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Microelectronics

CULTIVATION OBJECTIVES

After the study in the Microelectronics Program, the students are expected to demonstrate a comprehensive understanding of their ethical, professional and physical responsibilities. With the extensive academic training in this program, students should master the design and fabrication

techniques of large-scale integrated circuits and semiconductor devices，master the basic theoretical

principles, the experimental skills and the professional knowledge of all aspects of microelectronics necessary for identifying, formulating, and solving engineering problems. The graduates should be

creative and cooperative，so as to be fully prepared for successful careers in scientific research, teaching,

scientific technology development, engineering techniques, engineering management, production management or other professions in industries such as integrated circuit, information technology and communication and computers, and finally to be a highly qualified talents with international competitiveness.

MAIN AND RELATED DISCIPLINES

MAIN DISCIPLINE

Microelectronics

RELATED DISCIPLINES

Electronic Science and Technology, Information and Communication Engineering, Control Science and Engineering, Computer Science and Technology, Electric Engineering

MAIN COURSES

Circuits, Analog Electronics, Digital Logic Circuits, Signals and Systems, Electromagnetic Field Theory, Quantum Mechanics and Statistical Physics, Semiconductor Physics, Semiconductor Devices, Digital Integrated Circuits, Analog Integrated Circuits, Fabrication Techniques of Microelectronics

CHIEF ASPECTS OF PRACTICAL TEACHING

Curriculum Design, Graduation Design Project, Metalworking Practice, Electrical Engineering Practice, Professional Practice, Analog Integrated Circuits Experiments, Digital Integrated Circuits Experiments, Integrated Circuits Fabrication Experiments

EDUCATION SYSTEM AND ACADEMIC DGREE

Four years with the Bachelor Degree of Engineering

graduation requirements

The minimum credit requirement is 170 (within-class) plus 8 (extracurricular). Additionally, the students should pass the exams of military training, CET -4 and the test of National Standard for College Students’ Physique Health before graduation.

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Description and requirements for sellcting courses

1、 More Detailed Specifications of Curriculum Requirements for Each Category in the Table of Course Setting

（1） In the part of Comprehensive English，students are taught separately according to their test

scores of Entrance English Level Examination. During the first year, the college English （Ⅱ）, （Ⅲ）,

（IV）are taught accordingly with total 6 credits；during the second year, 4 credits are obtained from the

Advanced English courses, students who do not pass CET-4 are required to select Advanced English, with total 10 credits.

（2） 12 credits are taken from the General Courses of the Basic Curriculum, of which 6 credits are from electives in the categories of Cultural Heritage, Society and Art, Life and Environment, which account for 2 credits respectively, the other 6 credits are from either the general courses or the core courses of the Basic Curriculum.

（3） 4 credits are from Engineering Mathematics, students of microelectronics are suggested to select the course of Mathematical and Physical Equations” and Mathematical Modeling II.

（4） 3 credits may be from Chemistry and Biology, the course of College Chemistry II is suggested.

（5） In the specialized course category, the minimum requirement are 23.5 credits for electives, 17.5 credits for specialized courses; and 6 credits for the practical section; A suggesting list for Course Selection can refer to Curriculum Requirements in section 4.

（6） The courses which include the General Courses of the Basic Curriculum, the Specialized Curriculum of the Chief Disciplines, and Specialized Curriculum and the practical section which includes in-class Experiments, Experiments, Specialized Experiments, and the Curriculum Project etc. occupy no less than 20% of the total in-class credits which is 105 credits in total. Besides, the practical training is no less than 374 hours ( consisting of required ones and elective ones ).

（7） The courses of Semiconductor Physics, Digital Logic, Analog Integrated Circuits are bilingual courses offered in the fourth, the fifth, and the sixth semesters respectively.

（8） Except the seventh and the eighth semesters，the total credits for each student are usually

between 20 and 25 ( no more than 25) in each semester.

2、 Detailed Specifications and Requirements of Comprehensive Practical Curriculum

(1) Freshmen have to take part in Computer Operation Ability Test, those who fail to pass it are required to select the course of Basic Computer Application Experiment, which is computer operation skill training and is non-credit.

(2) Curriculum Project and Specialized Experiment are scheduled in the sixth and the seventh

semesters in conjunction with related courses，and students are expected to apply the learned theories into

practice and training. Proficiency is examined when the training is completed.

(3) Engineering Practices mainly includes Metalworking Practice which is scheduled in the second semester, and Electric Engineering Practice which is scheduled in the second semester. Through

participating in the activities of workshop，students need to learn the basic knowledge and operating

procedures of electronic and mechanical equipments, and acquire the perceptual knowledge of electrotechnics and machinery. Proficiency is examined by the corresponding factory when the training is completed.

