SMART GRID INFORMATION ENGINEERING

In the era of Industry 4.0, the development of smart grid systems plays a crucial role in optimizing energy usage and improving the operational efficiency of electrical systems. If you're passionate about technology, renewable energy, and want to contribute to the development of intelligent energy solutions, the Smart Grid Information Engineering program is an excellent choice. Let’s dive into this field and explore the career opportunities it offers!

Program Introduction

The Smart Grid Information Engineering program was established in response to national demands for smart grid development. It integrates electrical engineering and information engineering, forming a new engineering discipline with the characteristics of "Electrical Engineering + Information Engineering". The program covers technical directions such as new energy generation and intelligent integration, grid dispatching and control, electric energy metering and monitoring, and computer networks. It aims to cultivate application-oriented talents with international vision, a sense of social responsibility, and innovation capabilities.

Educational Objectives

This program aims to cultivate well-rounded talents with firm ideals, sound moral character, physical and aesthetic development, and strong labor skills. Graduates will possess the ability to apply fundamental science, electrical, and information engineering knowledge and skills to solve complex engineering problems in smart grid automation and intelligence. Within five years of graduation, students are expected to:

• Competently manage the commissioning, maintenance, and operation of smart grid information systems;
• Be engaged in the engineering design and manufacturing of related devices;
• Develop and innovate smart grid information acquisition and processing systems;
• Demonstrate professional ethics, lifelong learning capacity, and teamwork and management skills.

Graduation Requirements

Graduates should be equipped with the following 12 core competencies to address complex problems in the smart grid domain:

1. Engineering Knowledge: Mastery of mathematics, physics, basic electrical engineering, and smart grid professional knowledge;
2. Problem Analysis: Ability to identify and analyze engineering problems and draw valid conclusions;
3. Design/Development of Solutions: Ability to design systems and solutions with awareness of innovation;
4. Research Ability: Skills in modeling, experimentation, and data analysis for scientific research;
5. Modern Tool Usage: Proficiency in using simulation software and modern measurement tools;
6. Engineering and Society: Understanding of the societal and cultural impacts of engineering practices;
7. Environment and Sustainability: Awareness of environmental protection and sustainable development;
8. Professional Ethics: Adherence to engineering ethics and social responsibility;
9. Individual and Teamwork: Strong skills in collaboration and leadership;
10. Communication Skills: Ability to write reports and communicate across cultural backgrounds;
11. Project Management: Knowledge of engineering management and economic decision-making;
12. Lifelong Learning: Capability for self-learning and adapting to technological development.

Core Courses

• Circuits
• Analog Electronic Technology
• Digital Electronic Technology
• DSP Technology and Applications
• Electrical Machines
• Power Electronics Technology
• Communication Principles
• Automatic Control Theory
• Power System Analysis
• Power System Protection and Relaying

Main Practical Teaching Components

• Electrical and Electronic Training
• Control-related Professional Training
• Comprehensive Professional Training
• Engineering Practice
• Cognitive Internship, Production Internship, Graduation Internship
• Graduation Design (Thesis)

Major Laboratory Courses

• Circuit Experiments
• Analog/Digital Electronics Experiments
• Communication Principles Lab
• Automatic Control & Microcontroller Experiments
• Power Electronics Lab
• Electrical Machinery Lab
• Power System Analysis and Relay Protection Lab
• Advanced Sensors for Smart Grids Lab
• Microgrid Technology Lab

Duration of Study

Four years (Undergraduate Program)

Degree Awarded

Students who meet the university’s academic requirements will be awarded a Bachelor Smart Grid Information Engineering Arts degree.

Program Features

The program emphasizes the ability to analyze and solve complex engineering problems related to smart grid dispatching and control, power metering and monitoring, smart electricity usage, and new energy integration. Students will be well-prepared for careers in production, design, R&D, education, and management within modern intelligent power systems. The program focuses on cultivating application-oriented and innovative talents with skills in informatization, automation, and interactivity.

Research Directions

• Communication and Data Processing in Smart Grids
• Intelligent Control of Power Systems
• New Energy Generation and Grid Integration
• Smart Sensing and Information Acquisition

Career Prospects

Graduates can work in the following areas:

• Power Grid Companies: Operation, maintenance, equipment management, and system dispatching
• Power Equipment Manufacturing Enterprises: Engineering R&D and product design
• Research Institutes or Universities: Technical development, teaching, and scientific research
• Government and Related Institutions: Power informatization and policy management

Related Majors

• Electrical Engineering and Automation
• Automation
• Communication Engineering
• Information Engineering

Top Universities Offering Smart Grid Information Engineering Programs in China

1. North China Electric Power University
2. Tianjin University
3. University of Electronic Science and Technology of China
4. Nanjing University of Science and Technology
5. Beijing Jiaotong University