Elective Courses | 电子与技术硕士

Mathematical Methods

Fri, 01 Jan 2021 00:00:00 +0000

Course overview

The aim of this course is to foster and promote knowledge of complex value functions, Fourier transform, Laplace transform, the founder and solution of mathematical and physics equations.The course covers the analysis of complex value functions, calculating some complex integrals with residues, character of special functions, for example, Bessel function, associate Legendre function, and the special Bessel functions. It also discussed the some solution of partial differential equations.

What you will learn

Meet your instructor

Youlin Geng

Course content

Session 1：Complex number and complex variable function (Part 1)
Session 2：Scalar fields and multivalued functions (Part 2)
Session 3：Integral of complex functions
Session 4：Power series expansion of complex functions
Session 5：Computer of residue series
Session 6: Fourier Transform
Session 7: Laplace Transform
Session 8: Founder of Mathematical and Physics Equation
Session 9: The solution of separated variable method to the Mathematical and Physics Equation
Session 10：Series solution of second order ordinary differential equation, eigenvalue problem
Session 11：Spherical functions
Session 12：Cylinder functions
Session 13：Green functions method
Session 14：Integral transformation

Teaching methodology

Lectures, group discussion for problem solving, project-based learning

Assessment

Midterm exam (40%) Will include combination of numerical exercises and open-ended theoretical questions.
Final written exam (60%) Will include combination of numerical exercises and theoretical questions

Analog IC Design

Fri, 01 Jan 2021 00:00:00 +0000

Course overview

The aim of this course is to Using the theoretical knowledge to complete basic unit circuit design. The course covers Analog integrated circuit design basic knowledge and Provide basic theoretical simulation, analog hybrid. Using the theoretical knowledge to complete basic unit circuit design.

What you will learn

Analyze the basic principle of integrated circuit components structure
Analyze basic unit circuit with the theoretical knowledge
Identify and summarize common problems in the integrated circuit process technology
Explain the basics theory of analog circuit devices

Meet your instructor

Xiaofei Kuang

Course content

Session 1: Introduction to Microelectronics
Session 2: Physics of MOS Transistors
Session 3: Pn section, transistor, MOS tube
Session 4: CMOS amplifiers
Session 5: Differential Amplifiers
Session 6: Cascode Differential
Session 7: Common-mode Rejection
Session 8: Differential Pair with Active Load
Session 9: Frequency Response
Session 10: Frequency Response of CS stages
Session 11: Frequency Response of CG stages
Session 12: Frequency Response of Followers
Session 13: Feedback Topologies

Teaching methodology

Presentation, group discussion, and case study.

Assessment

Midterm exam (40%) Will include combination of numerical exercises and open-ended theoretical questions.
Final written exam (60%) Will include combination of numerical exercises and open-ended theoretical questions.

Semiconductor Physics and Devices

Fri, 01 Jan 2021 00:00:00 +0000

Course overview

The aim of this course is to enable students to master the basic theory of semiconductor physics and main properties of semiconductor, and to lay a necessary professional foundation for the development and design of semiconductor devices and electronic systems and related scientific research work. The course covers crystal structure, carrier modeling, carrier action, pn Junction electrostatics, I-V Characteristics of pn junction diode, optoelectronic diodes, BJT fundamentals, MS Contacts and Schottky diodes.

What you will learn

Analyze the physical mechanism of silicon and other semiconductors
Identify and summarize the main factors affecting device characteristics and common non-ideal effects in transistors
Propose and formulate solutions for common problems of semiconductor devices including modulation and improvement of performance
Assess proposed solutions related to semiconductor devices including modulation and improvement of performance

Meet your instructor

Zhangting Wu

Course content

Session 1: A General introduction of Semiconductors
Session 2: Carrier Modeling (part 1)
Session 3: Carrier Modeling (part 2)
Session 4: Carrier Action (part 1)
Session 5: Carrier Action (part 2)
Session 6: pn Junction Electrostatics
Session 7: pn Junction Diode: I—V Characteristics (part 1)
Session 8: pn Junction Diode: I—V Characteristics (part 2)
Session 9: Optoelectronic Diodes (part 1)
Session 10: Optoelectronic Diodes (part 2)
Session 11: BJT Fundamentals
Session 12: MS Contacts and Schottky Diodes
Session 13: MOS Fundamentals

Teaching methodology

Lectures, group discussion for problem solving, collaborative learning, independent learning

Assessment

Class Performance (40%) Will include homework and discussion
Final written exam (60%) Will include Short Answers and Calculations

VLSI Design

Fri, 01 Jan 2021 00:00:00 +0000

Course overview

The aim of this course is to help the graduate students to obtain the basic theory and methodology of CMOS digital integrated circuit design. The course covers the basic theory and design method of CMOS device, logic gate, combinational logic, sequential machine and digital system. The course also introduces the design flow of VLSI from RTL to GDSII.

