Train Objective and Career Perspective:

This major implements the education policies of the Party and the state, meets the needs of society and the industry for technology and talents in the field of electronic information. Based in Henan and facing the whole country, it aims to cultivate builders and successors of the electronic information industry with comprehensive development of morality, intelligence, physical fitness, aesthetics, and labor. It cultivates good socialist core values, professional qualities, innovation ability, lifelong learning spirit, international perspective, and a sense of social responsibility, High quality applied engineering and technical talents with the ability to solve complex engineering problems in signal detection, transmission, and processing in electronic information engineering, capable of conducting research, design/development, system integration, technical management, and operation maintenance in the field of electronic information engineering.

Specialty Features:

The major is based on high-level disciplines and scientific research as the foundation of professional practice and innovation platforms, cultivating comprehensive electronic information talents with broad basic knowledge, solid professional knowledge, strong application ability, and wide employment range. It focuses on basic knowledge and skill training in information perception, transmission, and processing, closely following the forefront of the discipline and current social needs of popular courses, in intelligent information processing The field of modern electronic system design has formed research and teaching characteristics, cultivating senior information professionals with solid foundations and outstanding engineering practical abilities.

Main Courses Description

Introduction to Electronic Information 

Credit: 1

Credit hours: 16

Course number: 2104498 

“Introduction to Electronic Information is a compulsory course for electronic information engineering majors. This course is designed for first-year university students, mainly to provide them with a preliminary understanding of the major, understand the training objectives, graduation requirements, course system, and career direction after graduation; At the same time, guide students to establish a preliminary awareness of professional norms, the connotation and significance of environmental and social sustainable development, and relevant regulations on environmental protection. By understanding the current development status of China's electronic information industry and curriculum ideological and political education, we can establish a patriotic and professional mindset, aspire to become builders of the electronic information industry, guide students to form good learning methods, and initially establish a sense of self-directed learning and lifelong learning.

Fundamentals of Circuit Analysis A

Credit: 3.5

Credit hours: 56

Course number: 2104499

The task of this course is to discuss the basic concepts, laws, and analysis methods of linear, lumped parameter, and non time-varying circuits. This course has a rigorous theory and strong logic. Through learning this course, students will have the ability to analyze complex linear circuits using basic theorems and laws, and learn to calculate physical quantities such as voltage, current, and power in DC circuits, dynamic circuits, and sinusoidal steady-state circuits; Derive the relevant parameters of the circuit using concepts such as network functions, frequency response, resonance, etc. Capable of designing simple linear circuits according to indicator requirements, able to learn how to use circuit simulation software with the guidance of basic concepts and analysis methods, conduct quantitative analysis of circuits, and have preliminary ability to write technical documents.

Analog electronic circuit A

Institute: School of Electronic Information

Credits: 3.5

Credit hours: 56

Course number: 2104402

This course is a discipline that analyzes and studies circuits and their applications for processing analog signals. Through the study of this course, students will become proficient in the performance of commonly used analog semiconductor devices, the working principles and applications of analog signal processing circuits, and the design, construction, testing, and analysis of analog circuits using simulation software. This will enable students to have preliminary analysis and design abilities in analog circuits, laying a solid foundation for further learning electronic technology and its application in their majors.

Digital Logic Circuit A

Institute: School of Electronic Information

Credits: 3.5

Credit hours: 56

Course number: 2104404

This course is a subject that studies the functions and applications of various digital logic circuits. Through the study of this course, students will become proficient in the basic concepts of digital logic circuits, the functions of gate circuits and triggers, the analysis and design methods of combinational logic circuits and sequential logic circuits, and the functions and applications of commonly used digital logic circuits. Cultivate students' ability to analyze and solve practical problems, logical thinking ability, and practical hands-on ability, so that they can apply the basic principles, analysis, and design methods of digital logic circuits to analyze, judge, and design digital logic circuits, laying the foundation for learning the principles and applications of microcontrollers, embedded system foundations, and other subsequent courses.

Radio Waves and Antennas 

Credit: 2

Credit hours: 32

Course number: 2104407

The course Radio Waves and Antennas is an important professional foundation course for undergraduate students majoring in Electronic Information Engineering. Based on studying courses such as College Physics and Fundamentals of Circuit Analysis A, it enables students to master the basic concepts, principles, and laws of electromagnetic fields and waves, understand the basic methods of quantitative analysis of electromagnetic fields, master the basic properties of electric fields and magnetic fields, and the motion forms of electromagnetic waves, and master the basic concepts of antennas Classic antenna analysis methods and basic characteristics of modern antennas, mastering the basic models, characteristics, and influencing factors of radio wave propagation.

