Some majors of Xi University of Posts and Telecommunications:No. Professional name belongs to category 1 electronic information engineering 2 administration 3 information and computing science 4 industrial engineering management 5 radio and television engineering 6 network engineering 7 applied physical science 8 data science and big data technology engineering 9 electromagnetic field and wireless technology engineering 1 industrial and commercial administration 12 planning management1 3 Public Enterprise Management/KOOC-0/4 Communication Engineering/KOOC-0/5 Information Countermeasure Technology Engineering/KOOC-0/6 Automation Engineering/KOOC-0/7 Financial Management Management/KOOC-0/8 Optoelectronic Information Science and Engineering Engineering/KOOC-0/9 Internet of Things Engineering 20 Introduction to Information Management and Information System Management Undergraduate, Xi 'an University of Posts and Telecommunications
Training objectives:
This major cultivates high-quality applied technical talents who meet the needs of information technology and industrial development, have high moral and cultural literacy, strong sense of social responsibility, physical and mental health, solid basic knowledge of natural science and necessary professional knowledge, good learning ability, practical ability and innovative consciousness, and can engage in research, product development, engineering design and technical management in microelectronic materials and devices, integrated circuit manufacturing technology and related electronic information science fields.
The specific goals that graduates of this major should achieve in the social and professional fields about five years after graduation include:
1) Extensive humanistic knowledge, sound personality, good cultivation and professional ethics, and strong sense of social responsibility;
2) Have certain teamwork, communication and organizational management skills, and be able to undertake the work of individuals, team members and leaders in multi-disciplinary teams;
3) Have professional engineering practice ability and system integration ability, be able to use relevant laws and technical standards, and rationally use the professional knowledge learned to analyze and solve complex engineering problems in the field of microelectronics;
4) Be able to independently undertake the design and application development of products and systems in microelectronic related fields such as microelectronic materials and devices and integrated circuit manufacturing technology. , and become the technical business backbone of the department;
5) In the rapidly changing global economic and technological environment, we can actively update our professional knowledge and improve our engineering practice ability through continuous study or engineering training to meet the needs of international communication.
Graduation requirements:
According to the training characteristics and professional training objectives of microelectronics science and engineering, through classroom teaching, lectures, social activities, cultural activities, various competitions, innovative experiments, internships, counseling, seminars and other teaching links of humanities and social sciences courses, engineering basic courses, professional basic courses and professional courses, the ability of graduates majoring in microelectronics science and engineering can meet the following 12 graduation basic requirements:
1. engineering knowledge: able to solve complex engineering problems in microelectronics field by using mathematical knowledge, engineering foundation and professional knowledge.
1. 1 can use the basic knowledge of mathematics, natural science and engineering to properly express complex engineering problems in the field of microelectronic materials and devices and integrated circuit manufacturing technology.
1.2 can establish a suitable mathematical model for the manufacturing process of microelectronic materials and devices and integrated circuits, and solve it with suitable boundary conditions.
1.3 can use engineering and professional knowledge to test and evaluate the performance, effectiveness and reliability of microelectronic materials and devices and integrated circuit manufacturing process. Understand the design, optimization process and implementation of microelectronic devices and related systems.
1.4 can apply the knowledge of engineering foundation, solid-state electronics and quantum mechanics to the manufacturing design, control and optimization of microelectronic materials, devices and integrated circuits.
2. Problem analysis: The basic principles of mathematics, natural science and engineering science can be applied to identify, express and analyze complex engineering problems in the field of microelectronics through literature research, so as to draw effective conclusions.
2. 1 can identify and judge the key links and parameters in complex engineering problems in microelectronics field, and have the ability to effectively decompose them with professional knowledge.
2.2 Through literature query and analysis, I have the ability to express, model and correctly describe the systematic solutions to the decomposed complex engineering problems.
2.3 Be able to use the basic principles of engineering and specialty to analyze the possible factors affecting the effectiveness, reliability, cost and efficiency of microelectronic materials and devices and integrated circuit manufacturing processes, and draw effective conclusions.
3. Design/develop solutions: be able to design solutions to complex engineering problems in the field of microelectronic materials and devices and integrated circuit manufacturing technology, design microelectronic devices and processes that meet specific needs, and reflect the sense of innovation in the design process, taking into account social, health, safety, legal, cultural and environmental factors.
3. 1 can analyze the problems involved in the field of microelectronic materials and devices and integrated circuit manufacturing technology, and clarify the relevant constraints and requirements.
3.2 The software and hardware modules of the system can be independently designed and implemented according to specific requirements.
3.3 Understand the impact of the application of microelectronics technology on society, security and law. , and can weigh the related factors involved in complex engineering problems in microelectronics field from the system point of view, put forward reasonable solutions, complete the system design and implementation, and analyze its effectiveness through test or experimental data.
Research: Based on the principles of natural science, using scientific methods to study complex engineering problems in the field of microelectronics technology, including designing experiments, analyzing and interpreting data, and drawing reasonable and effective conclusions through information synthesis.
4. 1 can use the correct method to study and verify the information processing system related to microelectronics technology.
4.2 Be able to use the basic theory in the field of microelectronics, choose the research route and design the feasible experimental scheme according to the characteristics of the research object.
4.3 Be able to build an experimental system according to the experimental scheme, analyze and explain the experimental results, and draw reasonable and effective conclusions through information synthesis.
