Basic educational system: four years | Enrollment target: | Education: technical secondary school | Professional code: 080704

Training objectives

Training objectives

Training objectives: This major aims to cultivate all-round development of morality, intelligence and physique, and has a solid natural science foundation, systematic professional knowledge, strong experimental skills and engineering practice ability for microelectronics science and engineering, and can engage in research, development, manufacturing and management in the field of microelectronics science and technology.

Training requirements: Students in this major are required to master the basic theories of physics, electronic technology, computer technology and microelectronics, master the principles, design, manufacture, packaging and application technologies of microelectronic devices and integrated circuits, receive good experimental technical training, master the basic methods of literature retrieval, have strong experimental skills and engineering practice ability, and have the research and development ability in the field of microelectronics science and engineering.

Graduates should have the following knowledge and abilities:

1. Good humanities and social sciences literacy, innovative spirit and broad scientific vision;

2. Establish the concept of lifelong learning, and have strong ability to continue learning in future life and work;

3. Have a solid theoretical foundation of natural science;

4. Have the theoretical foundation and experimental skills of microelectronic materials, microelectronic devices, large-scale integrated circuits, integrated systems, computer-aided design, packaging technology and testing technology;

5. Understand the development trends of science and technology and industry in this field, and be familiar with the national electronic information industry policy and domestic and foreign intellectual property laws and regulations;

6. Master the basic methods of literature retrieval and obtaining relevant information by using modern information technology;

7. Have the ability to summarize, sort out and analyze experimental results, write papers, reports and participate in academic exchanges.

Main subjects: microelectronics, electronic science and technology.

Core knowledge fields: circuit theory, electronic technology foundation, signal and system, electromagnetic field and electromagnetic wave, semiconductor physics, microelectronic device principle, integrated circuit design principle, microelectronic technology principle, integrated circuit packaging and system testing, embedded system principle and design, electronic design automation foundation, etc.

Example of core courses:

Example 1: circuit analysis principle (64 hours), microelectronics and circuit foundation (48 hours), signal and system (48 hours), semiconductor physics (64 hours), electronic circuit A(48 hours), digital logic circuit (48 hours), digital integrated circuit design (48 hours) and integrated circuit technology principle (48 hours).

Example 2: circuit analysis theory (48 hours), electromagnetic field theory (48 hours), analog electronic circuit (64 hours), signal and system (64 hours), digital electronic circuit (64 hours), solid state physics (64 hours), semiconductor physics (64 hours), integrated circuit principle and design (64 hours) and semiconductor device physics (64 hours).

Example 3: Core compulsory courses, including circuit analysis (54 class hours), analog electronic technology (48 class hours), digital electronic technology (48 class hours), solid state physics (48 class hours), semiconductor physics (64 class hours) and semiconductor process principle (48 class hours); The core elective courses in the professional direction include semiconductor integrated circuit principle and design (32 hours), integrated circuit CAD (32 hours), integrated circuit process design (32 hours), semiconductor optoelectronic materials (32 hours), semiconductor optoelectronic device principle (32 hours) and semiconductor optoelectronic device technology (32 hours).

Main practical teaching links: metalworking practice, electronic technology practice, course design, production practice, graduation design (thesis) and so on.

Main professional experiments: circuit experiment, electronic technology experiment, signal and system experiment, semiconductor basic experiment, microelectronics technology experiment.

Length of study: four years.

Degree awarded: Bachelor of Engineering or Bachelor of Science.

Professional ability requirements

Professional ability requirements

The main contents of professional teaching

The main contents of professional teaching

Fundamentals of circuit analysis, analog circuits, mathematical and physical methods, digital circuits, signals and systems, semiconductor physics, solid-state electronics, microelectronic devices, microelectronic integrated circuits, integrated circuit design and manufacturing, electronic design automation, integrated circuit CAD, computer principles and system design.

Major (skill) direction

Major (skill) direction

Electronic enterprises: electronic technology, product research and development, research and development of various electronic and photoelectric materials, design and manufacture of electronic and photoelectric devices, ic design and technology development.

Example of vocational qualification certificate

Example of vocational qualification certificate

Examples of continuing learning majors

Employment direction

Employment direction

Employment direction of microelectronics science and engineering specialty

Microelectronics science and engineering major is a graduate student who applies for microelectronics, solid-state electronics, communications, computer science and other disciplines, and is engaged in the development and research of information science and technology fields such as integrated circuit manufacturers, integrated circuit design centers, communications and computers.

Employment prospect of microelectronics science and engineering specialty

In recent years, the specialty of microelectronics science and engineering has gradually become hot and the competition is fierce. Microelectronics specialty has always been an enduring hot topic. Microelectronics science and engineering majors mainly study the design and manufacture of new electronic devices and large-scale integrated circuits, computer-aided integrated circuit analysis, the basic theory, new structure, manufacturing technology and testing technology of various electronic devices, and the development of new integrated devices. With the development of microelectronics technology in recent years, the computer capacity has doubled and the hardware cost has been greatly reduced, which has greatly promoted the development of industry and information industry. There are also contemporary hot research fields, such as the research and application of lasers and the research of sensors, which all belong to the category of microelectronics or are closely related to it. The development of microelectronics technology is the foundation of modern industry and information chemistry industry.

Corresponding occupation (post)

Corresponding occupation (post)

Other information:

Microelectronics science and engineering mainly includes circuit analysis foundation, analog circuit foundation, mathematical and physical methods, digital circuits, signals and systems, semiconductor physics, solid-state electronics, microelectronic devices, microelectronic integrated circuits, integrated circuit design and manufacturing, electronic design automation, integrated circuit CAD, and electronic design automation. Microelectronics science and engineering mainly studies the basic principles, design methods and basic skills of various microelectronic devices and integrated circuits, designs and manufactures semiconductor devices, functional electronic materials and integrated circuits, and designs and develops MEMS.