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Hehe, I'm an optical engineering student.
The basic courses of optics that all students of optics must take are "Applied Optics" and "Physical Optics", both of which are collectively called "Engineering Optics", and the books on these formulations can be used as a reference for learning. If the landlord wants to continue his studies in optics-related courses, there are also "Fourier Optics" and "Laser Principles", which are all necessary professional courses for graduate school entrance examinations, and they are also the basic courses of optics.
I recommend Zhang Yimo's "Applied Optics" to the landlord here, which can be called a classic and is a must-read for learning optical design!! Liang Quanting's "Physical Optics" is also a high-quality textbook.
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How much do you know about optical engineering? I'm going to change careers after I get a master's degree. But if you really want to do optical engineering, you can do that.
First of all, you will need to learn basic geometric optics, such as applied optics tutorials, and at the same time, you will need to start learning about optical design. There are books on this. Learn an optical design software:
Zemax, Cooddev, etc. choose one. Then learn to learn the basics of glass, and that's it. If you want to develop in this aspect of optics, you should also read two books, Nonlinear Optics and Principles of Optics.
Of course, there are many branches such as holographic, quantum entangled states, and optical remote sensing.
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Applied Optics Optical Design (Milton Laikin).
For recruiters, it's still very simple, as long as you know photography, you know this, but if you are in this industry, you must have an understanding of basic optical principles. In addition, there should be some concept of the design of the lens, so I recommend you to read these two books.
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The employment prospects of optical engineering majors are good, because the optical engineering majors are relatively unpopular, and the optical engineering industry is in short supply, so the society has a greater demand for optical engineering professionals.
Graduates generally have two employment directions, one is the optical direction, the demand is small, the threshold is high, and the prospects are good, and they are generally engaged in optical design work in large companies, such as optical field lens design, optical device design (optical communication), lighting optical design, etc.
The second is the direction of electricity, the demand is large, the threshold is relatively low, and hardware engineers (circuit design) are needed from mobile phones to standby freighters; Of course, with the development of the Internet, there are also graduates who work as software engineers and even algorithm engineers.
Research Directions of Optical Engineering:
1. Photoelectric imaging devices and wide-beam electron optics: mainly engaged in the research of the principle and technology of various photoelectric imaging devices, the detection and simplification application technology, the wide-beam electro-optical system and design, etc.
2. Virtual reality and augmented reality technology: mainly engaged in the research of virtual reality and augmented reality algorithms, technologies, systems, and their applications in various fields.
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Optical engineering is a discipline that is mainly based on optics and closely intersects with disciplines such as information science, energy science, materials science, life science, space science, precision machinery and manufacturing, computer science and microelectronic technology. In 2014, the state proposed to vigorously develop optical engineering, which can be said to have great potential.
Laser technology is revolutionizing optical technology; Microelectronics technology enables the rapid development of optical instrument automation and intelligence; Fiber optic technology has produced a new generation of optical instruments; Optical information processing has entered the practical stage. Optical engineering is making a huge difference in the world.
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Optical engineering is a discipline that focuses on optics and closely intersects and interpenetrates with disciplines such as information science, energy science, materials science, life science, space science, precision mechanics and manufacturing, computer science and microelectronic technology. In 2014, the state proposed to vigorously develop the cause of optical engineering, which can be said to have great potential.
Laser technology is revolutionizing optical technology; Microelectronics technology enables the rapid development of optical instrument automation and intelligence; Fiber optic technology has produced a whole new generation of optical instruments; Optical information processing has entered the practical stage. Optical engineering is making a huge difference in the world.
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Optical engineering does not belong to science, but to engineering. Optical engineering refers to a type of engineering that applies optical theory to practical applications. Optical engineering has developed into an optical-based discipline that closely intersects and interpenetrates with information science, energy science, materials science, life science, space science, precision machinery and manufacturing, computer science and microelectronic technology.
It contains many important emerging disciplines, such as laser technology, optical storage and recording, optical information processing, optoelectronic display, optoelectronic substrate and photonic technology, low-light and infrared thermal imaging technology, fiber optics, modern optics and optoelectronic instruments and devices.