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(4) Professional Practice I is scheduled in the summer of either the first or the second school year in

a distributed way. That is，the students contact with their major-related industry, and conduct research in it,

acquire knowledge of the production information. After the training is completed，students should submit

their fieldwork diary and industry training report. Proficiency is examined by the corresponding department.

(5) Professional Practice II: According to the practical training outline，students should conduct

practical training in the related industries after the third school year is finished，get to know information of

the production in microelectronics-related industry. The practical training is proceeded in a comprehensive

way. After the training is completed，the students should submit their fieldwork report. The conductor is

responsible for their proficiency examination.

(6) Project Design is scheduled in the sixth and the seventh semesters. With reference to theoretical principles, students should design, implement and accomplish a project by themselves in the extracurricular time. The in-class time is only for discussion and reporting. The teachers are in charge of project progress, and form groups to assess the proficiency of the students in the related areas. The test scores of the students are decided based on the project summary, project report, project defense, and peer evaluation among themselves.

(7) Scientific Research Training is scheduled between the fifth semester and the eighth semester. Outstanding students may join the research teams of the faculty members and their work is examined by supervisor. Students who pass the examination may get 1 credit.

(8) Graduation Design starts from the eighth semester, students enter the design of the graduation

project，including the determination of the project topic and the tasks intended to accomplish, and the

thesis outline under their teacher’s guidance . The thesis work should be finished before the middle of June of the eighth semester, and the thesis defense should be arranged by the school and the department before the end of June.

3、 Prerequisite Requirements of Course Selection

Prerequisite relations of courses are described in the following chart，the courses at the root of the

arrow are the prerequisites of the courses pointed by the arrow.

Semiconductor Physics

Semiconductor Device

Fabrication Techniques of

Microelectronics Digital Integrated CircuitsAnalog Integrated Circuits

Modeling of Semiconductor DevicesPower Semiconductor Devices

Introduction to Nano-electronics MicroElectroMechanical Systems

optronics

IC Packaging Technology

Signals and Systems

Principles of CommunicationDigital Signal Processing

Principles of Automatic Control

Electromagnatic Field Theory

Principles of Computer Organization

Verilog Hardware Description Language

Methodology of VLSI VerificationFPGA Baseed Embedded Systems Design

High-Frequency Electronic CircuitsSpecialized Laboratory

on IC CAD

Specialized Laboratory on Digital ICs

Specialized Laboratory on IC Fabrication

Specialized Laboratory on Analog ICs

Microcomputer Principles and Interface

Technologies

Digital Logic

Circuits

Analog Electronics

Quantum Mechanics and Statistical Physics

Fundamentals of IC Design

VLSI Testing and Testability Design

Class Project of Semiconductor Devices

Specialized Laboratory on Semiconductor

Physics and Devices

4、 Course Suggesting Lists for Different Areas of Concentration

（1） All the following courses are suggested for students with an emphasis on devices and

fabrication techniques：Modeling of Semiconductor Devices, Fundamentals of Integrated Circuit Design,

Power Semiconductor Devices, Introduction to Nano-electronics, Micro Electro Mechanical Systems, Electromagnetic Field Theory, Specialized Laboratory on Semiconductor Physics and Devices, Class Project of Semiconductor Devices, Specialized Laboratory on IC Fabrication, etc.

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（2） All the following courses are suggested for students with an emphasis on integrated circuit designs: Fundamentals of Integrated Circuit Design, Verilog Hardware Description Language, VLSI Testing and Testability Design, IC Packaging Technologies, FPGA-Based Embedded Systems Design, Digital Signal Processing, Principle of Automatic Control, Specialized Laboratory on IC CAD, Specialized Laboratory on Digital ICs, Specialized Laboratory on Analog ICs, et al.

（3） All the following courses are suggested for students with an emphasis on digital system designs: Verilog Hardware Description Language, VLSI Testing and Testability Design, FPGA-Based Embedded Systems Design, VLSI Verification Methodologies, Principles of Computer Organization, Principles of Communications, Specialized Laboratory on IC CAD, Specialized Laboratory on Digital Integrated Circuits, et al.

（4） Other courses may be freely selected according to personal interests.

（5） A minimum of 23.5 credits is required for specialized courses ( including the practical

training section )，and the credits gained on the practical training section should satisfy the school’s credit

proportionality requirement.

5、 The student department will set an extracurricular requirement of 8 credits and provide policy details by itself.

