At present, the field of micro-nano electronics and embedded system has sixteen majors, as listed below:

  • Telecommunication and Applied Electronics Engineering
  • Integrated Circuit Design
  • Advanced LED Lighting Technology
  • Photoelectronic Technique & Physics and Electronic Engineering
  • Integrated Circuit Manufacture
  • Embedded System Design
  • Solar Photovoltaics Technologies
  • Micro Electro Mechanical System
  • Low Carbon Technology and Economy

1. Telecommunication and Applied Electronics Engineering

This research direction lays more emphasis on the research of mobile communication system, technology and network technology application of electronic equipment. Research contents are as follows: mobile communication technology, digital signal processing technology, data communication network technology, and electronic system design technology. This direction thinks highly of the research on hardware and software of communication and applied electronic technology as well as engineering practice

Via this training, the students will grasp the theory of digital communication, digital signal processing and mobile communication network, cover technology of telecom-system design, electronic system design and embedded system design, and will be capable of developing communication and electronic systems. After graduation, students will have the ability to be a professional personnel in the field of telecommunication and applied electronics engineering. In employment, students can apply for communication, applied electronics as well as network equipment research, development, project management, technical support and so on.

2. Photoelectronic Technique and Physical Electronics Engineering

This research direction lays more emphasis on the research of laser control technique, photoelectronic technique, optical communication system, optical networking technology as well as instrumentation technology. Research contents are as follows: laser technology, photoelectronic technique, atomic clock & frequency standard, magnetic resonance imaging, photobiol technology, micro-nano machining technology, micro-nano photoelectric devices, digital signal processing technology, data communication and optical networking technology and so on, and this direction thinks highly of the research on hardware and software of photoelectronic technique as well as engineering practice.

Through classroom teaching and cases practicing, graduation practice, cutting-edge technical lecture and some other learning styles, students could master some technologies like semi-conductor laser technology, femtosecond laser technique, atomic clock & frequency standard, magnetic resonance imaging, photobiol technology, micro - nano scientific research methods and processing techniques, principle of photoelectric devices and optoelectronic devices, light signal receiving technology and Fiber-optic communication. After graduation, students will have the ability to be a professional personnel in the field of photoelectronic technique, in employment, students can apply for the research of photoelectronic technique and instrument Equipment, development, project management, technical support and so on.

3. Embedded System Design

This research direction lays more emphasis on the research of embedded system‘s structure, design theory and method as well as embedded system application technology. Research contents are as follows: composition principle of embedded system, embedded system design technology, peripheral and driver design of embedded system, embedded system applied technology.

Through classroom teaching and cases practicing, students could lay a solid foundation and broad expertise of embedded system engineering, and have the ability of engineering practice on embedded system design, bottom software and middleware. After graduation, students have the ability to meet the needs of market, become urgently-needed interdisciplinary talents in embedded system design, realization and management.

4. Integrated Circuit Design

Through classroom teaching and cases practicing, students could master the fundamental theory of microelectronics. with the help of advanced engineering methods, technology and tools, students could have the ability to engage in the design of integrated circuit and System-on-a-Chip(SOC) , ability of technological innovation, as well as the ability of project organization and management. Our students could become the senior interdisciplinary talents of research and management, adapting to what the integrated circuit design needs.

5. Integrated Circuit Design

Through classroom teaching and cases practicing, students could master the fundamental theory of microelectronics. With the help of advanced engineering methods, technology and tools, students could have the ability to engage in the integrated circuit manufacturing, technological innovation, as well as project organization and management. Our students could become the senior interdisciplinary talents of research and management, adapting to what the integrated circuit design needs.

6. Micro-Electro-Mechanical System

Through classroom teaching and project practice, the students can master the basics of micro-electro-mechanical system (MEMS) and have the ability to carry out the design, process development, system integration and application of MEMS device, based on the principle, method and new technology. Besides, they can acquire the latest development dynamics at home and abroad. With a solid foundation, reasonable knowledge structure, independent analysis and problem-solving skills, and teamwork spirit, they will become senior complex talents in the fields of micro-electro-mechanical systems’ research, development and management, making them adapt to the development of the integrated circuit industry.

7. Advanced LED Lighting Technology and Application

Through classroom teaching and project practice, students can master advanced device design, process engineering and packaging technology of LED, and then develop advanced LED energy saving lighting system. By mastering all kinds of advanced high power LED related materials and design, as well as technical features and development trends of advanced LED lighting system settings, etc., and with the spirit of teamwork, they could become senior interdisciplinary talents, adapting to what the advanced LED lighting industry’ research and management needs.

8. Solar Photovoltaic Technology

Through classroom teaching and project practice, students can master the basics of solar cell materials, device structure design, advanced technology, component manufacturing, and solar photovoltaic power generation system. And then they can grasp the advanced engineering methods and simulation technology, as well as the technique feature and technology development of solar photovoltaic system settings and the methods to improve efficiency, etc., with the spirit of teamwork, our students can become the senior interdisciplinary talents of research and management, adapting to what the solar photovoltaic industry needs

9. Low Carbon Technology and Economy

Through classroom teaching and project practice, students can master the basic principles of low carbon technology, advanced engineering method and basics of advanced simulation methods, as well as the technical characteristics and development of low carbon technology, etc. We focus mainly on economic development and analysis on the basis of low carbon technology, as well as the relevant economic management and policy planning. With the spirit of teamwork, our students can become the senior interdisciplinary talents of technology, economy and management, adapting to what the low carbon industry needs.