrams.
An electric circuit is a connection of electronic components like voltage/current sources, resistors, inductors and capacitors. Power is supplied by a source and dissipated by another component. The purpose of electronic components is to control current flow to achieve a specified output. Resistors restrict current flow while capacitors can store energy and diodes allow current to flow in one direction. Transistors are commonly used for amplification and switching. Integrated circuits combine multiple components on a single chip to perform complex functions.
Switchgear and control panels contain electrical disconnects, fuses, and circuit breakers to control, protect, and isolate equipment in power systems. Solid state devices like diodes, thyristors, transistors, and other semiconductors are increasingly used for control and protection over mechanical devices due to greater reliability and speed. Power semiconductor devices must conduct large currents with low losses while blocking high voltages, which is achieved through lightly doped drift layers between heavily doped layers.
This document provides an overview of protection and switchgear for an electrical engineering course. It includes definitions of key components in a power system like transformers, circuit breakers, and protective relays. It also describes the purpose of a protection system to isolate faults and prevent equipment damage. Additional sections cover current and voltage transformers, batteries, fuses, lighting arresters, and the different categories and functions of switchgear.
This ppt explains Ultra Fast Acting Electronic Circuit Breaker, student is provided with his/her authorized tag to swipe over the reader to record their attendance.
Edgefxkits.com has a wide range of electronic projects ideas that are primarily helpful for ECE, EEE and EIE students and the ideas can be applied for real life purposes as well.
http://www.edgefxkits.com/
Visit our page to get more ideas on popular electronic projects developed by professionals.
Edgefx provides free verified electronic projects kits around the world with abstracts, circuit diagrams, and free electronic software. We provide guidance manual for Do It Yourself Kits (DIY) with the modules at best price along with free shipping.
The document describes an ultra fast acting electronic circuit breaker. It uses a microcontroller to monitor the voltage drop across a current sensing resistor and compare it to a preset threshold. When the threshold is exceeded, the microcontroller triggers a relay through a MOSFET to disconnect the load. This allows for faster response than a thermal circuit breaker and protects equipment from overload. Key components include a microcontroller, current sensing resistor, comparator, relay, and MOSFET. The circuit breaker provides overcurrent protection for electrical devices.
The document discusses different types of electro-pneumatic and electro-hydraulic components including solenoid valves, relays, switches, and sensors. Solenoid valves use an electromagnet to actuate a pneumatic valve and control fluid flow. Relays are electromagnetically actuated switches that use a coil to switch contacts. Switches have normally open or closed contacts. Sensors convert physical values into electrical signals and can be contact or non-contact, with examples including limit switches, pressure sensors, and proximity sensors.
- Single-ended inputs are susceptible to ground loop errors and electrical noise, while differential inputs eliminate grounding errors and have better noise immunity.
- Sinking inputs receive power from an external source, while sourcing inputs provide power. A sinking input must connect to a sourcing output and vice versa.
- The EXTSUP option provides a sinking output from a signal conditioner, allowing compatibility with a PLC's single-ended inputs which may have a different ground than differential inputs.
This document outlines the syllabus for a Power Electronics course. It covers key topics like power semiconductor switches, AC-DC converters, DC-DC converters, AC-DC inverters, and AC-AC converters. Specific units will discuss power switching devices, phase controlled rectifiers, choppers/SMPS, inverters, and voltage regulators. The course aims to develop skills for designing power converters for drive and power system applications and to understand commercial and industrial power electronics applications.
Power Electronics Basic by Engr.Rajesh Royrajesh roy
This document introduces power electronics and discusses various topics including definitions, applications, power semiconductor switches, and losses. It describes how power electronics is used to convert electrical power efficiently from one form to another to suit user loads. The basic components of power electronics systems include an input power source, power processor, controller, and load. Examples of applications in static power supplies and motor drives are provided. Common power semiconductor switches like diodes, thyristors, BJTs, MOSFETs, and IGBTs are also introduced along with their characteristics.
Here is the list of major electrical and electronic components utilized in electrical and electronic projects and several circuits are designed with numerous components like Resistors, Capacitors, Fuses, Transistors, Integrated Circuits, Relays, Switches, Motors, Circuit Breakers, Resistors, Inductors, Transformers, Battery And Fuse.
Lecture-4 : Semiconductor Power Switching Devices-1rsamurti
This document discusses power semiconductor diodes and their use as switches. It describes the ideal characteristics of a switch and compares them to practical switches. There are different types of power diodes classified based on their control, controllability, conduction, and blocking properties. The key power loss mechanisms in a switch are also explained. Different types of power diodes like standard recovery, fast recovery, Schottky, and silicon carbide diodes are described along with their recovery times and applications. Diode packages and rectifier modules are shown. The next lecture will cover more power semiconductor switching devices.
This document discusses power semiconductor diodes and their use as switches. It describes the ideal characteristics of a switch and compares them to practical switches. There are different types of power diodes classified based on their control, controllability, conduction, and blocking properties. The key power loss mechanisms in a switch are also summarized. Different types of power diodes like standard recovery, fast recovery, Schottky, and silicon carbide diodes are described along with their recovery times and applications. Diode packages and rectifier modules are shown. The next lecture will cover more power semiconductor switching devices.
Elec581 chapter 2 - fundamental elements of power eletronicsTarek Schehadeih
This document discusses fundamental concepts of power electronics including potential levels in circuits, voltage across circuit elements like switches, resistors, inductors and capacitors. It also covers diodes and their behavior as switches based on forward or reverse bias. Diode circuits like rectifiers and filters are described. Thyristors are then introduced as switches whose conduction can be controlled by a gate signal. Basic thyristor circuits include controlled rectifiers supplying passive or active loads.
This document provides an overview of power semiconductor devices taught in a course at S.M.D.R. Government Polytechnic in Dhule, India. It covers various topics including semiconductor devices like power diodes, transistors, thyristors, and their characteristics. Specifically, it discusses the structures, symbols, V-I characteristics, and applications of power diodes, BJTs, MOSFETs, IGBTs, SITs, thyristors, SCRs, and triacs. It provides comparisons of the key features of BJTs vs MOSFETs and IGBTs vs MOSFETs. The document aims to educate students about important power semiconductor devices and their working principles
The document provides an overview of a class on fundamentals of power electronics. It covers topics like power electronics, power control using devices like thyristors, characteristics of SCR including V-I characteristics and different turn on/off methods. Diagrams are included to explain concepts like two transistor analogy of SCR, different commutation techniques etc. The document acts as notes for a class on basic concepts of power electronics.