5. Use modern tools: be able to develop, select and use appropriate technologies, resources, modern engineering tools and information technology tools, including the prediction and simulation of complex engineering problems, and understand their limitations.
5. 1 can skillfully use electronic instruments to observe and analyze the manufacturing process performance of microelectronic materials and devices and integrated circuits, and can use charts, formulas and other means to express and solve the design problems of microelectronic related projects.
5.2 Can correctly use computer software and hardware technology and microelectronics professional simulation tools to complete the simulation and simulation analysis of microelectronics engineering projects, and can understand its limitations.
5.3 Skillfully use literature retrieval tools to obtain the latest development of theory and technology in the field of microelectronics.
6. Engineering and society: be able to use the relevant engineering background knowledge of this major, make a reasonable analysis, evaluate the impact of engineering practice activities and solutions to complex engineering problems of this major on society, health, safety, law and culture, and understand the responsibilities to be undertaken.
6. 1 Have production practice and social practice experience in microelectronics enterprises, and know the necessary engineering background knowledge.
6.2 Familiar with microelectronics related technical standards, intellectual property rights, industrial policies, laws and regulations, and understand enterprise project management system.
6.3 Be able to identify and objectively evaluate the social, health, safety, legal and cultural impacts of the use of microelectronic systems and the implementation of engineering projects.
7. Environment and sustainable development: be able to understand and evaluate the impact of engineering practice of complex engineering problems in microelectronics field on environmental and social sustainable development.
7. 1 Understand the connotation and significance of environmental protection and social sustainable development;
7.2 According to the actual microelectronic system engineering project, using humanistic knowledge and industry standards and regulations, evaluate the impact of the scheme on the sustainable development of the environment and society.
8. Professional norms: with humanities and social sciences literacy and engineering professional ethics and norms.
8. 1 Possess humanities and social sciences such as philosophy, history, legal culture, etc. , and understand the social responsibility that should be assumed;
8.2 Have engineering professional ethics and norms, and consciously abide by them in engineering practice.
9. Individuals and teams: Be able to play the roles of individuals, team members and leaders in a team with multidisciplinary background.
9. 1 Can actively cooperate with members of other disciplines and independently complete the work assigned by the team.
9.2 Be able to understand the meaning of each role in a multi-role team, listen to the opinions of other members, organize team work and cooperate to complete team tasks.
10. Communication: Good communication skills, effective communication on professional issues, and a certain international perspective, including cross-cultural communication skills.
10. 1 can clearly express professional problems in written and oral form, and can effectively communicate with peers;
10.2 has the basic ability of listening, speaking, reading and writing in English, and can carry out cross-cultural communication;
10.3 Understand the international development trends and research hotspots in the field of microelectronics.
1 1. project management: understand and master the principles of project management and economic decision-making methods, and can be applied in a multidisciplinary environment.
1 1. 1 Understand the importance of microelectronics project management and economic decision-making, and identify the key factors in microelectronics project management and economic decision-making.
1 1.2 can apply management principles and technical and economic methods to the development, design, construction and maintenance of information microelectronics related products.
12. Lifelong learning: Have the awareness of autonomous learning and lifelong learning, and have the ability to keep learning and adapt to social development.
12. 1 can recognize the necessity of continuous exploration and learning, and have the consciousness of autonomous learning and lifelong learning; Have the knowledge base of lifelong learning, master the methods of autonomous learning, and understand the ways to expand knowledge and ability;
12.2 can adopt appropriate methods to meet the needs of personal or professional development, learn independently and adapt to social development.
Introduction to electromagnetic field and wireless technology in Xi 'an University of Posts and Telecommunications
Training objectives: This major aims to train senior engineering and technical personnel who have a solid foundation in electromagnetic field theory and circuit design, have the ability to use computer and electronic technology, have received strict scientific experimental training and scientific research training, can engage in scientific research, product development, teaching and management in electromagnetic field and wireless technology, and can meet the needs of the development of contemporary information field.
Training requirements: have a solid mathematical foundation; Strong English reading, writing and listening skills; Have extensive system expertise; Master the basic theory and engineering methods of RF microwave generation, processing, emission, radiation and reception; Have a deep understanding of engineering application and system development in wireless field; Strong practical skills in computer and wireless communication technology; Strong scientific research and independent working ability; Understand the theoretical frontier, application prospect and latest development trends in the field of electromagnetic field and wireless technology; Have good ideological and moral cultivation, professional accomplishment and physical and mental quality.
Main subjects and courses: electronic science and technology. Circuit analysis, signal and system, analog electronic technology, digital circuit and logic design, electromagnetic field and electromagnetic wave, microwave technology, communication principle, high-frequency electronic circuit, advanced language programming, microcomputer principle and interface technology, microwave electronic circuit, antenna and radio wave, numerical calculation method and Matlab application, microwave circuit CAD and production, antenna CAD and production, etc.
Undergraduate course, with a four-year academic system, awarded the Bachelor of Engineering degree.
Research direction: electromagnetic field and microwave technology, electronic science and technology, modern wireless communication technology, internet of things and radio frequency identification.
Employment after graduation: mainly employed in wireless communication, electromagnetic field and microwave technology manufacturing, information and communication operation, and also engaged in teaching and scientific research in universities or research institutes.
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