Master's Program in Electrical and Electronic Engineering

Training engineers and researchers capable of responding to environmental issues and energy conservation.

This program is based on the "Report on Graduate Education in the Era—Towards Building an Attractive Graduate Education Internationally" (Central Council for Education, September 5, 2005), and aims to develop highly specialized professionals with advanced knowledge and skills. It provides foundational knowledge and general abilities essential for applying engineering theories, while ensuring mastery of advanced knowledge and techniques in engineering, and developing a broad perspective.

Specifically, it provides education based on advanced specialized knowledge and techniques in electrical and electronic engineering, focusing on practical exercises and research activities to address societal challenges such as environmental issues and energy conservation. The goal is to develop professionals who can identify social issues, respond flexibly and creatively, and continuously improve their technical abilities while contributing to regional communities and industries.

Additionally, the program trains professionals to support and develop technologies fundamental to an energy-efficient and highly informatized society, such as electrical energy, efficient electrical machinery, power conversion, and technologies for improving daily life, including electronic materials, sensors, measurement, and control technologies. The program is structured into three specialized fields:

(1) Basic Electrical and Electronic Engineering: Focuses on understanding the physical and electrical properties of various solid, semiconductor, gaseous, and magnetic materials, plasma electronics, semiconductor engineering, and electronic devices.
(2) Electrical Systems Engineering: Analyzes electrical systems and their components, energy generation, conversion, transportation, control, utilization, power electronics, high-voltage engineering, electrical machinery engineering, and electromagnetic field numerical analysis.
(3) Applied Electrical and Electronic Engineering: Covers ultrasonic measurement, development of related electronic technologies, acoustic signal processing, electrical and electronic measurement, power conversion device performance enhancement, control engineering, optical material properties, laser engineering, optoelectronic control, signal processing, and life support applications.

Summary

Diploma Policy

A degree will be awarded to those who complete the prescribed period, earn the required credits, pass the thesis examination and final exam, and fulfil the following requirements:

(1) Possess advanced specialized knowledge and skills backed by basic knowledge and techniques in natural sciences and the specialized field of electrical and electronic engineering, along with the general education necessary for highly skilled professionals and researchers.

(2) Have the ability to independently identify social issues in the field of electrical and electronic engineering and acquire advanced knowledge, logical thinking, and techniques required to solve these issues, including electrical energy, electrical machinery, power conversion, electronic materials, sensor technologies, and measurement and control technologies.

(3) Apply advanced knowledge and techniques in electrical energy, electrical machinery, power conversion, electronic materials, sensor technologies, measurement and control technologies, and develop the ability to solve problems flexibly with a broad perspective, continually improving technical capabilities.

(4) Possess advanced presentation and communication skills, explaining their thought and decision-making processes, providing concrete examples and evidence.

(5) Effectively perform group work and research activities, using team-building methods to establish strong collaborative relationships.

(6) Understand the ethics and social responsibilities to be upheld as advanced professionals and researchers in the field of electrical and electronic engineering.
Curriculum Policy

To equip students with the abilities outlined in the Diploma Policy, the curriculum is based on the following principles:

(1) Offer courses that develop foundational knowledge and general abilities necessary for applying and developing engineering theories in the field of electrical and electronic engineering, as well as courses that ensure mastery of advanced specialized knowledge and techniques in electrical energy, electrical machinery, power conversion, electronic materials, sensor technologies, and measurement and control technologies.

(2) Provide courses that apply advanced specialized knowledge and general abilities in electrical energy, electrical machinery, power conversion, electronic materials, sensor technologies, and measurement and control technologies, while developing the ability to set challenges with a broad perspective, develop and implement action plans, and collaborate with others to verify and improve solutions.

(3) Offer courses that promote understanding of ethics and social responsibilities, including respecting life, complying with laws, and prohibiting data manipulation, plagiarism, and theft, essential for advanced professionals or researchers.