1. Master the basic theory of Marxism, establish the spirit of patriotism and collectivism, abide by the law, have a strong sense of professionalism and responsibility, have good moral quality and academic accomplishment, and be physically and mentally healthy.

2. Master the solid and extensive basic theory and systematic and in-depth professional knowledge of this discipline, have good scientific literacy and the ability to engage in scientific research independently, and make creative achievements in science or special technology.

3. Be proficient in using a foreign language.

Two. Introduction of disciplines, specialties and research directions

Optical engineering is a young discipline with a long history. Its theoretical basis-optics, as the main subject of physics, has gone through a long and tortuous development road, casting geometric optics, wave optics, quantum optics and nonlinear optics, revealing the law of light generation and propagation and its interaction with matter. With the rise of laser technology and optoelectronic technology, optical engineering has developed into a discipline based on optics, which closely intersects and interpenetrates with information science, energy science, material science, life science, space science, precision machinery and manufacturing, computer science, microelectronics technology and other disciplines. It includes laser technology, optical communication, optical storage and recording, optical information processing, photoelectric display, holography and three-dimensional imaging, thin film and integrated optics, photoelectron and photon technology, laser material processing and processing, low light level and infrared imaging technology, photoelectric measurement, fiber optics, modern optics and photoelectric instruments and devices, optical remote sensing technology, integrated optical engineering technology and many other important emerging branches. These branches not only make a qualitative leap in optical engineering, but also promote the establishment of rapidly developing modern optical industry and optoelectronic industry.

This major received a master's degree in optical engineering from 65438 to 0998 and a doctorate in 2005. Relying on the two key laboratories of the Ministry of Education, Luminescence and Optical Information Technology and All-Optical Network and Modern Communication Network, under the guidance of Academician Xu and Academician Jane, this subject has formed the following research directions:

1. Flat panel display technology and equipment

Flat panel display is realized by using flat panel display devices and logic circuits. Because of its low voltage, light weight, small volume and good display quality, it will be widely used in civil and military fields. This direction is mainly engaged in the frontier scientific problems of luminescence and information display. It includes not only luminescent display materials (organic materials, inorganic materials and their related composite materials), but also many display devices (field emission, plasma, light-emitting diodes, liquid crystals and electroluminescence, etc.). ).

2. All-optical signal processing and network application technology

This paper mainly studies the frontier topics in the fields of optical communication network, optical fiber sensing and biomedical photonics-the network technology of optical packet switching all-optical network and all-optical signal processing technology supporting optical packet switching, such as photoelastic packet ring optical fiber communication network, all-optical buffer technology, optical switch, optical logic, optical head recognition, distributed optical fiber sensing system, on-line detection of optical fiber performance, and the application of optical fiber technology in biomedical photonics.

3. Photoelectric detection technology

This paper mainly studies the photoelectric detection mechanism, methods, technologies and realization ways of various geometric physical quantities in advanced manufacturing technology, rail transit and other engineering fields, and adopts various information and signal processing methods and technologies to obtain various evaluation parameters, and finally realizes real-time detection and fault diagnosis of key parameters and defects of important parts and equipment to ensure their safe operation.

4. Biomolecular light detection technology

Using advanced optoelectronic technology, taking prions, HIV and other important viruses as models, we will carry out research on the interaction mechanism and immune protection mechanism between viruses and cells, carry out advanced technology research on the detection of biological macromolecules and the recognition of molecular interaction, and develop rapid detection technology. Carry out research on new virus vectors and eukaryotic expression vectors. Develop new vaccines and drugs.

5. Photoelectric materials and devices

Solar cell technology mainly studies advanced crystalline silicon solar cell technology, as well as single crystal silicon/amorphous silicon heterojunction (HIT) solar cell technology, amorphous silicon thin film solar cell technology, organic thin film solar cell technology, dye-sensitized solar cell technology and broadband absorption enhancement solar cell technology.

Study rare earth luminescence, semiconductor luminescence, white LED lighting, mercury-free fluorescent lamp, optical film basic design, optical storage, photoelectric detection and other materials and photoelectric devices, and study the new technologies, new processes and applications of these materials and devices.

Third, training methods and years of study

1. culture method

The cultivation method of doctoral students adopts the tutor responsibility system, or the tutor-oriented guidance group system can be implemented. Curriculum learning and scientific research can cross each other. The course study adopts the credit system, and the required credits must be completed before applying for defense.

2. Study time

The study period of full-time doctoral students is generally three to five years; Postgraduates who continue to study for master's and doctoral degrees usually spend four to six years. The study period of part-time doctoral students in school is generally not more than six years.

Fourth, courses and credits

To implement the credit system, the minimum credits should be 12 credits. Courses are divided into degree courses and non-degree courses. Degree courses are divided into public courses, basic courses, specialized basic courses and specialized courses, while non-degree courses are divided into compulsory links and elective courses. The minimum required credits for doctoral students in school are 12 credits, including 7 credits for degree courses and 5 credits for non-degree courses. The course study is based on the credit system. Doctoral students should choose the appropriate course study time according to the needs of scientific research and thesis, and complete the course credits before the doctoral thesis defense.