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The document provides an introduction to power electronics. It discusses power electronic systems and various types of electronic converters including AC-DC, DC-DC, DC-AC, and AC-AC converters. It also describes common power semiconductor devices such as power diodes, thyristors, MOSFETs, IGBTs, and IGCTs. Applications of power electronics in areas like power supplies, motor drives, renewable energy and power transmission are also highlighted. Gate drive circuits, switching losses, and heat dissipation in power switches are some other topics covered in the document.
This document outlines the syllabus for a Power System Protection course, including 5 units: introduction, relay operating principles and characteristics, apparatus protection, theory of circuit interruption, and circuit breakers. It provides an overview of key concepts like faults and fault currents in power systems, the importance of protective schemes, and components of protection systems like relays, circuit breakers, and batteries. The document also shares diagrams to illustrate power system configurations and protective devices.
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The document discusses power electronics concepts and devices. It begins with an introduction to power electronics and outlines various power electronic converters including controlled rectifiers, choppers, inverters, cycloconverters, and AC voltage controllers. It then discusses applications of power electronic converters in various industries. The document also describes several power semiconductor devices used in power electronics, such as power diodes, transistors, MOSFETs, IGBTs, thyristors, GTOs, and IGCTs. It covers the characteristics, ratings, and drive circuits of these devices.
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This document provides guidance for engineering technicians on interpreting engineering drawings for electronic, electrical, and communication circuits. It begins with an overview of the steps to interpret engineering information, which are to identify components, understand their purpose, and determine the overall circuit purpose. It then details the standard symbols and functions of common circuit components for electronic circuits like wires, power supplies, switches and resistors. The same is done for electrical circuits covering logic gates. Finally, communication circuit components are explained including routers, switches, hubs and network diagrams. Activities are included to have technicians interpret sample circuit diagrams.
An electric circuit is a connection of electronic components like voltage/current sources, resistors, inductors and capacitors. Power is supplied by a source and dissipated by another component. The purpose of electronic components is to control current flow to achieve a specified output. Resistors restrict current flow while capacitors can store energy and diodes allow current to flow in one direction. Transistors are commonly used for amplification and switching. Integrated circuits combine multiple components on a single chip to perform complex functions.
Switchgear and control panels contain electrical disconnects, fuses, and circuit breakers to control, protect, and isolate equipment in power systems. Solid state devices like diodes, thyristors, transistors, and other semiconductors are increasingly used for control and protection over mechanical devices due to greater reliability and speed. Power semiconductor devices must conduct large currents with low losses while blocking high voltages, which is achieved through lightly doped drift layers between heavily doped layers.
This document provides an overview of protection and switchgear for an electrical engineering course. It includes definitions of key components in a power system like transformers, circuit breakers, and protective relays. It also describes the purpose of a protection system to isolate faults and prevent equipment damage. Additional sections cover current and voltage transformers, batteries, fuses, lighting arresters, and the different categories and functions of switchgear.
This ppt explains Ultra Fast Acting Electronic Circuit Breaker, student is provided with his/her authorized tag to swipe over the reader to record their attendance.
Edgefxkits.com has a wide range of electronic projects ideas that are primarily helpful for ECE, EEE and EIE students and the ideas can be applied for real life purposes as well.
http://www.edgefxkits.com/
Visit our page to get more ideas on popular electronic projects developed by professionals.
Edgefx provides free verified electronic projects kits around the world with abstracts, circuit diagrams, and free electronic software. We provide guidance manual for Do It Yourself Kits (DIY) with the modules at best price along with free shipping.
The document describes an ultra fast acting electronic circuit breaker. It uses a microcontroller to monitor the voltage drop across a current sensing resistor and compare it to a preset threshold. When the threshold is exceeded, the microcontroller triggers a relay through a MOSFET to disconnect the load. This allows for faster response than a thermal circuit breaker and protects equipment from overload. Key components include a microcontroller, current sensing resistor, comparator, relay, and MOSFET. The circuit breaker provides overcurrent protection for electrical devices.
The document discusses different types of electro-pneumatic and electro-hydraulic components including solenoid valves, relays, switches, and sensors. Solenoid valves use an electromagnet to actuate a pneumatic valve and control fluid flow. Relays are electromagnetically actuated switches that use a coil to switch contacts. Switches have normally open or closed contacts. Sensors convert physical values into electrical signals and can be contact or non-contact, with examples including limit switches, pressure sensors, and proximity sensors.
- Single-ended inputs are susceptible to ground loop errors and electrical noise, while differential inputs eliminate grounding errors and have better noise immunity.
- Sinking inputs receive power from an external source, while sourcing inputs provide power. A sinking input must connect to a sourcing output and vice versa.
- The EXTSUP option provides a sinking output from a signal conditioner, allowing compatibility with a PLC's single-ended inputs which may have a different ground than differential inputs.
This document outlines the syllabus for a Power Electronics course. It covers key topics like power semiconductor switches, AC-DC converters, DC-DC converters, AC-DC inverters, and AC-AC converters. Specific units will discuss power switching devices, phase controlled rectifiers, choppers/SMPS, inverters, and voltage regulators. The course aims to develop skills for designing power converters for drive and power system applications and to understand commercial and industrial power electronics applications.
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Three-day training on academic research focuses on analytical tools at United Technical College, supported by the University Grant Commission, Nepal. 24-26 May 2024
Low power architecture of logic gates using adiabatic techniquesnooriasukmaningtyas
The growing significance of portable systems to limit power consumption in ultra-large-scale-integration chips of very high density, has recently led to rapid and inventive progresses in low-power design. The most effective technique is adiabatic logic circuit design in energy-efficient hardware. This paper presents two adiabatic approaches for the design of low power circuits, modified positive feedback adiabatic logic (modified PFAL) and the other is direct current diode based positive feedback adiabatic logic (DC-DB PFAL). Logic gates are the preliminary components in any digital circuit design. By improving the performance of basic gates, one can improvise the whole system performance. In this paper proposed circuit design of the low power architecture of OR/NOR, AND/NAND, and XOR/XNOR gates are presented using the said approaches and their results are analyzed for powerdissipation, delay, power-delay-product and rise time and compared with the other adiabatic techniques along with the conventional complementary metal oxide semiconductor (CMOS) designs reported in the literature. It has been found that the designs with DC-DB PFAL technique outperform with the percentage improvement of 65% for NOR gate and 7% for NAND gate and 34% for XNOR gate over the modified PFAL techniques at 10 MHz respectively.
