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Updated in [September 27th, 2023]
What does this course tell?
(Please note that the following overview content is from the original platform)In this course we cover the basics of NMOS and CMOS Digital Integrated Circuit Design If you are looking for an introduction to this subject then this is the course for youWe start with a look at some device physics This will allow us to be introduced to some terminology and will set the foundations for the rest of the course We then move onto device fabrication and layout which will be covered more extensively when we look at designing and simulating our circuits in an Electronic Design Automation tool (EDA) called Electric which you can download for free and give it a go yourselfWe then look at deriving some equations that allow us to understand and use the MOSFET (Metal Oxide Field Effect Transistors) transistors to build useful digital logic circuits We then cement our understanding of the 4 device types depletion and enhancement nmos and pmos devices using a simple simulation which I built myself which gives a good intuitive understanding of the MOSFET Then we move onto simple pass transistor circuits which allow us to get used to the transistor equations and will also help us with an understanding of dynamic logicWe cover the Inverter (NOT gate) in detail as we will use this as the building block for many future circuitsWe then come to the section on NMOS circuit design where we design simple building blocks such as NOR and NAND gates and other simple gates and random combinational logic culminating in the full adder circuit The next section covers CMOS circuit design and again we work through the design of the basic logic building blocks culminating in a full adder circuitThe final section covers the EDA tool called electric in which we design and layout our CMOS circuits finishing off with a full adder circuitI have spent 7 years after graduation as an Integrated Circuit Designer with a world leading design house I also have spent 4 years with a company with its own wafer fabrication plant which allowed me to not only design the integrated circuits (chips) but also follow the production process and to work through the full characterisation then implementation of the chip into a customers system So I have worked through several end to end life cycles of chips that are out there and working now
We considered the value of this course from many aspects, and finally summarized it for you from two aspects: skills and knowledge, and the people who benefit from it:
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What skills and knowledge will you acquire during this course?
During this course on CMOS Digital Integrated Circuit Design, students will acquire the following skills and knowledge:
1. Understanding of device physics: Students will learn the basics of NMOS and CMOS transistors, including their operation and characteristics. This knowledge will provide a foundation for the rest of the course.
2. Device fabrication and layout: Students will gain an understanding of the process of fabricating integrated circuits and the layout considerations involved. They will also learn how to use the Electric Electronic Design Automation (EDA) tool for designing and simulating circuits.
3. Equations for MOSFETs: Students will derive and learn to use equations that describe the behavior of MOSFETs. This knowledge will enable them to design and analyze digital logic circuits using MOSFETs.
4. Understanding of depletion and enhancement NMOS and PMOS devices: Students will develop an intuitive understanding of the different types of MOSFETs through a simple simulation. This understanding will be crucial for designing more complex circuits.
5. Pass transistor circuits: Students will learn about pass transistor circuits, which will help them gain familiarity with transistor equations and dynamic logic.
6. Inverter (NOT gate) design: The course will cover the design of inverters in detail, as they serve as the building blocks for many other circuits. Students will learn how to design and analyze inverters.
7. NMOS circuit design: Students will design various building blocks such as NOR and NAND gates, as well as random combinational logic circuits. The culmination of this section will be the design of a full adder circuit.
8. CMOS circuit design: The course will also cover CMOS circuit design, where students will learn to design basic logic building blocks using CMOS technology. They will then apply this knowledge to design a full adder circuit.
9. Use of the Electric EDA tool: The final section of the course will focus on using the Electric EDA tool for designing and layout of CMOS circuits. Students will gain hands-on experience by designing a full adder circuit using this tool.
Who will benefit from this course?
This course on CMOS Digital Integrated Circuit Design will benefit individuals who are interested in or pursuing a career in the field of integrated circuit design. It is particularly suitable for those who are looking for an introduction to the subject.
Professionals in the semiconductor industry, such as integrated circuit designers, electronic engineers, and electrical engineers, will find this course valuable. It provides a comprehensive understanding of the basics of NMOS and CMOS digital integrated circuit design, including device physics, fabrication, layout, and simulation using an Electronic Design Automation (EDA) tool.
The course is also beneficial for individuals involved in the production process of integrated circuits, as it covers the entire life cycle of chip development, from design to implementation. This includes professionals working in wafer fabrication plants and those involved in chip characterization and integration into customer systems.
Course Syllabus
Introduction
Semiconductor Device Physics
Transistor Equations
MOSFET Simulations
Pass Transistors
The Inverter
NMOS Pull Down Logic Circuits
CMOS Static Logic Circuits
Electronic Design Automation with Electric (EDA)
CMOS Combinational Logic