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Curriculum Structure

Credit:21 12.3%

Extracurricular Practice

Compulsory 40 credits

Credit:43 25.3%

Compulsory 42.5 credits

Compulsory 23.5 credits Credit: 106

62.4%

Basic Curriculum of Each Specialty

Specialized Curriculum

Compulsory 16 credits Optional XX credits

Ideological and Political Education National Defense Education

Physical Education, English, Fundamentals of Computers

General Course of Basic Curriculum

General Curriculum

Basic Curriculum of Each Discipline

Comprehensive Practical

Curriculum

Graduation Design Curriculum Design

≥ Optional 8 credits

Compulsory 12 credits

Compulsory 9 credits

Optional 12 credits

Engineering Practice Scientific Research Training

Specialized Curriculum of

Chief Disciplines

Microelectronics

Compulsory 15 credits Optional XX credits

Credits: 170+8

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Course Setting

Course Type Coding Course Credits HoursCompulsory/

Optional Term

Politics and

Military Education

MLMD0006 Introduction to Mao Zedong Thought and the Theoretical System of Socialism with Chinese

Characteristics

5 80

Compulsory 16

credits

2，3

MLMD1004 Thoughts and Morals Cultivation and Law Basics 3 48 1

MILI1003 National Defense Education 2 32 1

MLMD2001 Basic Principles of Marxism 3 48 4

MLMD0002 Conspectus of Chinese Modern History 2 32 2

GNED0004 Situations and Policies 1 32 1-7

Physical

Education, English,

Computer Education

COMP1011 Fundamentals of Programming Design 3 56 Compulsory 5

credits

1

PHED1001 Physical Education 2 128 1- 4

ENGL1015 Comprehensive

English

College English (II) 6 96 Compulsory 6

credits

1,2

ENGL1017 College English ( )Ⅲ 6 96 1,2

ENGL1018 College English（Ⅳ） 6 96 1,2

ENGL2013

Advanced English

Advanced English 2 32

Optional

4 credits，

those who fail CET-4 must take

advanced English.

3,4

ENGL0003 College Spoken English 2 32 3,4

ENGL0004 English Writing 2 32 3,4

ENGL2010 Advanced Viewing, Listening and

Speaking 2 32 3,4

ENGL0005 E-C and C-E Translation: Skills and

Practice 2 32 3,4

ENGL2012 Sources of European Culture 2 32 3,4

ENGL2014 Western Etiquette Culture 2 32 3,4

ENGL2015 British and American Culture 2 32 3,4

General Course of Basic Curriculum (including core courses)

Optional 12 credits

General curriculum subtotal Compulsory credits are 27, optional credits are 16.

Basic 

Curriculum of 

each Discipline 

MATH1038 Linear Algebra and Space Analytic Geometry II 3.5 56

Compulsory 33

credits

1

MATH1032 Advanced Mathematics I 13 220 1, 2

PHYS1022 College Physics II 8 128 2, 3

PHYS1019 College Physics Experiment A 2 64 2, 3

MATH2156 Probability and Mathematical Statistics 3 50 3

MATH2031 Complex Function and Integral Transformation 3 48 3

MATH2029 Mathematical and Physical Equations 2 32

Optional 4 credits

4

MATH2152 Mathematical Modeling II 2 40 4

MATH2034 Computational Mathematics 2 32 4

MATH2150 Vector and Tensor Analysis 2 32 4

CHEM1109 College Chemistry II 3 52 Optional 3 credits

2

BIOL1003 Introduction to Modern Biology 3 48 2

BICH1001 Biochemistry 3 48 1

Basic Curriculum of each Discipline subtotal Compulsory credits are 33, optional credits are 7.

Specialized

Curriculum of Chief

Disciplines

ELEC2007 Circuits 4.5 80

Compulsory 42.5

credits

3

EELC2012 Analog Electronics 3.5 56 4

EELC0003 Electronics Experiment 1.5 48 4、5

EELC2016 Digital Logic Circuits（Bilingual） 3.5 56 5

INFT3014 Signals and Systems A 4 68 4

MACH1103 Engineering Drawing 2 32 1

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Course Type Coding Course Credits HoursCompulsory/