Digital Signal Processing

Institute: School of Electronic Information

Credit: 4

Credit hours: 64

Course number: 2104423

This course is the core course of the Electronic Information Engineering major, introducing the basic concepts, principles, analysis methods, and processing techniques of digital signal processing. The main content includes the basic theory of discrete time signals and systems, Fourier transform DTFT of discrete time signals, discrete Fourier transform DFT theory and its fast algorithm FFT, basic network structure of time-domain discrete systems, and design of IIR and FIR digital filters. Through the study of this course, the foundation can be laid for subsequent courses such as detection technology and applications, measurement and control system principles and applications, and digital image processing.

Principles and Applications of Measurement and Control Systems

Institute: School of Electronic Information

Credit: 3

Credit hours: 48

Course number: 2104430

This course is a discipline that focuses on information acquisition and processing, control algorithms, and applications. It is based on the quadcopter unmanned aerial vehicle experimental platform, mainly focusing on two aspects: airborne sensors and flight control algorithms. It is a combination of theory and practice. Through the study of this course, students will become proficient in the interface design and data processing algorithms of various sensors (attitude, pressure altitude, magnetic heading, etc.), as well as typical algorithms of basic control systems widely used such as PID and Kalman filtering. They will also understand the working principles and applications of control systems such as drones, and the basic framework for information acquisition and processing in their major, This will enable students to initially possess the basic development ability of control systems, laying a solid foundation for future engineering practice and graduation design.

Data Transmission Technology A

Institute: School of Electronic Information

Credits: 3

Credit hours: 36

Course number: 2104428

This course focuses on the technical methods of data transmission between MCU and peripheral devices in information systems, as well as between systems, and has strong practicality. It mainly includes basic knowledge of information and communication, principles and applications of buses and protocols (RS232 422 485 SPI IIC, etc.), composition, principles and characteristics of wired and wireless transmission systems (fiber optic, microwave, satellite, mobile), characteristics and applications of commonly used wireless modules (4G, NRF2401, LORA, NB, etc.), etc. The course focuses on the introduction of application and is a practical and broad comprehensive lecture course. Through the study of this course, students will be able to understand the basic principles and solutions of data transmission, thus enabling them to have a preliminary design ability for system data transmission, laying a solid foundation for future engineering practice and graduation design.

Wireless Location Technology

Institute: School of Electronic Information

Credit: 2

Credit hours: 32

Course number: 2104432

“Wireless Location Technology is a professional elective course for electronic information engineering majors. This course starts with the background of wireless positioning and location service requirements, basic knowledge of wireless positioning concepts, and focuses on the basic principles, design, and engineering practice of wireless positioning. It introduces wireless propagation theory, signal detection methods, basic theories of positioning systems, common positioning methods, positioning accuracy, and sensor network positioning technology Non line of sight communication technology and other core technologies and methods strive to achieve the organic integration of knowledge system integrity, theoretical and practical aspects, as well as the coordination and unity of classical theory and cutting-edge knowledge. Through the study of this course, students can have a more comprehensive and profound understanding of the knowledge system of wireless positioning technology, become familiar with the application methods and skills of wireless positioning technology in various engineering fields, and master the use of wireless positioning related technologies to solve positioning and location service problems in practical engineering.

Advanced Development of Microcontroller Applications

Credit: 2

Credit hours: 32

Course number: 2104427

This course is an elective course for electronic information engineering majors in higher education institutions, and is also a classic course that closely combines the theory of microcontrollers and embedded systems with practical engineering applications. This course mainly focuses on STM32 microprocessors and introduces the composition, principles, peripheral interfaces and communication bus protocols of embedded systems, hardware design of embedded systems, software design of embedded systems, embedded operating systems, and applications. Cultivate students' understanding of the basic principles, design methods, and the latest developments of embedded systems, preliminarily grasp the process and commonly used methods of embedded system development, master the working principles of typical embedded microprocessors, and become familiar with some commonly used real-time embedded operating systems. The course adopts a combination of lectures and experiments, with a focus on cultivating students' practical hands-on abilities. This course is applicable to majors such as Electronic Information Engineering, Information and Communication Engineering, and Embedded Software. The purpose of setting up this course is to enable students to understand the basic concepts of embedded systems, familiarize themselves with the development process of embedded systems, and preliminarily establish the development and debugging methods of electronic systems with STM32 microcontroller as the core, laying the foundation for engaging in comprehensive embedded system development work.