2. Power
Electronic
s
2
Outline
Outline
1.1 An introductory overview of power electronic devices
1.1 An introductory overview of power electronic devices
1.2 Uncontrolled device
1.2 Uncontrolled device —
— power diode
power diode
1.3 Half
1.3 Half-
-controlled device
controlled device —
— thyristor
thyristor
1.4 Typical fully
1.4 Typical fully-
-controlled devices
controlled devices
1.5 Other new power electronic devices
1.5 Other new power electronic devices
1.6 Drive circuit for power electronic devices
1.6 Drive circuit for power electronic devices
1.7 Protection of power electronic devices
1.7 Protection of power electronic devices
1.8 Series and parallel connections of power electronic
1.8 Series and parallel connections of power electronic
devices
devices
3. Power
Electronic
s
3
The concept and features
The concept and features
Configuration of systems using power electronic devices
Configuration of systems using power electronic devices
Classifications
Classifications
Major topics
Major topics
1.1
1.1 An introductory overview of power
An introductory overview of power
electronic devices
electronic devices
4. Power
Electronic
s
4
Power electronic devices:
Power electronic devices:
In broad sense
In broad sense
Very often:
Very often:
Major material used in power semiconductor devices
Major material used in power semiconductor devices
——
—— Silicon
Silicon
are the electronic devices that can be directly used in the powe
are the electronic devices that can be directly used in the power
r
processing circuits to convert or control electric power.
processing circuits to convert or control electric power.
The concept of power electronic devices
The concept of power electronic devices
power electronic devices
power electronic devices
Vacuum devices: Mercury arc
Vacuum devices: Mercury arc
rectifier
rectifier thyratron
thyratron, etc. . seldom
, etc. . seldom
in use today
in use today
Semiconductor devices:
Semiconductor devices:
major power electronic devices
major power electronic devices
Power electronic devices = Power semiconductor devices
Power electronic devices = Power semiconductor devices
5. Power
Electronic
s
5
Features of power electronic devices
Features of power electronic devices
The electric power that power electronic device
The electric power that power electronic device
deals with is usually much larger than that the
deals with is usually much larger than that the
information electronic device does.
information electronic device does.
Usually working in switching states to reduce power
Usually working in switching states to reduce power
losses
losses
p=vi=0
Off-state Current through the device is 0
i=0
p=vi=0
On-state Voltage across the device is 0
v=0
6. Power
Electronic
s
6
Features of power electronic devices
Features of power electronic devices
Need to be controlled by information electronic circuits.
Need to be controlled by information electronic circuits.
Very often, drive circuits are necessary to interface
Very often, drive circuits are necessary to interface
between information circuits and power circuits.
between information circuits and power circuits.
Dissipated power loss usually larger than information
Dissipated power loss usually larger than information
electronic devices
electronic devices —
— special packaging and heat sink
special packaging and heat sink
are necessary.
are necessary.
7. Power
Electronic
s
7
Power losses on power semiconductor
Power losses on power semiconductor
devices
devices
= conduction loss + turn
= conduction loss + turn-
-off loss + off
off loss + off-
-state loss + turn
state loss + turn-
-on loss
on loss
O n -s ta te
(c o n d u c tio n s ta te )
tu rn in g -
o ff
O ff-s ta te
(b lo c k in g s ta te )
tu rn in g
-o n
t
t
t
v
i
p
Total power loss on
Total power loss on
power semiconductor
power semiconductor
Switching loss
Switching loss
(on
(on-
-state loss)
state loss)
8. Power
Electronic
s
8
Configuration of systems using power
Configuration of systems using power
electronic devices
electronic devices
Control
circuit
detection
circuit
drive
circuit
Power circuit
(power stage,
main circuit)
Control circuit (in a broad sense)
Power electronic
system: Electric isolation:
optical, magnetic
Protection circuit is also very often used in power electronic
system especially for the expensive power semiconductors.
9. Power
Electronic
s
9
Terminals of a power electronic device
Terminals of a power electronic device
C
E
G
A power electronic device
must have at least two
terminals to allow power
circuit current flow through.
A power electronic
device usually has
a third terminal —
—control terminal
to control the
states of the device.
Control signal from drive circuit must be connected between the
Control signal from drive circuit must be connected between the
control terminal and a fixed power circuit terminal (therefore
control terminal and a fixed power circuit terminal (therefore
called common terminal ).
called common terminal ).
Drive
Circuit
10. Power
Electronic
s
10
A classification of power electronic devices
A classification of power electronic devices
Uncontrolled device: diode
Uncontrolled device: diode
(Uncontrollable device)
(Uncontrollable device)
Fully
Fully-
-controlled device: Power MOSFET, IGBT,GTO, IGCT
controlled device: Power MOSFET, IGBT,GTO, IGCT
(Fully
(Fully-
-controllable device)
controllable device)
Half
Half-
-controlled device:
controlled device: thyristor
thyristor
(Half
(Half-
-controllable device)
controllable device)
has only two terminals and can not be controlled by control signal.
The on and off states of the device are determined by the power
circuit.
is turned-on by a control signal and turned-off by the power circuit
The on and off states of the device are controlled by control signals.
11. Power
Electronic
s
11
Other classifications
Other classifications
power electronic devices
power electronic devices
Pulse
Pulse-
-triggered devices
triggered devices
Level
Level-
-sensitive (level
sensitive (level-
-triggered) devices
triggered) devices
power electronic devices
power electronic devices
power electronic devices
power electronic devices
Current
Current-
-driven (current
driven (current-
-controlled) devices
controlled) devices
Voltage
Voltage-
-driven (voltage
driven (voltage-
-controlled) devices
controlled) devices
(Field
(Field-
-controlled devices)
controlled devices)
Unipolar
Unipolar devices (Majority carrier devices)
devices (Majority carrier devices)
Composite devices
Composite devices
Bipolar devices (Minority carrier devices)
Bipolar devices (Minority carrier devices)
12. Power
Electronic
s
12
Appearance, structure, and symbol
Appearance, structure, and symbol
Physics of operation
Physics of operation
Characteristics
Characteristics
Specification
Specification
Special issues
Special issues
Devices of the same family
Devices of the same family
Major topics for each device
Major topics for each device
Switching characteristics
Switching characteristics
Static characteristics
Static characteristics
13. Power
Electronic
s
13
Passive components in power electronic
Passive components in power electronic
circuit
circuit
Transformer, inductor, capacitor and resistor:
Transformer, inductor, capacitor and resistor:
these are passive components in a power electronic
these are passive components in a power electronic
circuit since they can not be controlled by control signal and
circuit since they can not be controlled by control signal and
their characteristics are usually constant and linear.
their characteristics are usually constant and linear.
