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Keon Jae Lee
This course aims to provide a general understanding of semiconductor devices. This coures covers the Metal-Semiconductor Contact, Metal-Oxide-Semiconductor (MOS) capapcitor, Metal-Oxide-Semiconductor Field Effect Transistors(MOSFETs), CMOS, Metal-Semiconductor Field Effect Transistors(MESFETs), Memory and Bipolar Junction Transistor (BJT) to improve the overall knowledge of semiconductor industry.
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This course aims to provide a general understanding of semiconductor devices. This coures covers the Metal-Semiconductor Contact, Metal-Oxide-Semiconductor (MOS) capapcitor, Metal-Oxide-Semiconductor Field Effect Transistors(MOSFETs), CMOS, Metal-Semiconductor Field Effect Transistors(MESFETs), Memory and Bipolar Junction Transistor (BJT) to improve the overall knowledge of semiconductor industry.
Read more
This course aims to provide a general understanding of semiconductor devices. This coures covers the Metal-Semiconductor Contact, Metal-Oxide-Semiconductor (MOS) capapcitor, Metal-Oxide-Semiconductor Field Effect Transistors(MOSFETs), CMOS, Metal-Semiconductor Field Effect Transistors(MESFETs), Memory and Bipolar Junction Transistor (BJT) to improve the overall knowledge of semiconductor industry.
The lecture notes can be downloaded with registration, that helps students watch the videos. It is recommeded to print them in two pages in one A4 sheet and take notes during lectures for better understanding. Also, there are quiz problems to check your understanding of the lectures each week. To receive course certificate, you must score at least 60% of each week's quiz withing two chances.
Lecture notes, quiz and certificate are offered to registered students only.
week 1 Metal-Semiconductor Contact (Schottky/Ohmic contacts)
week 2 Metal-Oxide-Semiconductor(MOS) Capacitor
week 3 MOS Field Effect Transistors(MOSFETs)
week 4 CMOS, CMOS logic (Inverter, NAND & NOR gate)
week 5 Memory, Optoelectronic Devices
week 6 MESFETs, Bipolar Junction Transistors, Modern MOSFET
Register for this course and see more details by visiting:
OpenCourser.com/course/uggtp2/introduction
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What's inside
Syllabus
Week 1 Metal-Semiconductor Contact
Week 2 MOS Capacitor
Week 3 MOSFETs
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Syllabus
Week 1 Metal-Semiconductor Contact
Week 2 MOS Capacitor
Week 3 MOSFETs
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Traffic lights
Traffic lights
Read about what's good
what should give you pause and
possible dealbreakers
Engineers working with semiconductor industries will benefit from taking this course
Taught by Keon Jae Lee, who is recognized for their work in the topic that the course teaches
Teaches Metal-Semiconductor Contact (Schottky/Ohmic contacts), which is standard in the semiconductor industry
Teaches Metal-Oxide-Semiconductor (MOS) Capacitor, which is standard in the semiconductor industry
Teaches MOS Field Effect Transistors(MOSFETs), which is standard in the semiconductor industry
Teaches CMOS logic, which is standard in the semiconductor industry
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Reviews summary
Comprehensive semiconductor device theory
According to students, this course offers a comprehensive and well-structured deep dive into semiconductor devices, serving as an excellent continuation from its predecessor. Learners widely praise the instructor's expertise and ability to clearly explain complex concepts like MOSFETs and CMOS logic. The detailed lecture notes are consistently highlighted as an essential resource for comprehension. While the course provides thorough coverage of fundamental theory, some learners noted the pacing can be fast for certain advanced topics, and it assumes a solid background in the subject. A few reviews also suggest it is more theory-heavy and could benefit from additional hands-on or simulation elements, though its strong theoretical foundation is largely appreciated.
Quizzes are useful for checking understanding, though some found them basic.
"The quizzes were challenging but fair, really solidifying my understanding."
"Quizzes were good for self-assessment."
"The quizzes didn't always reflect the depth of the lectures. The quizzes felt a bit basic for some complex topics."
Provides a deep, theory-driven understanding of device physics.
"The course provides a deep dive into semiconductor devices. Every topic... was covered thoroughly."
