Objective
Introduction to wearable technology, reviews on wearable robotics, wearable sensor principles, wearable augmentation and machine intelligence, wearable design by "MINDS" (Miniaturization, Intelligence, Networking, Digitization, and Standardization), wearable medical devices and systems, wearable electro-physiologies, implantable therapeutic systems, sensor informatics, data-driven intelligent applications, and project topics of current interests.

Syllabus
Introduction to health informatics, fundamentals in electro-physiologies, reviews on bio-electronics including ion channels, sensor principles, e-textile sensing, flexible-stretchable-printable bioelectronics, organic transistors, wearable design by "MINDS" (Miniaturization, Intelligence, Networking, Digitization, and Standardization), wearable medical devices and systems, wearable robotics, implantable therapeutic systems, sensor informatics, applications, and topics of current interests.

Learning Outcome
Upon completion of this course, students will be able to

• Understand the basic concepts of wearable electronics technology
• Understand the basic principles of sensor technology for wearable device design
• Learn the fundamentals of wearable robotics
• Know how to design wearable devices and systems
• Familiar with applications of machine intelligence in wearable electronics and healthcare

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Objective

Syllabus
Overview of optical fibre communications. Types and properties of fibres. Optical transmitters, receivers, and repeaters. Passive optical component. Optical modulation and multiplexing techniques. Fibre communication systems. Optical networks. Introduction to optical interconnects. Silicon photonics. Active optical cables. Recent trends in optical interconnects.

Learning Outcome
By the end of the course, students should obtain an overall picture of the history and recent developments of optical communications, and understand its advantages and limitations. They will acquire knowledge on the operating principle and technology of different key components in an optical communication system and optical interconnects. They should be able to apply skills for the design of basic fibre components, systems, and networks and carry out qualitative and quantitative analyses on their performances.

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Objective

Syllabus
Starting with the introduction of different types of Intellectual Property (IP), such as patents, trademarks, registered design, copyright and trade secret, etc., from legal regulations, going through case studies and the best practices of intellectual property rights (IPR) protection and enforcement, to establish a foundation for the proactive management of IP and commercialization of technologies and innovations.

This course covers the following elements:

1. Introduction of different types of IP from legal definition, requirements, and scope of protection
2. Enforcement of different types of IP and the economic impact of IP
3. IP information analysis and applications
4. IP valuation and finance
5. IP exploitation and anatomy of licensing agreement
6. Formulating IP management strategy

Learning Outcome
This course aims to raise awareness of the principal concepts of Intellectual Property Management (IPM) and its importance as a spur to human creativity and the advancement of economic and social development. It also provides explanation on the development and implementation of an IPM strategy including the management of intellectual property (IP) in a company or an organization.

After going through the course, students are able :

• To identify the proper types of IP protection for an innovation
• To formulate a strategy to exploit a technology with IP protection
• To use IP information for planning and decision making
• To handle IP transactions through licensing
• To establish an IP management strategy for an organization

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Objective

Syllabus
Comparison between different lighting sources, lighting standards, basics of all-solid-state lamps, solid-state lighting systems, sensor fundamentals, signal conditioning, functional aspects of different sensors, sensor device examples, technology trend and challenges of solid-state lighting and sensor devices.

Learning Outcome
By the end of the course, students should demonstrate the following outcomes:

• have a brief picture of the technology aspects of various solid-state lighting systems and sensor devices;
• clear understanding on the physics of light generation from semiconducting junctions, important parameters governing the performance of high-power light-emitting diodes, system design consideration;
• clear understanding on the operation principles of common sensor devices and their design considerations;
• appreciation of technology trend and challenges of solid-state lighting and sensor device technologies.

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