The requirements for these passive components by power
The requirements for these passive components by power
electronic circuits could be very different from those by
electronic circuits could be very different from those by
ordinary circuits.
ordinary circuits.
14. Power
Electronic
s
14
1.2 Uncontrolled device Power diode
1.2 Uncontrolled device Power diode
Appearance
Appearance
Structure
Structure Symbol
Symbol
Cathode
Anode
K
K
A
A
Anode Cathode
15. Power
Electronic
s
15
PN junction
PN junction
-
。 -
。 -
。
-
。 -
。 -
。
-
。 -
。 -
。
-
。 -
。 -
。
-
。 -
。 -
。
+
· +
· +
·
+
· +
· +
·
+
· +
· +
·
+
·
+
· +
·
+
· +
· +
·
+
-
+
-
+
-
+
-
+
-
p region n region
Direction of
inner electric field
Space charge
region
(depletion region,
potential barrier
region)
Semiconductor (Column IV element,
Semiconductor (Column IV element, Si
Si)
)
Electrons and holes.
Electrons and holes.
Pure semiconductor (intrinsic semiconductor)
Pure semiconductor (intrinsic semiconductor)
Doping, p
Doping, p-
-type semiconductor. N
type semiconductor. N-
-type semiconductor
type semiconductor
PN junction
PN junction
Equilibrium of diffusion and drift
Equilibrium of diffusion and drift
16. Power
Electronic
s
16
PN junction with voltage applied in the
PN junction with voltage applied in the
forward direction
forward direction
V
+
+
+
+
+
-
-
-
-
-
n
p
Wo
W
+ -
17. Power
Electronic
s
17
PN junction with voltage applied in the reverse
PN junction with voltage applied in the reverse
direction
direction
+
-
V
+
+
+
+
+
-
-
-
-
-
-
-
-
+
+
+
n
p
Wo
W
Effective direction
of electronic field
18. Power
Electronic
s
18
Construction of a practical power diode
Construction of a practical power diode
Features different from low
Features different from low-
-power (information electronic) diodes
power (information electronic) diodes
–
– Larger size
–
– Vertically oriented structure
–
– n drift region (p-i-n diode)
–
– Conductivity modulation
250μm
Breakdown
voltage dependent
10 μm
p
Nd =10 cm
n substrate -3
19
Na =10 cm
-3
19
+
n epi Nd =10 cm
-3
14
p
Nd =10 cm
n substrate -3
19
+
Na =10 cm
-3
19
+
n epi
-
Nd =10 cm
-3
14
i
Anode
Cathode
+
-
V
-
21. Power
Electronic
s
21
The positive and negative charge in the depletion region is
The positive and negative charge in the depletion region is
variable with the changing of external voltage.
variable with the changing of external voltage.
—
—–
–Junction capacitor C
Junction capacitor CJ
J .
.
Junction capacitor C
Junction capacitor CJ
J
Junction capacitor influences the switching characteristics of
Junction capacitor influences the switching characteristics of
power diode.
power diode.
Junction capacitor
Junction capacitor
Diffusion capacitor
Diffusion capacitor C
CD
D
Potential barrier capacitor
Potential barrier capacitor C
CB
B
22. Power
Electronic
s
22
Static characteristics of power diode
Static characteristics of power diode
The I
The I-
-V characteristic of power diode
V characteristic of power diode
I
O
IF
UTO UF U
23. Power
Electronic
s
23
Switching (dynamic) characteristics of power
Switching (dynamic) characteristics of power
diode
diode
Reverse
Reverse-
-recovery process:
recovery process:
Reverse-recovery time, reverse-recovery charge,
reverse-recovery peak current.
Turn
Turn-
-off transient
off transient
IF
UF
tF t0
trr
td
tf
t1 t2 t
UR
URP
IRP
diF
dt
diR
dt
25. Power
Electronic
s
25
Specifications of power diode
Specifications of power diode
Average rectified forward current I
Average rectified forward current IF(AV)
F(AV)
Forward voltage U
Forward voltage UF
F
Peak repetitive reverse voltage U
Peak repetitive reverse voltage URRM
RRM
Maximum junction temperature T
Maximum junction temperature TJM
JM
Reverse
Reverse-
-recovery time
recovery time t
trr
rr
26. Power
Electronic
s
26
Types of power diodes
Types of power diodes
General purpose diode (rectifier diode):
General purpose diode (rectifier diode):
Fast recovery diode
Fast recovery diode
Schottky
Schottky diode (
diode (Schottky
Schottky barrier diode
barrier diode-
-SBD)
SBD)
standard recovery
Reverse recovery time and charge specified. trr is usually
less than 1μs, for many less than 100 ns —— ultra-fast
recovery diode.
– A majority carrier device
– Essentially no recovered charge, and lower forward voltage.
– Restricted to low voltage (less than 200V)
28. Power
Electronic
s
28
History and applications of power diode
History and applications of power diode
Applied in industries starting 1950s
Applied in industries starting 1950s
Still in
Still in-
-use today. Usually working with controlled
use today. Usually working with controlled
devices as necessary components
devices as necessary components
In many circumstances fast recovery diodes or
In many circumstances fast recovery diodes or
schottky
schottky diodes have to be used instead of general
diodes have to be used instead of general
purpose diodes.
purpose diodes.
29. Power
Electronic
s
29
1.3 Half
1.3 Half-
-controlled device
controlled device—
—Thyristor
Thyristor
Another name: SCR
Another name: SCR—
—silicon controlled rectifier
silicon controlled rectifier
Thyristor
Thyristor Opened the power electronics era
Opened the power electronics era
–
– 1956, invention, Bell Laboratories
1956, invention, Bell Laboratories
–
– 1957, development of the 1st product, GE
1957, development of the 1st product, GE
–
– 1958, 1st commercialized product, GE
1958, 1st commercialized product, GE
–
– Thyristor
Thyristor replaced vacuum devices in almost every power
replaced vacuum devices in almost every power
processing area.
processing area.
Still in use in high power situation.
Still in use in high power situation. Thyristor
Thyristor till has the
till has the
highest power
highest power-
-handling capability.
handling capability.