Radar Signal Processing

Institute: School of Electronic Information

Credits: 2

Credit hours: 32

Course number: 2104434

“Radar Signal Processing” is a professional elective course for electronic information engineering majors, designed for third year college students. The main knowledge of electronic technology and signal processing is reflected in the field of radar. This course aims to provide students with a preliminary understanding of the application of professional knowledge in the field of radar, to understand the basic principles and typical scenarios of radar signal processing, to understand basic knowledge in the field of radar, and to possess preliminary radar signal processing development capabilities. At the same time, guide students to establish a preliminary awareness of professional norms, the connotation and significance of environmental and social sustainable development, and relevant regulations on environmental protection. By understanding the current development status of the radar field and the ideological and political aspects of the curriculum, we can establish a patriotic and professional mindset, aspire to become builders of the electronic information industry, guide students to form good learning methods, and initially establish a sense of self-directed learning and lifelong learning.

Signal and system analysis

Institute: School of Electronic Information

Credits: 4

Credit hours: 64

Course number: 2104405

This course is the core course of the Electronic Information Engineering major, mainly including the basic theory and analysis methods of signals and systems. The theoretical part of signals mainly studies the description methods and basic characteristics of signals, the establishment of signal mathematical models, and the transformation and processing methods of signals; The system theory section mainly includes establishing a mathematical model of the system, studying the basic properties of the system with the help of the system mathematical model, and solving the system response. Through the study of this course, students will be able to systematically and deeply apply the basic concepts and methods of signal and system analysis to analyze and calculate the process of signal passing through linear systems, mathematical modeling, system structure design, etc., thereby improving their ability to analyze and solve problems, as well as their autonomous learning ability.

FPGA System Design A

Institute: School of Electronic Information

Credits: 3

Credit hours: 48

Course number: 2104426

This course is a professional foundation course that plays a connecting role in the professional talent cultivation system. It aims to further cultivate students' abilities in FPGA based digital system design, embedded system design, and practical application, based on their knowledge of digital logic circuits and microcontroller system design and development. Guide students to design digital logic circuits, drive FPGA peripheral interfaces, and design digital systems by learning the internal structure principles, peripheral interface circuits, and hardware description language VerilogHDL of FPGA. By becoming familiar with the development tool QuartusII and simulation tool ModelSim, students can complete the overall development process of FPGA digital systems, including design, simulation, verification, configuration, and download, and cultivate their skills in integrated circuit design and development. Through comprehensive experimental projects and course design, cultivate students' ability to use EDA integrated development tools, collaborate in teams, and effectively communicate and exchange ideas; Possess the ability to design and develop digital systems, as well as certain embedded system design and practical skills, laying the foundation for future collaborative development of FPGA based embedded systems.

FPGA System Design A Course Design 

Institute: School of Electronic Information

Credits :1

Credit hours: 1 week

Course number: 2104458

Based on the theoretical foundation of FPGA System Design A learned, use QuartusII and Modsim integrated development platform as implementation tools to carry out preliminary design of the FPGA system and complete the specified design tasks within the specified time. Through course design, students are required to understand the design ideas of FPGA systems, implement the hardware structure principles of related systems, and the basic process of program design, in order to cultivate their ability to analyze and solve practical engineering problems and engage in engineering design. Through the study of this course, students can preliminarily master the design methods of integrated circuits and digital systems, laying the foundation for future work in FPGA based embedded system design and development.

Course Design of Digital Signal Processing

Institute: School of Electronic Information

Credits :1

Credit hours: 1 week

Course number: 2104457

This course is a compulsory course for telecommunications engineering majors, titled Digital Signal Processing. It aims to deepen students' understanding and comprehension of the basic concepts and theories of digital signal processing, and cultivate their ability to comprehensively apply the knowledge they have learned to analyze and solve problems. At the same time, through methods such as literature review, cultivate students' programming and document writing abilities. Cultivate students' teamwork and effective communication and communication skills through group discussions and centralized defense of the project. This course design requires students to apply relevant knowledge of digital signal processing to achieve the collection, transmission, and storage of speech signals, and to design appropriate digital filters to process the signals, achieving the expected design functions. Students are able to effectively express their thoughts and learn how to write design reports during the final defense.