Optional Term

EELC2019 Quantum Mechanics and Statistical Physics 3.5 56 3

PHYS3037 Semiconductor Physics（Bilingual） 4 64 4

EELC3042 Semiconductor Devices 3 48 5

EELC3168 Digital Integrated Circuits 3.5 56 6

EELC3169 Analog Integrated Circuits（Bilingual） 3.5 56 6

EELC3046 Fabrication Techniques of Microelectronics 2.5 40 5

EELC2021 Electromagnetic Field Theory B 3.5 56 5

Specialized Curriculum of Chief Disciplines subtotal Compulsory credits are 42.5

Specialized

Curriculum

EELC3158 Modeling of Semiconductor Devices 3 48

Optional

17.5 credits

6

EELC3159 Fundamentals of Integrated Circuit Design 2 32 5

EELC3160 Verilog Hardware Description Language 3 48 6

EELC3079 VLSI Testing and Testability Design 3 48 7

EELC4028 Power Semiconductor Devices 3 48 6

EELC4095 Introduction to Nano-electronics 3 48 7

EELC4052 IC Packaging Technologies 2 32 7

EELC4096 FPGA-Based Embedded Systems Design 2 48 7

EELC4098 VLSI Verification Methodologies 2.5 48 7

COMP3227 Principles of Computer Organization 3 48 6

INFT3034 Principles of Communication B 3 48 6

INFT3042 Digital Signal Processing 2.5 44 6

AUTO3017 Principle of Automatic Control B 3 52 5

EELC3114 Optronics 3.5 56 5

EELC3041 High Frequency Electronic Circuits 3 48 5

COMP3480 Microcomputer Principles and Interface Technologies 3 52 6

EELC3161 Specialized Experiment on Semiconductor Physics

and Devices 1.5 48

Optional

practical training 6 credits

5、6

EELC3162 Specialized Experiment on IC CAD 1.5 48 6

EELC3130 Class Project of Semiconductor Devices 2 64 5

EELC4099 Specialized Experiment on Digital ICs 1.5 48 7

EELC4100 Specialized Experiment on Analog ICs 1.5 48 7

EELC3163 Specialized Experiment on IC Fabrications 1.5 48 6

EELC4101 Specialized Experiment on Electronic Systems 1.5 48 7

ITDE3001 Project Design（Compulsory） 2 64 6，7

SCTR4001 Scientific Research Training 1 32 5、6,7

COMP1026 Specialized Experiment on Fundamental

Applications of Computers 0 16 1

Specialized Curriculum subtotal optional credits are 23.5

Comprehensi-ve Practical

Curriculum

PRAC3012 Professional Practice II 3 0

Compulsory 21 credits

6

MPRA2001 Metalworking Practice 2 0 2

EPRA2001 Electrical Engineering Practice 1 0 2

MCRA2001 Practical Training on Control Measurement 1 0 3

PRAC3012 Professional Practice I 2 0 2、4

BSIS4015 Graduation Design Project 12 0 8

GNED0004 Security Education 0 6 1

Comprehensive Practical Curriculum subtotal Compulsory credits are 21

Total Credits 170

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Teaching Plan

First semester Second semester

Coding Course Credits Coding Course Credits

MLMD1004 Thoughts and Morals Cultivation and Law

Basics 3 MLMD0006

Introduction to Mao Zedong Thought and the Theoretical System of Socialism with

Chinese Characteristics 3

MILI1003 National Defense Education 2 MLMD0002 Conspectus of Chinese Modern History 2

PHED1001 Physical Education 0.5 PHED1001 Physical Education 0.5

ENGL1015 ENGL1017 ENGL1018

College English（Ⅱ） College English（Ⅲ） College English（Ⅳ）

3 ENGL1015 ENGL1017 ENGL1018

College English（Ⅱ） College English（Ⅲ） College English（Ⅳ）

3

MATH1038 Linear Algebra and Space Analytic

Geometry II 3.5 MATH1032 Advanced Mathematics I 6.5

MATH1032 Advanced Mathematics I 6.5 PHYS1022 College Physics II 4

MACH1103 Engineering Drawing 2 PHYS1019 College Physics Experiment A 1

COMP1011 Fundamentals of Programming Design 3 MPRA2001 Metalworking Practice 2

Safety Education EPRA2001 Electrical Engineering Practice 1

Total Compulsory 23.5 credits, Optional 3～4 credits Total Compulsory 23 credits, Optional 3～4 credits

* the course of Situations and Policies is scheduled from the first to seventh semesters, total 1credit

* 2 credits may be from the General Courses of Basic Curriculum * students who fail Fundamental Applications of Computers should select Specialized Experiment on Fundamental Applications of Computers

* 3 elective credits may be from Chemistry and Biology。 * students should accomplish Production Practical Training II in the summer of either the current semester or the fourth semester。

Third semester Fourth semester

Coding Course Credits Coding Course Credits

PHYS1022 College Physics II 4 MLMD2001 Principles of Marx 's Revolutionary Social

Theory 3

PHYS1019 College Physics Experiment A 1 EELC2012 Analog Electronics 3.5

MATH2156 Probability and Mathematical Statistics 3 EELC0003 Electronics Experiment 0.75