What you will learn

Analyze and design of logic gate, combinational logic, sequential machine and simple digital system
Analyze and design the structure of complex digital system
Master the design flow of VLSI from RTL to GDSII
Experiment the system design or RTL design of a digital chip

Meet your instructor

Qi Ma

Course content

Session 1: Introduction
Session 2: CMOS process technologies and device characteristics
Session 3: Logic gate
Session 4: Combinational logic network
Session 5: Sequential machine
Session 6: Digital system
Session 7: Introduction to VLSI design flow
Session 8: System design (Part 1)
Session 9: System design (Part 2)
Session 10: RTL design (Part 2)
Session 11: RTL design (Part 2)
Session 12: Logic design and Layout design
Session 13: SoC design methodology based on IP.

Teaching methodology

Lectures, discussing, and independent learning

Assessment

Assignments (30%) Written assignments throughout the course.
Final examination （70%） Will include combination of numerical exercises and open-ended theoretical questions.

RF IC Design

Fri, 01 Jan 2021 00:00:00 +0000

Course overview

The aim of this course is foster and promote knowledge of RF/microwave integrated circuits and systems. The course covers the design and performance analysis of common methods microwave/RF integrated circuits and systems.

What you will learn

Analyze complex modern RF/microwave integrated circuits systems
Understand and use the basic concepts of RF/microwave integrated circuits and systems
Propose and formulate solutions for microwave/RF integrated circuits.
Identify the unit modules in the RF front-end circuit
Arrange common EDA tools to design circuits

Meet your instructor

LinglingSUN

Course content

Session 1: the basics of RFIC
Session 2: Introduction of wireless transceiver
Session 3: analysis and design of LNA (part 1)
Session 4: analysis and design of LNA (part 2)
Session 5: analysis and design of PA (part 1)
Session 6: analysis and design of PA (part 2)
Session 7: VCO design and phase noise analysis (part 1)
Session 8: VCO design and phase noise analysis (part 2)
Session 9: PLL analysis and design (part 1)
Session 10: PLL analysis and design (part 2)
Session 11: analysis and design of mixer
Session 12: the measurement of RFIC
Session 13: Practical examples

Teaching methodology

Lectures, group discussion for problem solving, collaborative learning

Assessment

Assignments (30%) Written assignements throughout the course.
final exam (70%) Will include combination of numerical exercises and open-ended theoretical questions

Electronic System Design

Fri, 01 Jan 2021 00:00:00 +0000

Course overview

The aim of this course is to understand and master the general methods and skills of electronic system design. The course covers systematic to study of integrated operational amplifiers, power semiconductor devices, new semiconductor sensors, new integrated circuits, data communication technology, power system design, filter design, Multisim circuit simulation technology, electronic system design example analysis.

What you will learn

Master the ability of comprehensive design of general electronic system.
Analyze of relevant cases of integrated circuits and semiconductors,
Understand the application of integrated circuits and semiconductors in automotive electronics and industrial automation control system,
Identify and summarize common problems in electronic system design.
Evaluate and assess the performance of proposed solutions related to electronic system.

Meet your instructor

Mingyu Gao

Course content

Session 1: Operational amplifiers
Session 2: Amplification circuit design (part 1)
Session 3: Amplification circuit design (part 2)
Session 4: Power semiconductor devices
Session 5: Power system design
Session 6: Semiconductor sensor and filter design
Session 7: MCU / ARM (part 1)
Session 8: MCU / ARM (part 2)
Session 9: A / D and D / A conversion circuit design (part 1)
Session 10: A / D and D / A conversion circuit design (part 2)
Session 11: Communication circuit design
Session 12: Circuit simulation technologies based on Multisim
Session 13: Examples of integrated electronic system design.

Teaching methodology

Lectures, group discussion for problem solving, collaborative learning, independent learning

Assessment

Assignments (40%) Written assignements throughout the course.
Final examination （60%） Will include combination of numerical exercises and open-ended theoretical questions.

Analogue and Mixed IC Design

Fri, 01 Jan 2021 00:00:00 +0000

Course overview

The aim of this course is to establish a theoretical foundation and gradually master the methodology of analog and mixed IC design for students. The course covers the basic knowledge of analog integrated circuit design and the course design. The first aspect is the basis theory of electric circuit, including the background and development of analog and mixed-signal integrated circuit, CMOS integrated circuit technology and active device, single stage amplifier, differential amplifier, current mirror, active load and voltage reference circuit, output stage, operational amplifier. The other aspect is the course design, including designing and simulating a module of integrated circuit according to circuit requirements

What you will learn

Analyze complex analog and mixed-signal integrated circuit
Design integrated circuit according to circuit requirements
Master expertly the use of EDA software to simulate integrated circuits
Evaluate and assess the performance of analog and mixed-signal integrated circuit

Meet your instructor

Hui Hong

Course content

Session 1: Background and design process
Session 2: CMOS technology
Session 3: Single transistor amplifier
Session 4: Differential amplifier
Session 5: Current sink and current mirror
Session 6: Voltage and current reference
Session 7: Output stage
Session 8: CMOS amplifier design
Session 9: Frequency Response of Amplifiers
Session 10: Op-Amps characteristics and frequency compensation
Session 11: Course design
Session 12: Course design
Session 13: Course design

Teaching methodology

Presentations, group discussions, case studies.

Assessment

In-class assessment (30%) Will include combination of regular discussions, classroom questioning, etc.
Design project (70%) Will include combination of circuit design and design report.