History
History
32. Power
Electronic
s
32
Physics of
Physics of thyristor
thyristor operation
operation
Equivalent circuit: A
Equivalent circuit: A pnp
pnp
transistor and an
transistor and an npn
npn transistor
transistor
interconnected together
interconnected together
Positive feedback
Positive feedback
Trigger
Trigger
Can not be turned off by control
Can not be turned off by control
signal
signal
Half
Half-
-controllable
controllable
33. Power
Electronic
s
33
Quantitative description of
Quantitative description of thyristor
thyristor operation
operation
I
Ic1
c1=
=α
α1
1 I
IA
A +
+ I
ICBO1
CBO1 (
(1
1-
-1
1)
)
I
Ic2
c2=
=α
α2
2 I
IK
K +
+ I
ICBO2
CBO2 (
(1
1-
-2
2)
)
I
IK
K=
=I
IA
A+
+I
IG
G (
(1
1-
-3
3)
)
I
IA
A=
=I
Ic
c1
1+
+I
Ic
c2
2 (
(1
1-
-4
4)
)
)
(
1 2
1
CBO2
CBO1
G
2
A
α
α
α
+
−
+
+
=
I
I
I
I (
(1
1-
-5
5)
)
When I
When IG
G=0,
=0, α
α1
1+α
+α2
2 is small.
is small.
When I
When IG
G>0,
>0, α
α1
1+α
+α2
2 will approach 1, I
will approach 1, IA
A will be very large.
will be very large.
34. Power
Electronic
s
34
Other methods to trigger
Other methods to trigger thyristor
thyristor on
on
High voltage across anode and cathode
High voltage across anode and cathode—
—
avalanche breakdown
avalanche breakdown
High rising rate of anode
High rising rate of anode voltagte
voltagte —
— du/dt
du/dt too high
too high
High junction temperature
High junction temperature
Light activation
Light activation
35. Power
Electronic
s
35
Static characteristics of
Static characteristics of thyristor
thyristor
Blocking when reverse
Blocking when reverse
biased, no matter if there
biased, no matter if there
is gate current applied
is gate current applied
Conducting only when
Conducting only when
forward biased and there
forward biased and there
is triggering current
is triggering current
applied to the gate
applied to the gate
Once triggered on, will be
Once triggered on, will be
latched on conducting
latched on conducting
even when the gate
even when the gate
current is no longer
current is no longer
applied
applied
Turning off: decreasing
Turning off: decreasing
current to be near zero
current to be near zero
with the effect of external
with the effect of external
power circuit
power circuit
Gate I
Gate I-
-V characteristics
V characteristics
O U Ak
IA
I
H
IG2
IG1
IG
=0
U bo
U DSM
U DRM
U RRM
U RSM
forward
forward
conducting
conducting
avalanche
avalanche
breakdown
breakdown
reverse
reverse
blocking
blocking
increasing IG
forward
forward
blocking
blocking
36. Power
Electronic
s
36
Switching characteristics of
Switching characteristics of thyristor
thyristor
Turn
Turn-
-on transient
on transient
–
– Delay time t
Delay time td
d
–
– Rise time
Rise time t
tr
r
–
– Turn
Turn-
-on time
on time t
tgt
gt
Turn
Turn-
-off transient
off transient
–
– Reverse recovery
Reverse recovery
time
time t
trr
rr
–
– Forward recovery
Forward recovery
time
time t
tgr
gr
–
– Turn
Turn-
-off time
off time t
tq
q
100%
90%
10%
uAK
t
t
O
0 td
tr
trr tgr
URRM
IRM
iA
37. Power
Electronic
s
37
Specifications of
Specifications of thyristor
thyristor
Peak repetitive forward blocking voltage U
Peak repetitive forward blocking voltage UDRM
DRM
Peak repetitive reverse blocking voltage U
Peak repetitive reverse blocking voltage URRM
RRM
Peak on
Peak on-
-state voltage U
state voltage UTM
TM
Average on
Average on-
-state current I
state current IT(AV)
T(AV)
Holding current I
Holding current IH
H
Latching up current I
Latching up current IL
L
Peak forward surge current I
Peak forward surge current ITSM
TSM
du/dt
du/dt
di/dt
di/dt
38. Power
Electronic
s
38
The family of
The family of thyristors
thyristors
Fast switching
Fast switching thyristor
thyristor—
—FST
FST
Triode AC switch
Triode AC switch—
—TRIAC
TRIAC
(Bi
(Bi-
-directional triode
directional triode thyristor
thyristor)
)
Reverse
Reverse-
-conducting
conducting thyristor
thyristor Light
Light-
-triggered (
triggered (activited
activited)
) thyristor
thyristor
—
—RCT
RCT —
—LTT
LTT
I
O U
IG=0
K
G
A
A
G
K
G
K
A
G
T1
T2
39. Power
Electronic
s
39
1.4 Typical fully
1.4 Typical fully-
-controlled devices
controlled devices
1.4.1 Gate
1.4.1 Gate-
-turn
turn-
-off
off thyristor
thyristor —
—GTO
GTO
1.4.2 Giant transistor
1.4.2 Giant transistor —
—GTR
GTR
1.4.3 Power metal
1.4.3 Power metal-
-oxide
oxide-
-semiconductor field effect
semiconductor field effect
transistor
transistor —
— Power MOSFET
Power MOSFET
1.4.4 Insulated
1.4.4 Insulated-
-gate bipolar transistor
gate bipolar transistor —
—IGBT
IGBT
Features
Features
–
– Begin to be used in large amount in 1980s
Begin to be used in large amount in 1980s
–
– GTR is obsolete and GTO is also seldom used today.
GTR is obsolete and GTO is also seldom used today.
–
– IGBT and power MOSFET are the two major power
IGBT and power MOSFET are the two major power
semiconductor devices nowadays.
semiconductor devices nowadays.
Applications
Applications
–
– IC fabrication technology, fully
IC fabrication technology, fully-
-controllable, high frequency
controllable, high frequency
40. Power
Electronic
s
40
A
G K G G
K
N1
P1
N2
N2 P2
b)
a)
1.4.1 Gate
1.4.1 Gate-
-turn
turn-
-off
off thyristor
thyristor—
—GTO
GTO
Major difference from conventional
Major difference from conventional thyristor
thyristor:
:
The gate and cathode structures are highly
The gate and cathode structures are highly interdigitated
interdigitated, with
, with
various types of geometric forms being used to layout the
various types of geometric forms being used to layout the
gates and cathodes.
gates and cathodes.