Supplementary Materials: 1. Training Objectives of Optical Engineering:
1) Have a good grasp of the basic theories of Marxism, establish patriotism and collectivism, abide by discipline and law, have a strong sense of professionalism and responsibility, have good moral character and academic accomplishment, and be physically and mentally healthy.
2) Master solid basic theories and systematic professional knowledge in this discipline, and have the ability to engage in scientific research or independently engage in specialized technical work.
2. Research direction of optical engineering:
1) Low-light infrared and ultraviolet imaging technology.
2) Virtual Reality and Augmented Reality.
3) Photoelectric radar detection, imaging and countermeasure technology.
4) Image Engineering & Color Science.
5) Modern optical design and process, lithography technology and precision instrument engineering. Bu Minjin.
6) Photoelectric information acquisition, display and processing technology.
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Optoelectronic information technology is a multidisciplinary comprehensive technology composed of optics, optoelectronics, microelectronics and other technologies, involving the radiation, transmission, detection of optical information, as well as the conversion, storage, processing and display of optoelectronic information.
Optoelectronic information technology is widely used in all walks of life in the national economy and national defense construction. With the rapid development of the optoelectronic information technology industry, the demand for practitioners and talents is increasing year by year, so the demand for basic knowledge of optoelectronic information technology is also increasing. Featured Courses:
Computer principle, single-chip microcomputer principle, software technology, automatic control principle and fine and dry reed mechanics, etc. Display technology, microcomputer optoelectronic system, visual inspection, military optics, refractive optical system, etc. are featured courses.
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This project is completely gender-neutral, unlike other engineering disciplines, such as computer engineering, where men are more suitable. The ratio of men and women in optical technology in the Chinese Academy of Sciences is basically the same, as long as you learn well, you will definitely have a future. Don't worry, don't worry about this, but also consider whether you are interested.
Question: Doesn't the difference in physics affect the study of optics?
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This question needs to be discussed in a categorical manner:
There are 90 alphas that are eligible to be rounded to the nearest whole number.
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Just one... Perpendicular incidence a-mirror.
Biomedical engineering, this should not have much requirement for eyesight, as long as you meet the application score, you should be able to enter.
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Could it be an issue with the disc?
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Hello, Fudan University Biomedical Engineering Postgraduate Examination Subjects include: Basic Theory of Biomedical Engineering, Experimental Technology of Biomedical Engineering, Biomaterials Science, Principles of Biosensors, Bioinformatics Land Stimulation, Biomedical Image Processing, Mathematical Models of Biomedical Engineering, Computer Software for Biomedical Engineering, Mechanical Design of Biomedical Engineering, Instrument Design of Biomedical Engineering, Systems Engineering of Biomedical Engineering, Materials and Tissue Engineering of Biomedical Engineering, Biosensing and Control of Biomedical Engineering, Biomedical Engineering Signal Processing, Biomedical Engineering Computer Networks, Biomedical Engineering Cell and Molecular Engineering, Biomedical Engineering Drug Design and Analysis, Biomedical Engineering Biosensor Technology, Biomedical Engineering Medical Informatics, Biomedical Engineering Computer-Aided Diagnosis and Biomedical Engineering, Biomedical Engineering Biomimetic Technology, Biomedical Engineering Drug Preparations, Biomedical Engineering Grip Process Cell Engineering, Biomedical Engineering Drug Research and Development, Biomedical Engineering Biomaterials Research and Development, Biomedical Engineering Drug Detection and Analysis, Biomedical Engineering Biomedical Informatics, Biomedical Engineering Computer-Aided Diagnosis and Analysis, Biomedical Engineering Drug Preparations, Biomedical Engineering Section Xiyuan Cell Engineering, Biomedical Engineering Drug Research and Development, Biomedical Engineering Biomaterials Research and Development, Biomedical Engineering Drug Testing and Analysis, Biomedical Engineering Biomedical Informatics, Biomedical Engineering Computer-Aided Diagnosis and Biomedical Engineering, Biomedical Engineering Biomimetic Technology, Biomedical Engineering Drug Preparations, biomedical engineering, cell engineering, biomedical engineering.
In recent years, the country's chemical industry has not been very prosperous, so the employment prospects are average. >>>More