MATH2031 Complex Function and Integral

Transformation 3 PHYS3037 Semiconductor Physics 4

MCRA2001 Practical Training on Measurement and

Control 1 INFT3014 Signals and Systems A 4

ELEC2007 Circuits 4.5 PHED1001 Physical Education 0.5

EELC2019 Quantum Mechanics and Statistical Physics 3.5

MLMD0006 Introduction to Mao Zedong Thought and the Theoretical System of Socialism with

Chinese Characteristics 2

PHED1001 Physical Education 0.5

Total Compulsory 22.5 credits, Optional at least 2 credits Total Compulsory 15.75 credits, Optional 6～9 credits

Suggested Elective Courses

MATH2152 Mathematical Modeling II 2

MATH2029 Mathematical and Physical Equations 2

* according to different levels, students in English Class A may take College English (I)，students in English Class B may take College English Advanced English。

* 4 credits may be from Engineering Mathematics * according to different levels, students in English Class A may take College English (I)，students in English Class B may take Advanced English。 * 2 credits may be from the General Course of Basic Curriculum

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Teaching Plan

Fifth semester Sixth semester

Coding Course Credits Coding Course Credits

EELC2016 Digital Logic Circuits 3.5 PRAC3012 Professional Practice II 3

EELC0003 Electronics Experiment 0.75 EELC3169 Analog Integrated Circuits 3.5

EELC3042 Semiconductor Devices 3 EELC3168 Digital Integrated Circuits 3.5

EELC3046 Fabrication Techniques of Microelectronics 2.5 ITDE3001 Project Design 1

EELC2021 Electromagnetic Field Theory B 3.5

Total Compulsory 13.25 credits, Optional 9～12 credits Total Compulsory 11 credits, Optional 12～14 credits

6～9 credits are from the following Electives Courses 11～13 credits are from the following Elective Courses

EELC3159 Fundamentals of Integrated Circuit Design 2 EELC3160 Verilog Hardware Description Language 3

AUTO3017 Principle of Automatic Control B 3 COMP3227 Principles of Computer Organization B 3

EELC3130 Curriculum Project of Semiconductor Devices 2 EELC3162 Specialized Experiment on IC CAD 1.5

EELC3114 Optronics 3.5 EELC3158 Modeling of Semiconductor Devices 3

EELC3041 High Frequency Electronic Circuits 3 EELC3161 Specialized Experiment on

Semiconductor Devices 0.75

EELC3161 Specialized Experiment on Semiconductor

Physics and Devices 0.75 EELC3163

Specialized Experiment on IC Fabrication Techniques

1.5

EELC4028 Power Semiconductor Devices 3

INFT3042 Digital Signal Processing 2.5

COMP3480Microcomputer Principles and Interface

Technologies 3

INFT3034 Principles of Communication 3

* 2 credits may be from the General Course of Curriculum。 * 1 credit is from Scientific Research Training and scheduled in the fifth、sixth、seventh semesters。

* 2 credits may be from the General Course of Curriculum。

Seventh semester Eighth semester

Coding Course Credits Coding Course Credits

ITDE3001 Project Design 1 BSIS4015 Graduation Project 12

Total Compulsory 1 credits, Optional 12～16 credits Total Compulsory 12 credits

8～12 credits are from the following Electives

EELC3079 VLSI Testing and Testability Design 3 At the end of the current semester，the total credit hours may be at least 170 credits, in which the General Course of Curriculum subtotal is 43 credits (Compulsory 31 credits, Optional more than 12 credits); the Basic Curriculum subtotal is 40 credits (Compulsory 33 credits, Optional more than 7 credits) ； the Specialized Curriculum of Chief Disciplines subtotal is 42 credits；Specialized Curriculum subtotal is no less than 24 credits；the Comprehensive Practical Curriculum subtotal is no less than 21 credits。Practical Training subtotal is no less than 374 hours (including in-class Laboratory、Specialized Experiment Classes、Class Project, et al.). Additionally, the students need meet an extracurricular requirement of 8 credits, and pass Military Training Examination, CET -4, and National Standard for College Students’ Physique Health before graduation.

EELC4095 Introduction to Nano-electronics 3

EELC4052 IC Packaging Technologies 2

EELC4096 FPGA-Based Embedded Systems Design 2

EELC4099 Specialized Experiment on Digital ICs 1.5

EELC4100 Specialized Experiment on Analog ICs 1.5

EELC4098 VLSI Verification Methodologies 2.5

EELC4101 Specialized Experiment on Electronic Systems 1.5

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*4 credits may be from the General Course of Basic Curriculum。