"It's theory-heavy, which is good for understanding fundamentals..."
"It's definitely a course for those who are serious about the theory and underlying physics of devices."
Provided lecture notes are crucial for following the course content.
"The lecture notes are definitely a must-have for following along."
"The lecture notes provided were essential."
"The PDF notes are crucial. The lecture notes are a lifesaver."
The instructor excels at clarifying complex semiconductor topics.
"The instructor explains complex concepts like MOSFETs and CMOS logic very clearly."
"The instructor's delivery is clear and easy to follow, making even difficult topics accessible."
"The instructor's clear explanations made it very easy to grasp complex ideas."
Some advanced topics felt rushed or lacked sufficient depth.
"Some of the later topics, like short channel effects, could have used a bit more depth..."
"I found the pacing a bit fast, and some of the later topics like Memory and Optoelectronic Devices felt rushed."
"The explanations were not always clear to me, and I felt like it jumped into complex topics too quickly."
Requires a solid foundational understanding of semiconductor physics.
"This course assumes a solid background."
"I think for someone without a strong prior background, this would be very challenging. Not for beginners."
"I struggled with this course. I needed to spend a lot of time searching for supplementary material to keep up."
Activities
Be better prepared
before
your course. Deepen your understanding
during
and
after
it. Supplement your coursework and achieve mastery of the topics covered
in Introduction to Semiconductor Devices 2 with these
activities:
Identify mentors in the field of semiconductor devices
Show steps
Establish connections with experts to gain guidance and insights into the field.
Show steps
-
Attend industry events, conferences, or workshops.
-
Reach out to professors, researchers, or engineers in the field.
-
Build relationships and seek their mentorship.
Review basic electronics concepts
Show steps
Strengthen foundational knowledge in electronics to enhance understanding of semiconductor devices.
Browse courses on
Electronics
Show steps
-
Review textbooks or online resources on basic electronics concepts.
-
Solve practice problems related to circuit analysis and transistor behavior.
-
Build simple electronic circuits to reinforce concepts.
Solve semiconductor device physics problems
Show steps
Strengthen your understanding of the fundamental principles governing semiconductor devices.
Show steps
-
Review textbook material and lecture notes on semiconductor device physics.
-
Find practice problems online or in textbooks.
-
Solve the problems and check your answers.
Three other activities
Expand to see all activities and additional details
Show all six activities
Participate in study groups or online forums
Show steps
Engage with peers to discuss concepts, solve problems, and share insights.
Show steps
-
Find or create study groups with classmates or online forums dedicated to semiconductor devices.
-
Actively participate in discussions, ask questions, and share your own knowledge.
-
Collaborate on problem-solving and assignments.
Solve practice problems on semiconductor device simulations
Show steps
Practice using TCAD tools and understand the underlying principles of semiconductor device operation.
Show steps
-
Find online tutorials or courses on semiconductor device simulation.
-
Follow the tutorials and complete the practice problems.
-
Troubleshoot any errors or difficulties you encounter.
Create a presentation on a specific semiconductor device
Show steps
Develop a deep understanding of the operation and applications of a particular semiconductor device.
Browse courses on
Semiconductor Devices
Show steps
-
Choose a semiconductor device to focus on.
-
Research the device's structure, operation, and applications.
-
Create a presentation that clearly explains the device's key features and uses.
Identify mentors in the field of semiconductor devices
Show steps
Establish connections with experts to gain guidance and insights into the field.
Show steps
Show steps
Show steps
- Attend industry events, conferences, or workshops.
- Reach out to professors, researchers, or engineers in the field.
- Build relationships and seek their mentorship.
Review basic electronics concepts
Show steps
Strengthen foundational knowledge in electronics to enhance understanding of semiconductor devices.
Browse courses on
Electronics
Show steps
Show steps
Show steps
- Review textbooks or online resources on basic electronics concepts.
- Solve practice problems related to circuit analysis and transistor behavior.
- Build simple electronic circuits to reinforce concepts.
Solve semiconductor device physics problems
Show steps
Strengthen your understanding of the fundamental principles governing semiconductor devices.
