Graduate
Ethics for Engineers
2Credits
32Hours
2Credits
32Hours
Curricula Introduction:Ethics for Engineers will provide ethics training to graduate students in engineering and technology. The course prepares students to become familiar with discussions and methods for developing ethical approaches to engineering research and applied projects. Contemporary issues in engineering ethics will be presented and discussed. These issues include research integrity, professional ethics, human subjects protections, environment and animal protections, intellectual property rights, software license issues and sustainability.
Innovation, Technology and Management in Modern Engineering
3Credits
48Hours
3Credits
48Hours
Curricula Introduction:The objective of the course is to give students a general overview and roadmap of creating cutting edge technology innovation. It also attempts to give students a deeper understanding how engineering practice works, how to become best engineering performers. The concept of critical thinking, decision making and intellectual property (IP) rights, protection, and management from a technology development perspective will be introduced. Through case studies, students will appreciate that decisions about which technologies to develop, the development process, the management aspects and how to turn them into real products in projects. The aspect of finance, market study and commercialization will also be covered. Lectures, in class discussions, debates and group projects are used to deliver the course content.
Optical electronics in Modern Communications
3Credits
48Hours
3Credits
48Hours
Curricula Introduction:This course is intended to introduce to you various optical communication devices and systems, as well as advanced technologies in today’s optical communications systems and networks. Upon the completion of the course, you should be able to:
1.Differentiate various types of optical fibers
2.Determine how to use active and passive optical devices in optical fiber communication systems
3.Identify the performance issues of the most important relevant devices.
4.Implementation of fiber optic communication systems such as an elementary WDM optical fiber system.
Nonlinear Circuit and system
3Credits
48Hours
3Credits
48Hours
Curricula Introduction:This course is intended to introduce to you the theory and application of microwave circuit using nonlinear technique. Upon the completion of the course, you should be able to:
1.Familiar with the fundamental theory of circuit using nonlinear technique;
2.Familiar with the fundamental analysis of circuit using nonlinear technique;
3.Theoretically understand the essence of circuit using nonlinear technique;
4.Learn the physical significance of the phenomenon of circuit using nonlinear technique.
Computational Electromagnetics
3Credits
48Hours
3Credits
48Hours
Curricula Introduction:Understanding the foundations and intricacies of the computational techniques commonly used in Computational Electromagnetics. Acquiring the ability to select the “optimum” technique for a particular problem, to develop a soft package, and to carry out research for advancing the methods learned.
Antenna Theory and Techniques
3Credits
64Hours
3Credits
64Hours
Curricula Introduction:This course introduces the basic theory of antennas and propagation including antenna basics, wire antennas, slot and patch antennas and horn antennas, antenna arrays, radio wave propagation basics, and path loss model. The students use antenna theories and simulations to analyze realistic and reasonably complex antenna problems.
Semiconductor Optoelectronics
3Credits
48Hours
3Credits
48Hours
Curricula Introduction:This course is suitable for optoelectronic and microelectronic year 1 master student, is very basic and important. By learning the curriculum, students will understand and grasp several aspects of semiconductor optoelectronics: Theory of optical waveguide, optical waveguide devices and integrated devices technologies, semiconductor emitters, semiconductor receivers, materials and fabrication methods of integrated optoelectronics, which allows students to systematically comprehensive and understand the semiconductor optoelectronics domain knowledge.
Integrated Circuit Design with EDA Design Methodology
3Credits
64Hours
3Credits
64Hours
Curricula Introduction:The primary objective of the course is to make the students get introduced with Internet-of-Things (IoT), its architecture, components and various issues such as security, privacy, energy preservation etc. Through the course the students will also become aware of how various other important domains such as Computer Network Communication Protocols, Artificial Intelligence, Machine Learning, Data Analytics etc. are applied together to bring efficient collaboration among “Things” despite massive size and inherent heterogeneity issues in IoT.
Micro-Nano sensors and applications
3Credits
48Hours
3Credits
48Hours
Curricula Introduction:Course Learning Objectives: By the end of this class, students could master:
MEMS technology;
Micro-nano sensor principle;
Concept, design, fabrication and application of micro-nano sensors;
Health sensors;
Autonomous driving sensors;
Wireless passive sensors.
Modern signal processing
3Credits
48Hours
3Credits
48Hours
Curricula Introduction:Parameter estimation. Least-square, mean-square, and minimum-variance estimators. Maximum A Posteriori (MAP) and Maximum-Likelihood (ML) estimators. Bayes estimation. Cramer-Rao lower bound. Continuous and discrete time detection and estimation.
Advanced Characterization Techniques for Electronic Materials
1Credits
16Hours
1Credits
16Hours
Curricula Introduction:To understand the various characterization techniques that can used for electronic materials;
To be able to apply these techniques in the analysis of electronic materials and research.
Advanced Nonlinear Optimization
3Credits
64Hours
3Credits
64Hours
Curricula Introduction:Learn nonlinear optimization concepts/algorithms;
Learn application of nonlinear optimization ;
Learn Matlab and Optimization Toolbox ;
Identify optimization problem and suggest possible optimization algorithms ;
Solve optimization problems using Matlab
SPECTROSCOPY AND SPECTRAL TECHNOLOGY
3Credits
48Hours
3Credits
48Hours
Curricula Introduction:After the completion of this course, students should know the following items. (1) Familiar with the principle of all kinds of spectrum technology; have a comprehensive understading of all kinds of detection methods which will be useful for their future research work; (2) Understand the specific content including spectroscopy, conventional spectra-system and laser spectroscopy technology.
BioMEMS and Lab-on-a-Chip
3Credits
48Hours
3Credits
48Hours
Curricula Introduction:Pre-requisites:The class will be offered for both Master and Ph.D students and will be taught together.
The field of BioMEMS and Lab-on-a-Chip has seen tremendous growth in the past several years. The Lab-on-a-Chip concept and its advantages will be introduced. Various microfabrication techniques that are commonly used in BioMEMS device fabrications will be taught. Microfluidics, which is the foundation for most of the applications, will be covered flowed by the various chemical and biomedical applications such as separation, minimally invasive diagnosis tools, implantable devices, drug delivery, and microsystems for cellular studies and tissue engineering. Students will gain a broad perspective in the area of miniaturized systems for biomedical and chemical applications.
Advanced Display and Lighting Technologies
2redits
40Hours
2redits
40Hours
Curricula Introduction:This course will introduce advanced display and lighting technologies and related emerging developments. For the display part, this course will focus on plane display technologies, including liquid crystal display, organic light emitting display, quantum dot light emitting display, and thin-film-transistor driving technologies. Moreover, other emerging display technologies, such as lase display, 3D display, touch display, e-paper, etc., also will be introduced. For the lighting part, this course will focus on solid state lighting technologies, including GaN epitaxial growth, LED chip, LED packaging, and LED optical design and thermal management technologies. Moreover, other emerging LED technologies, such as visible light communication, quantum dot LED, etc., also will be introduced. After completing the course, students should master the fundamental sciences behind each display technology and solid state lighting technology and understand the cutting-edge technologies and development trends of this area.
Nonlinear Optics
3Credits
48Hours
3Credits
48Hours
Curricula Introduction:先修要求:光学基础,量子力学
Combining the lectures, discussion, and experiments, inspire the students to learn more actively, enhance the students’s understanding of the principles of nonlinear optics and capability of conducting research in this field.