Structure
Structure Symbol
Symbol
G
K
A
41. Power
Electronic
s
41
Physics of GTO operation
Physics of GTO operation
The basic operation of GTO is the
The basic operation of GTO is the
same as that of the conventional
same as that of the conventional
thyristor
thyristor.
.
The principal differences lie in the
The principal differences lie in the
modifications in the structure to
modifications in the structure to
achieve gate turn
achieve gate turn-
-off capability.
off capability.
–
– Large
Large α
α2
2
–
– α
α1
1+
+α
α2
2 is just a little larger than
is just a little larger than
the critical value 1.
the critical value 1.
–
– Short distance from gate to
Short distance from gate to
cathode makes it possible to
cathode makes it possible to
drive current out of gate.
drive current out of gate.
R
NPN
PNP
A
G
S
K
EG
IG
EA
IK
Ic2
Ic1
IA
V1
V2
42. Power
Electronic
s
42
Characteristics of GTO
Characteristics of GTO
Static characteristic
Static characteristic
–
– Identical to conventional
Identical to conventional thyristor
thyristor in the forward direction
in the forward direction
–
– Rather low reverse breakdown voltage (20
Rather low reverse breakdown voltage (20-
-30V)
30V)
Switching characteristic
Switching characteristic
O
t
0 t
iG
iA
IA
90%IA
10%IA
tt
tf
ts
td
tr
t0
t1
t2
t3
t4
t5
t6
43. Power
Electronic
s
43
Specifications of GTO
Specifications of GTO
Most GTO specifications have the same meanings
Most GTO specifications have the same meanings
as those of conventional
as those of conventional thyristor
thyristor.
.
Specifications different from
Specifications different from thyristor
thyristor’
’s
s
–
– Maximum controllable anode current I
Maximum controllable anode current IATO
ATO
–
– Current turn
Current turn-
-off gain
off gain β
βoff
off
–
– Turn
Turn-
-on time t
on time ton
on
–
– Turn
Turn-
-off time
off time t
toff
off
44. Power
Electronic
s
44
1.4.2 Giant Transistor
1.4.2 Giant Transistor—
—GTR
GTR
GTR is actually the bipolar junction transistor that can handle
GTR is actually the bipolar junction transistor that can handle
high voltage and large current.
high voltage and large current.
So GTR is also called power BJT, or just BJT.
So GTR is also called power BJT, or just BJT.
Basic structure
Basic structure Symbol
Symbol
b
e
c
45. Power
Electronic
s
45
Structures of GTR different from its
Structures of GTR different from its
information
information-
-processing counterpart
processing counterpart
Multiple
Multiple-
-emitter structure
emitter structure Darlington configuration
Darlington configuration
46. Power
Electronic
s
46
Physics of GTR operation
Physics of GTR operation
Same as information BJT device
Same as information BJT device
holes
electrons
Eb
Ec
ib
ic
=βib
ie
=(1+β )ib
48. Power
Electronic
s
48
Switching characteristics of GTR
Switching characteristics of GTR
Turn
Turn-
-on transient
on transient
–
– Turn
Turn-
-on delay time t
on delay time td
d
–
– Rise time
Rise time t
tr
r
–
– Turn
Turn-
-on time t
on time ton
on
Turn
Turn-
-off transient
off transient
–
– Storage time
Storage time t
ts
s
–
– Falling time
Falling time t
tf
f
–
– Turn
Turn-
-off time
off time t
toff
off
ib Ib
1
Ib
2
Ics
ic
0
0
90%Ib1
10%Ib1
90%Ics
10%Ics
t0 t1 t2 t3 t4 t5 t
t
toff
ts tf
ton
tr
td
51. Power
Electronic
s
51
1.4.3 Power metal
1.4.3 Power metal-
-oxide
oxide-
-semiconductor field
semiconductor field
effect transistor
effect transistor—
—Power MOSFET
Power MOSFET
Basic structure
Basic structure Symbol
Symbol
G
S
D
P channel
A classification
A classification
Field Effect
Field Effect
Transistor
Transistor
(FET)
(FET)
Metal
Metal-
-onside
onside-
-semiconductor FET (MOSFET)
semiconductor FET (MOSFET) Power MOSFET
Power MOSFET
Junction FET (JFET)
Junction FET (JFET) Static induction transistor (SIT)
Static induction transistor (SIT)
n channel
n channel
p channel
p channel
G
S
D
N channel
52. Power
Electronic
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52
Structures of power MOSFET
Structures of power MOSFET
Also vertical
Also vertical
structure
structure—
—VMOS
VMOS
–
– VVMOS, VDMOS
VVMOS, VDMOS
Multiple parallel
Multiple parallel
cells
cells
–
– Polygon
Polygon-
-shaped
shaped
cells
cells A structure of hexagon cells
A structure of hexagon cells
53. Power
Electronic
s
53
Physics of MOSFET operation
Physics of MOSFET operation
p-n- junction is
reverse-biased
off-state voltage
appears across
n- region
Off
Off-
-state
state
54. Power
Electronic
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54
Physics of MOSFET operation
Physics of MOSFET operation
p-n- junction is slightly
reverse biased
positive gate voltage
induces conducting
channel
drain current flows
through n- region and
conducting channel
on resistance = total
resistances of n- region,
conducting
channel,source and drain
contacts, etc.