Show steps
Show steps
Show steps
- Review textbook material and lecture notes on semiconductor device physics.
- Find practice problems online or in textbooks.
- Solve the problems and check your answers.
Three other activities
Expand to see all activities and additional details
Show all six activities
Participate in study groups or online forums
Show steps
Engage with peers to discuss concepts, solve problems, and share insights.
Show steps
Show steps
Show steps
- Find or create study groups with classmates or online forums dedicated to semiconductor devices.
- Actively participate in discussions, ask questions, and share your own knowledge.
- Collaborate on problem-solving and assignments.
Solve practice problems on semiconductor device simulations
Show steps
Practice using TCAD tools and understand the underlying principles of semiconductor device operation.
Show steps
Show steps
Show steps
- Find online tutorials or courses on semiconductor device simulation.
- Follow the tutorials and complete the practice problems.
- Troubleshoot any errors or difficulties you encounter.
Create a presentation on a specific semiconductor device
Show steps
Develop a deep understanding of the operation and applications of a particular semiconductor device.
Browse courses on
Semiconductor Devices
Show steps
Show steps
Show steps
- Choose a semiconductor device to focus on.
- Research the device's structure, operation, and applications.
- Create a presentation that clearly explains the device's key features and uses.
Career center
Learners who complete Introduction to Semiconductor Devices 2 will develop knowledge and skills
that may be useful to these careers:
Nanotechnology Engineer
Nanotechnology Engineer
Nanotechnology Engineers research and develop materials, devices, and systems at the nanoscale. The work you do can have applications in a wide range of fields, including electronics, medicine, and manufacturing. Introduction to Semiconductor Devices 2 can help you build a foundation for this exciting and growing field.
Semiconductor Device Physicist
Semiconductor Device Physicist
Semiconductor Device Physicists research and develop new semiconductor devices, such as transistors and integrated circuits. This work is essential for the advancement of modern electronics. Introduction to Semiconductor Devices 2 can provide you with the foundational knowledge you need to succeed in this field.
Semiconductor Process Engineer
Semiconductor Process Engineer
Semiconductor Process Engineers develop and improve the manufacturing processes used to produce semiconductor devices. Your work can help to increase the yield and quality of these devices.
Electronic Engineer
Electronic Engineer
Electronic Engineers design and develop electronic circuits and systems. This work can be applied to a wide range of industries, including consumer electronics, telecommunications, and aerospace. Introduction to Semiconductor Devices 2 can help you build a foundation for a successful career in this field.
Materials Scientist
Materials Scientist
Materials Scientists research and develop new materials for use in a variety of applications. This work can have applications in a wide range of fields, including electronics, energy, and medicine. Introduction to Semiconductor Devices 2 can help you build a foundation for this exciting and growing field.
Optical Engineer
Optical Engineer
Optical Engineers design and develop optical systems and devices. This work can have applications in a wide range of fields, including telecommunications, medicine, and manufacturing. Introduction to Semiconductor Devices 2 can help you build a foundation for this exciting and growing field.
Nuclear Engineer
Nuclear Engineer
Nuclear Engineers design and develop nuclear reactors and other nuclear systems. This work is essential for the production of nuclear power and the development of nuclear weapons. Introduction to Semiconductor Devices 2 may be useful for understanding the nuclear industry.
Biomedical Engineer
Biomedical Engineer
Biomedical Engineers design and develop medical devices and systems. This work can have applications in a wide range of fields, including medical imaging, diagnostics, and treatment. Introduction to Semiconductor Devices 2 may be useful for understanding the semiconductor devices used in medical equipment.
Chemical Engineer
Chemical Engineer
Chemical Engineers design and develop chemical processes and systems. This work can have applications in a wide range of fields, including the production of chemicals, pharmaceuticals, and food. Introduction to Semiconductor Devices 2 may be useful for understanding the semiconductor devices used in chemical processing equipment.
Computer Engineer
Computer Engineer
Computer Engineers design and develop computer systems. This work can have applications in a wide range of fields, including software development, hardware design, and networking. Introduction to Semiconductor Devices 2 may be useful for understanding the semiconductor devices used in computer systems.
