Microelectronics Science and engineering is a multidisciplinary and high technology-intensive major. It is an applied interdisciplinary discipline developed based on physics, electronics, computer science, semiconductor material science, microelectronics and other disciplines. It is the forerunning and core of electronic information science and technology and is known as the heart of the modern information industry and the driving force of high technology. It is of great strategic significance to national economic development and national security. This major establishes circuit devices, analog integrated circuit design, digitally integrated circuit design, photoelectric integration and other professional course modules, through the combination of theory and practice training modes, to train talents who can engage in integrated circuit-related engineering research, development, design, manufacturing and operation management.

Principle and Application of Sensors

Credits 2

Class hour 32

Course number：1709087

Principle and Application of Sensors is an important professional elective course for Microelectronics Science and Engineering specialty students, required to master the sensing mechanism, composition, structure, measurement circuit and application methods of some sensors, understand the basic knowledge of new sensors, and know the development path and direction of modern sensors.

Signals and Systems

Credits 3.5

Class hour 56

Course number：1709058

The contents of Signals and Systems include the definition and classification of signals and systems, operation rules of signals, typical signal, characteristics of systems and the mathematical module of systems. Signals and systems can be analyzed in time domain, frequency domain, S domain which is for continuous signals and systems, and Z domain which is for discrete signals and systems. The overall structure of this course is including two equations (Differential Equations of Continuous Systems and Difference Equations of Discrete Systems), three transformations (Fourier Transformation，Laplace Transformation，and Z Transformation) and two analysis methods (Port Analysis Method and Status Variables Analysis Method).

Solid State Physics

Credits 3.5

Class hour 56

Course number：  2109053

Solid state physics is a fundamental course in physics, microelectronics science and engineering, electronic science and technology, and other related majors, closely related to the physical properties of materials in real life. This course aims to cultivate students' rigorous logical thinking ability, problem-solving ability, and improve their professional comprehensive quality by establishing and continuously modifying physical models and applying theories to explain the emergence of physical phenomena. The course task is to enable students to master the basic laws and concepts of solid-state physics, learn unique methods for dealing with solid-state physics problems, lay the necessary theoretical foundation for subsequent course learning, and cultivate students' comprehensive ability to analyze and solve problems. Through the study of this course, it is helpful to expand the breadth and depth of students' knowledge, and systematically grasp the structure, physical properties, and theoretical explanations of solid materials. Through course learning, students have laid an important foundation for their future work in materials science, microelectronics, electronic science and technology, and related disciplines.

Integrated Circuit Manufacturing Technology

Credits 3.0

Class hour 48

Course number：2109033

Integrated Circuit Manufacturing Technology is a compulsory course for the major of microelectronics science and technology, and is a leading course for courses such as device simulation and process simulation. This course mainly studies the principles and technologies involved in integrated circuit manufacturing, such as materials, epitaxy, oxidation, doping, lithography, and micro pattern processing, and is familiar with the manufacturing process of bipolar and MOS integrated circuits; Through the study of this course, students will have a preliminary understanding of the characteristics of integrated circuit manufacturing processes; Master the manufacturing process and basic manufacturing methods of integrated circuits, and possess preliminary process knowledge to lay a foundation for further research on integrated circuit manufacturing.

Semiconductor Physics and Devices

Credits 4

Class hour 64

Course number 2109505

semiconductor physics and devices is an important professional elective courses for the microelectronics science and engineering specialty students, required to master the basic principle of microelectronics science, include the quantum mechanics, solid-state physics, semiconductor material physics, and semiconductor device physics, especially learning how to use use semiconductor theory to solve practical problems。

Quantum Mechanics Fundamentals

Credits: 3

Class hours: 48

Course number: 1709009

Quantum Mechanics Fundamentals is a crucial elective course designed for students specializing in physics and quantum science. This course aims to provide students with a profound understanding of the fundamental principles of quantum mechanics. Topics covered include wave-particle duality, Schrödinger's equation, quantum states, and operators. Students will also delve into applications of quantum mechanics in modern technology, including quantum computing and quantum information theory.

Electromagnetic Fields and Waves

Credits 3  

Class hour 48   

Course number 1709053

Starting from vector analysis and field theory, 《Electromagnetic Fields and Waves》focuses on discussing the basic theories of electromagnetism and electromagnetic engineering. The basic theory of electromagnetism mainly includes the basic laws of electrostatic field, constant electric field, constant magnetic field, and time-varying electromagnetic field, as well as the basic concepts of electromagnetic waves and the propagation characteristics of planar electromagnetic waves in different media; The basic part of electromagnetic engineering mainly includes the theory and application of guided electromagnetic waves and antenna radiation. This course focuses on a more in-depth introduction to guided electromagnetic waves, including the transmission characteristics and modes of electromagnetic waves in rectangular waveguides, circular waveguides, resonant cavities, and coaxial lines.

Principle of Integrated Circuits

Credits 3

Class hour 48

Course number 2109053

Principle of Integrated Circuits is a backbone course for microelectronics majors, focusing on the design technology of ultra-large-scale integrated circuits, suitable for undergraduate and graduate students in electronics and computer related majors, and also suitable for engineers who need to review professional basic knowledge after work. The teaching content of the course is the basic theory and basic method of VLSI design. Starting with the introduction of the mainstream technology of VLSI, four main technical foundations of VLSI design are introduced: device and process foundation, integrated circuit foundation, layout foundation and CAD foundation.

CMOS Digital Integrated Circuits

Credits 2

Class hour 32

Course number 2109509

CMOS Digital Integrated Circuits is an important professional elective course for the microelectronics science and engineering specialty students, provides detailed information on CMOS digital integrated circuits. It can be used by undergraduate and graduate students in various electrical fields related to integrated circuit design, as well as by engineers engaged in integrated circuit design, digital system design, and VLSI design.

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Analysis and Design of Analog CMOS Integrated Circuits

Credits 3

Class hour 48

Course number 2109502

Analysis and Design of Analog CMOS Integrated Circuits is an important professional core course for the micro-electronics specialty students. The course is aimed to Build a knowledge system from CMOS devices to unit circuits then to function circuit systems, The students are required to know lasted development, learn the basic design method and master the technology of Analog CMOS Integrated Circuits

Integrated circuit layout design

Credits 2

Class hour 32

Course number 2109510

《Integrated Circuit Layout Design》is an elective course of the microelectronics science and engineering major. Through the theoretical study and practice, the students can master the basic concepts as well as the processes of integrated circuit layout design. They can use the relevant tools to design the corresponding circuit configuration, and test the reliability of the circuit.

This course requires students to master the use of L Edit, post-layout simulation T Spice and post-layout simulation W Edit. Through practical training, students should possess the basic thinking and knowledge of integrated circuits layout design. They know well the editing methods of basic devices. Finally, the preliminary integrated circuit design ability, good learning and practice ability can be cultivated. The students have the ability to analyze and solve practical problems.