On
On-
-state
state
56. Power
Electronic
s
56
Switching characteristics of power MOSFET
Switching characteristics of power MOSFET
Rs
RG RF
RL
iD
uGS
up
iD
+UE
iD
O
O
O
up
t
t
t
uGS
uGSP
uT
td(on) tr
td(off) tf
Turn
Turn-
-on transient
on transient
–
– Turn
Turn-
-on delay time t
on delay time td(on)
d(on)
–
– Rise time
Rise time t
tr
r
Turn
Turn-
-off transient
off transient
–
– Turn
Turn-
-off delay time t
off delay time td(off)
d(off)
–
– Falling time
Falling time t
tf
f
57. Power
Electronic
s
57
Specifications of power MOSFET
Specifications of power MOSFET
Drain
Drain-
-source breakdown voltage U
source breakdown voltage UDS
DS
Continuous drain current I
Continuous drain current ID
D
Peak pulsed drain current I
Peak pulsed drain current IDM
DM
On (On
On (On-
-state) resistance R
state) resistance RDS(on)
DS(on)
Inter
Inter-
-terminal capacitances
terminal capacitances
–
– Short circuit input capacitance
Short circuit input capacitance C
Ciss
iss=
= C
CGS
GS+
+ C
CGD
GD
–
– Reverse transfer capacitance
Reverse transfer capacitance C
Crss
rss=
= C
CGD
GD
–
– Short circuit output capacitance
Short circuit output capacitance C
Coss
oss=
= C
CDS
DS+
+ C
CGD
GD
SOA of power MOSFET
SOA of power MOSFET
–
– No second breakdown
No second breakdown
59. Power
Electronic
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59
Features and applications of power MOSFET
Features and applications of power MOSFET
Voltage
Voltage-
-driven device, simple drive circuit
driven device, simple drive circuit
Majority
Majority-
-carrier device, fast switching speed, high
carrier device, fast switching speed, high
operating frequency (could be hundreds of kHz)
operating frequency (could be hundreds of kHz)
Majority
Majority-
-carrier device, better thermal stability
carrier device, better thermal stability
On
On-
-resistance increases rapidly with rated blocking
resistance increases rapidly with rated blocking
voltage
voltage
–
– Usually used at voltages less than 500V and power less
Usually used at voltages less than 500V and power less
than 10kW
than 10kW
–
– 1000V devices are available, but are useful only at low
1000V devices are available, but are useful only at low
power levels(100W)
power levels(100W)
Part number is selected on the basis of on
Part number is selected on the basis of on-
-
resistance rather than current rating
resistance rather than current rating
60. Power
Electronic
s
60
The body diode of power MOSFET
The body diode of power MOSFET
The body diode
The body diode Equivalent circuit
Equivalent circuit
61. Power
Electronic
s
61
1.4.4
1.4.4 Insulated
Insulated-
-gate bipolar transistor
gate bipolar transistor
—
—IGBT
IGBT
Features
Features
•
• On
On-
-state losses are much smaller than those of a power
state losses are much smaller than those of a power
MOSFET, and are comparable with those of a GTR
MOSFET, and are comparable with those of a GTR
•
• Easy to drive
Easy to drive —
—similar to power MOSFET
similar to power MOSFET
•
• Faster than GTR, but slower than power MOSFET
Faster than GTR, but slower than power MOSFET
Application
Application
•
• The device of choice in 500
The device of choice in 500-
-1700V applications, at power
1700V applications, at power
levels of several kW to several MW
levels of several kW to several MW
Combination of MOSFET and GTR
Combination of MOSFET and GTR
GTR
GTR: low conduction losses (especially at larger blocking volta
: low conduction losses (especially at larger blocking voltages),
ges),
longer switching times, current
longer switching times, current-
-driven
driven
MOSFET
MOSFET: faster switching speed, easy to drive (voltage
: faster switching speed, easy to drive (voltage-
-driven),
driven),
larger conduction losses (especially for hi
larger conduction losses (especially for higher blocking voltages)
gher blocking voltages)
IGBT
IGBT
62. Power
Electronic
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62
Structure and operation principle of IGBT
Structure and operation principle of IGBT
Basic structure
Basic structure Also multiple cell structure
Also multiple cell structure
Basic structure similar to
Basic structure similar to
power MOSFET, except
power MOSFET, except
extra p region
extra p region
On
On-
-state: minority carriers
state: minority carriers
are injected into drift region,
are injected into drift region,
leading to conductivity
leading to conductivity
modulation
modulation
compared with power
compared with power
MOSFET: slower switching
MOSFET: slower switching
times, lower on
times, lower on-
-resistance,
resistance,
useful at higher voltages
useful at higher voltages
(up to 1700V)
(up to 1700V)
E G
C
N+
N-
a)
P
N+ N+
P
N+ N+
P+
Emitter Gate
Collector
Injecting layer
Buffer layer
Drift region
J3 J2
J1
63. Power
Electronic
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63
Equivalent circuit and circuit symbol of IGBT
Equivalent circuit and circuit symbol of IGBT
Equivalent circuit
Equivalent circuit Circuit symbol
Circuit symbol
G
E
C
+
-
+
-
+
-
ID
RN
IC
VJ1
ID
Ron
Drift region
resistance
G
C
E
64. Power
Electronic
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64
Static characteristics of IGBT
Static characteristics of IGBT
O
Active region
Cut-off (forward
blocking) region
Saturation region
(On region)
Reverse
blocking region
IC
URM
UFM UCE
UGE(th)
UGE
65. Power
Electronic
s
65
Switching characteristics of IGBT
Switching characteristics of IGBT
IGBT turn-on is
similar to power
MOSFET turn-on
The major
difference between
IGBT turn-off and
power MOSFET
turn-off:
– There is current
tailing in the IGBT
turn-off due to the
stored charge in
the drift region.
t
t
t
10%
90%
10%
90%
UCE
IC
0
O
0
UGE
UGEM
ICM
UCEM
tfv1 tfv2
toff
ton
tfi1
tfi2
td(off)
tf
td(on)
tr
UCE(on)
UGEM
UGEM
ICM
ICM
current tail
66. Power
Electronic
s
66
Parasitic
Parasitic thyristor
thyristor and latch
and latch-
-up in IGBT
up in IGBT
Main current path
Main current path pnp
pnp transistor and the parasitic
transistor and the parasitic npn
npn transistor
transistor
compose a parasitic
compose a parasitic thyristor
thyristor inside IGBT.
inside IGBT.
High emitter current tends to latch the parasitic
High emitter current tends to latch the parasitic thyristor
thyristor on.
on.
Modern
Modern IGBTs
IGBTs are essentially latch
are essentially latch-
-up proof
up proof
Location of equivalent devices
Location of equivalent devices Complete IGBT equivalent circuit
Complete IGBT equivalent circuit
67. Power
Electronic
s
67
Specifications of IGBT
Specifications of IGBT
Collector
Collector-
-emitter breakdown voltage U
emitter breakdown voltage UCES
CES
Continuous collector current I
Continuous collector current IC
C
Peak pulsed collector current I
Peak pulsed collector current ICM
CM
Maximum power dissipation P
Maximum power dissipation PCM
CM
Other issues:
Other issues:
SOA of IGBT
SOA of IGBT
–
– The IGBT has a rectangular SOA with similar shape to the
The IGBT has a rectangular SOA with similar shape to the
power MOSFET.
power MOSFET.