Comprehensive practice of detection Technology

Institute: School of Electronic Information

Credits: 2

Credit hours: 2 weeks

Course number: 2104424

“Comprehensive Practice of Detection Technology”is an important professional course for electronic information engineering majors, mainly introducing the latest technology and development trends of sensors, mathematical models and response characteristics of sensors, as well as methods for collecting, analyzing, and processing physical, chemical, and biological signals. Due to the high degree of intersection between this course and other courses, it requires extensive knowledge accumulation. Comprehensive Practice of Testing Technology is a highly comprehensive and practical teaching link that is paired with the course Testing Technology and Application . Students apply the sensor technology they have learned to preliminarily design a sensor application system and complete the designated design tasks within the specified time. Through course design, students are required to understand the structural principles, working processes, and basic content of sensor application systems, master the basic steps and design methods of sensor application system design, in order to cultivate their ability to analyze and solve practical engineering problems, and then engage in engineering design.

 Principles and Applications of Microcontrollers A

Institute: School of Electronic Information

Credits: 3.5

Credit hours: 56

Course number: 2104420

This course plays a connecting role in the professional talent cultivation system, with a focus on guiding students to master the hardware structure of the 51 series microcontroller, the C51 language programming of the microcontroller, the interface circuit design and programming of single-chip application systems, and the use of development tools for system simulation and debugging. Through course assignments and experimental projects, cultivate students' teamwork skills, effective communication and communication skills. Through the study of this course, students can master the interface circuit design and programming of various functional modules in microcontroller application systems, as well as the development, design, and debugging methods of application systems. They have the ability to research and develop electronic systems centered on microcontrollers.

Detection Technology and Application

Institute: School of Electronic Information

Credits: 2.5

Credit hours: 40

Course number: 2104424

This course is a professional course for electronic information majors in higher education institutions. Through the study of this course, students will be able to understand the latest developments in detection technology, master the methods of collecting, analyzing, and processing physical, chemical, and biomass signals using sensors, and become familiar with the mathematical models and response characteristics of sensors. This course is accompanied by experiments to enable students to master the functions and usage methods of general sensors, and to independently design simple sensor systems. This course not only has a strong guiding role in the study of comprehensive application courses in the field of electronic information engineering, improving students' comprehensive analysis ability and solving complex engineering problems, but also has an important guiding role in the selection of electronic components for students in their graduation designs.

Embedded System Design

Institute: School of Electronic Information

Credit: 3

Credit hours: 48

Course number: 2104431

This course is an elective course in the field of Electronic Information Engineering. UML is the most widely used modeling method for visual object-oriented systems. The course mainly teaches object-oriented analysis methods. UML introduces modeling ideas into the design and development process of embedded systems. Through the learning of modeling technology knowledge, students are familiar with the basic meaning of symbols in UML modeling language, understand the meaning of different modeling diagrams, master the ability to use UML modeling tools to obtain user requirements, analyze and design systems, and complete system modeling through diagrams that meet international standards.

Communication Circuits and Systems

Institute: School of Electronic Information

Credits: 3

Credit hours: 48

Course number: 2104425

This course is the core course of the Electronic Information Engineering major, mainly introducing the composition of analog communication systems, basic concepts, working principles, characteristic analysis, performance index calculation, and circuit design methods related to frequency selection circuits, small signal amplifiers, high-frequency power amplifiers, sine wave oscillators, amplitude modulation demodulation and mixing circuits, angle modulation and demodulation circuits. After completing this course, students will be able to apply the basic concepts and analysis of communication circuits and systems, as well as design methods, to analyze the working status of various functional modules in analog communication systems, calculate performance index parameters, and design circuits.