Electrical Engineer
Electrical Engineer
Electrical Engineers design and develop electrical systems. This work can have applications in a wide range of fields, including power generation, distribution, and utilization. Introduction to Semiconductor Devices 2 may be useful for understanding the semiconductor devices used in electrical systems.
Industrial Engineer
Industrial Engineer
Industrial Engineers design and develop industrial processes and systems. This work can have applications in a wide range of fields, including manufacturing, transportation, and healthcare. Introduction to Semiconductor Devices 2 may be useful for understanding the semiconductor devices used in industrial equipment.
Mechanical Engineer
Mechanical Engineer
Mechanical Engineers design and develop mechanical systems. This work can have applications in a wide range of fields, including manufacturing, transportation, and robotics. Introduction to Semiconductor Devices 2 may be useful for understanding the semiconductor devices used in mechanical systems.
Software Engineer
Software Engineer
Software Engineers design and develop software systems. This work can have applications in a wide range of fields, including web development, mobile development, and game development. Introduction to Semiconductor Devices 2 may be useful for understanding the semiconductor devices used in computer systems.
Systems Engineer
Systems Engineer
Systems Engineers design and develop systems that integrate hardware and software. This work can have applications in a wide range of fields, including telecommunications, aerospace, and defense. Introduction to Semiconductor Devices 2 may be useful for understanding the semiconductor devices used in systems.
For more career information including salaries, visit:
OpenCourser.com/course/uggtp2/introduction
Reading list
We've selected 14 books
that we think will supplement your
learning. Use these to
develop background knowledge, enrich your coursework, and gain a
deeper understanding of the topics covered in
Introduction to Semiconductor Devices 2.
This comprehensive textbook provides a thorough grounding in the fundamentals of semiconductor devices, making it an excellent companion to the course. It delves into the physics and operation of diodes, transistors, and integrated circuits, providing a deep understanding of the underlying principles.
Provides a comprehensive overview of semiconductor devices, including their physics, technology, and applications. It valuable resource for students and professionals who want to learn more about this field.
This classic textbook provides an in-depth treatment of the physics and operation of semiconductor devices. It offers a comprehensive understanding of the fundamental principles and valuable reference for advanced study in this field.
Provides a detailed overview of microelectronic circuits. It valuable resource for students who want to learn more about this field.
This textbook focuses on the design and fabrication of modern semiconductor devices used in integrated circuits. It provides insights into the latest advancements and challenges in the field, complementing the course's coverage of device technologies.
This comprehensive resource provides a practical guide to characterizing semiconductor materials and devices. It offers valuable insights into experimental techniques and data analysis, enhancing the understanding of device behavior and performance.
Provides a clear and concise introduction to the basic principles of semiconductor devices. It valuable resource for students who are new to this field.
Provides a comprehensive overview of the physics of solar cells, which are optoelectronic devices.
This widely used textbook covers the fundamentals of electronic devices and circuit theory. It provides a comprehensive overview of the subject matter, including semiconductor devices, and complements the course's focus on device principles and applications.
This textbook offers a comprehensive introduction to microelectronic circuits and devices. It provides a solid foundation for understanding the design and analysis of analog and digital circuits, complementing the course's focus on semiconductor device applications.
This textbook provides a clear and concise introduction to semiconductor physics and devices. It offers a comprehensive overview of the subject matter, including semiconductor materials, devices, and applications.
This textbook covers the fundamentals of solid-state electronic devices. It provides a comprehensive overview of the subject matter, including semiconductor materials, devices, and applications.
This textbook focuses on the design and fabrication of semiconductor devices used in integrated circuits. It provides insights into the latest advancements and challenges in the field, complementing the course's coverage of device technologies.
This textbook provides an introduction to semiconductor optoelectronics. It covers the basic principles of light emission and detection in semiconductor devices, complementing the course's coverage of optoelectronic devices.
For more information about how these books relate to this course, visit:
OpenCourser.com/course/uggtp2/introduction
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Effort
2-4 hours/week
Level
Intermediate
Via
Coursera
Institution
Korea Advanced Institute of Science and Technology(KAIST)
Instructor
Keon Jae Lee
Language
English
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