Usually fabricated with an anti
Usually fabricated with an anti-
-parallel fast diode
parallel fast diode
69. Power
Electronic
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69
1.5 Other new power electronic devices
1.5 Other new power electronic devices
Static induction transistor
Static induction transistor —
—SIT
SIT
Static induction
Static induction thyristor
thyristor —
—SITH
SITH
MOS controlled
MOS controlled thyristor
thyristor —
— MCT
MCT
Integrated gate
Integrated gate-
-commutated
commutated thyristor
thyristor —
—IGCT
IGCT
Power integrated circuit and power module
Power integrated circuit and power module
70. Power
Electronic
s
70
Static induction transistor
Static induction transistor—
—SIT
SIT
Another name: power junction field effect
Another name: power junction field effect
transistor
transistor—
—power JFET
power JFET
Features
Features
–
– Major
Major-
-carrier device
carrier device
–
– Fast switching, comparable to power MOSFET
Fast switching, comparable to power MOSFET
–
– Higher power
Higher power-
-handling capability than power MOSFET
handling capability than power MOSFET
–
– Higher conduction losses than power MOSFET
Higher conduction losses than power MOSFET
–
– Normally
Normally-
-on device, not convenient (could be made
on device, not convenient (could be made
normally
normally-
-off, but with even higher on
off, but with even higher on-
-state losses)
state losses)
71. Power
Electronic
s
71
Static induction
Static induction thyristor
thyristor—
—SITH
SITH
other names
other names
–
– Field controlled
Field controlled thyristor
thyristor—
—FCT
FCT
–
– Field controlled diode
Field controlled diode
Features
Features
–
– Minority
Minority-
-carrier device, a JFET structure with an additional
carrier device, a JFET structure with an additional
injecting layer
injecting layer
–
– Power
Power-
-handling capability similar to GTO
handling capability similar to GTO
–
– Faster switching speeds than GTO
Faster switching speeds than GTO
–
– Normally
Normally-
-on device, not convenient (could be made
on device, not convenient (could be made
normally
normally-
-off, but with even higher on
off, but with even higher on-
-state losses)
state losses)
72. Power
Electronic
s
72
MOS controlled
MOS controlled thyristor
thyristor—
—MCT
MCT
Essentially a GTO with integrated MOS
Essentially a GTO with integrated MOS-
-driven
driven
gates controlling both turn
gates controlling both turn-
-on and turn
on and turn-
-off that
off that
potentially will significantly simply the design of
potentially will significantly simply the design of
circuits using GTO.
circuits using GTO.
The difficulty is how to design a MCT that can be
The difficulty is how to design a MCT that can be
turned on and turned off equally well.
turned on and turned off equally well.
Once believed as the most promising device, but
Once believed as the most promising device, but
still not commercialized in a large scale. The future
still not commercialized in a large scale. The future
remains uncertain.
remains uncertain.
73. Power
Electronic
s
73
Integrated gate
Integrated gate-
-commutated
commutated thyristor
thyristor —
— IGCT
IGCT
The newest member of the power semiconductor
The newest member of the power semiconductor
family, introduced in 1997 by ABB
family, introduced in 1997 by ABB
Actually the close integration of GTO and the gate
Actually the close integration of GTO and the gate
drive circuit with multiple
drive circuit with multiple MOSFETs
MOSFETs in parallel
in parallel
providing the gate currents
providing the gate currents
Short name: GCT
Short name: GCT
Conduction drop, gate driver loss, and switching
Conduction drop, gate driver loss, and switching
speed are superior to GTO
speed are superior to GTO
Competing with IGBT and other new devices to
Competing with IGBT and other new devices to
replace GTO
replace GTO
74. Power
Electronic
s
74
Power integrated circuit and power module
Power integrated circuit and power module
Two major challenges
Two major challenges
–
– Electrical isolation of high
Electrical isolation of high-
-voltage components from low
voltage components from low-
-
voltage components
voltage components
–
– Thermal management
Thermal management—
—power devices usually at higher
power devices usually at higher
temperatures than low
temperatures than low-
-voltage devices
voltage devices
Integration of
power electronic
devices
Monolithic integration:
Monolithic integration:
power integrated circuit
power integrated circuit
Packaging integration:
Packaging integration:
power module
power module
Smart power integrated circuit(Smart
power IC, SPIC, Smart switch)
High voltage integrated circuit (HVIC)
Ordinary power module:just power
devices packaged together
Integrated power electronics
Module(IPEM): power devices, drive
circuit, protection circuit, control circuit
Intelligent power module (IPM):
power devices, drive circuit, protection
circuit
75. Power
Electronic
s
75
Review of device classifications
Review of device classifications
power electronic
power electronic
devices
devices
Pulse
Pulse-
-triggered devices:
triggered devices: thyristor
thyristor, GTO
, GTO
Level
Level-
-sensitive (Level
sensitive (Level-
-triggered) devices:
triggered) devices:
GTR,power MOSFET, IGBT, SIT, SITH,
GTR,power MOSFET, IGBT, SIT, SITH,
MCT, IGCT
MCT, IGCT
power electronic
power electronic
devices
devices
power electronic
power electronic
devices
devices
Current
Current-
-driven (current
driven (current-
-controlled) devices:
controlled) devices:
thyristor, GTO, GTR
Voltage
Voltage-
-driven (voltage
driven (voltage-
-controlled) devices
controlled) devices
(Field
(Field-
-controlled devices):power MOSFET,
controlled devices):power MOSFET,
IGBT, SIT, SITH, MCT, IGCT
IGBT, SIT, SITH, MCT, IGCT
Uni
Uni-
-polar devices (Majority carrier devices):
polar devices (Majority carrier devices):
SBD, power MOSFET, SIT
SBD, power MOSFET, SIT
Composite devices: IGBT, SITH, MCT
Composite devices: IGBT, SITH, MCT
Bipolar devices (Minority
Bipolar devices (Minority carrier devices):
carrier devices):
ordinary power diode,
ordinary power diode, thyristor
thyristor, GTO, GTR,
, GTO, GTR,
IGCT, IGBT, SITH, MCT
IGCT, IGBT, SITH, MCT
76. Power
Electronic
s
76
Comparison of the major types of devices
Comparison of the major types of devices
Power
Power-
-handling capability
handling capability
77. Power
Electronic
s
77
Comparison of the major types of devices
Comparison of the major types of devices
Maximum allowed current density as a function of
Maximum allowed current density as a function of
the switching frequency
the switching frequency