Control Algorithms and Applications

Credits: 3

Credit hours: 48

Course number: 2104410

This course is a professional elective course in the field of Electronic Information Engineering. It starts with the background of system control requirements, control theory, and other basic knowledge, with a focus on the basic principles, design, and engineering practice of control algorithms. It introduces the basic theories and applications of linear systems, sensor data acquisition and preprocessing, classic control algorithms, modern control algorithms, intelligent control algorithms, and other core technologies and methods, Strive to achieve the organic integration of knowledge system integrity, theoretical and practical aspects, as well as the coordination and unity of classical theory and cutting-edge knowledge. Through the study of this course, students can have a more comprehensive and profound understanding of control algorithms and their application knowledge system, become familiar with the application methods and skills of typical control algorithms in various engineering fields, and enhance their ability to design scientific control algorithms to solve practical engineering problems.

Fundamentals of Communication Technology

Institute：School of Electronic Information

Credits：3.5

Credit hours：56

Course number：2104408

This course is the core course of the Electronic Information Engineering major. This course focuses on the basic principles of information transmission, mainly introducing the basic concepts involved in communication, the composition of communication systems, the characteristics and performance of various communication methods, and the main analysis methods of communication system performance. Through the study of this course, students will be able to proficiently use professional terminology and information theory knowledge in communication systems, analog modulation, speech coding, multiplexing, digital baseband transmission, digital modulation, optimal reception, and other knowledge, to solve problems such as signal representation, system design, and performance analysis in the process of information transmission. To lay a solid theoretical foundation for the subsequent learning of electronic information engineering professional knowledge.

Information processing program design

Credits：2

Credit hours：32

Course number：2104409

This course is an elective course established for the Electronic Information Engineering major, with the task of cultivating students' comprehensive application ability of computer software development languages and tools. This article mainly introduces Python basic programming, data visualization, Python machine learning, classification implementation of BP neural network, and practical application of TensorFlow deep learning. Through the learning and practical experience of this course, students will master the basic techniques and methods of using Python for information processing program design, possess the basic ability of software development, and lay a foundation for future information processing software development and application.

Embedded System Project Practice

Credits：2

Credit hours：2 weeks

Course number：2104462

This course is an engineering practice course for the field of electronic information engineering. The course content is aimed at the fields of biological information and smart medicine, using advanced modern signal processing, statistical signal processing, image processing, and machine learning technologies. It is based on the Python environment to achieve intelligent recognition of biological information. Through the study of this course, it helps to broaden students' horizons, enable them to understand the forefront of information processing and artificial intelligence development in their major, and also enable them to master certain scientific research methods and skills, which helps to improve their theoretical and engineering practical abilities.

Engineering Practice of Biological Signal Detection and Processing

Credits：2

Credit hours：2 weeks

Course number： 2104459

This course is a compulsory course for electronic information engineering and an important comprehensive practical link that supports the development direction of edge intelligence in this major. This course comprehensively applies relevant knowledge from multiple courses such as electronic circuit technology, microcontroller and interface technology, sensor and detection technology, and embedded system design, guiding students to complete a comprehensive and multifunctional embedded system. The course includes tasks allocation, scheme design, basic platform and module development, software development, system joint experimentation and testing, project report writing, reporting, and defense. Through the learning and practice of this course, cultivate students' practical skills and embedded project development abilities. Guide students to apply their professional knowledge, consult relevant materials according to task requirements, design argumentation plans, and complete project software and hardware design, system joint testing, report writing through hands-on work. Finally, complete this course through reporting and defense, enabling students to have basic embedded project development and application abilities.

Measurement and Control System Engineering Practice

Credits：4

Credit hours：4 weeks

Course number： 2104448

Measurement and Control System Engineering Practice is a compulsory course for electronic information engineering majors, and is a comprehensive practical link that reflects one of the professional development directions of information measurement and control technology. Based on the comprehensive experimental box of unmanned aerial vehicles and quadcopter unmanned aerial vehicles, and the relevant knowledge of multiple courses such as microcontroller, detection technology, algorithms and applications, and measurement and control system principles, the development of sensor interfaces, control algorithms, flight control, remote control and telemetry of unmanned aerial vehicles is completed, and ultimately the flight control of a unmanned aerial vehicle is achieved. The course includes tasks, design plans, basic unit training, flight control development, flight testing and testing, writing project reports, reporting, and defense.

Through the learning and practice of this course, cultivate students' practical and project development abilities. Guide students to apply their professional knowledge, consult relevant materials, design argumentation plans according to task requirements, and complete project algorithm design, flight testing, report writing through hands-on work. Finally, complete this course through reporting and defense, enabling students to have basic project development abilities.