Biomedical Engineering (English) | |||||
Bachelor | TR-NQF-HE: Level 6 | QF-EHEA: First Cycle | EQF-LLL: Level 6 |
Course Code: | UNI309 | ||||
Course Name: | Introduction to Metaverse | ||||
Semester: | Fall | ||||
Course Credits: |
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Language of instruction: | English | ||||
Course Condition: | |||||
Does the Course Require Work Experience?: | No | ||||
Type of course: | University Elective | ||||
Course Level: |
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Mode of Delivery: | E-Learning | ||||
Course Coordinator: | Prof. Dr. HATİCE ÖZ PEKTAŞ | ||||
Course Lecturer(s): | Michael Barngrover | ||||
Course Assistants: |
Course Objectives: | The main objective of the course is to develop within students an understanding of the core components of the metaverse and an awareness of its potential impacts on society. By the end of the class, students will possess developed ethical positions on many of the important metaverse topics. |
Course Content: | The course introduces fundamental elements that form the foundation of various conceptualizations of “The Metaverse”. Topics to be presented and discussed include shared spatialization, digital mediation of reality, socialization, and assigning value to digital objects. The course will devote significant time to discussions of ethics and the impacts that digitization will have on non-digital aspects of society. Students will be required to research and write several essays throughout the course and design a metaverse scenario as a final group project. Online class sessions will frequently take place inside of 2D and 3D “metaverse platforms”. Students will be expected to know how to use their keyboard and mouse/touchpad to navigate these spaces and to use their microphone effectively. This is not a course focused on cryptographic topics. Blockchains, cryptocurrencies, and NFTs will not be the focus of the course, although these subjects will be included in discussions of metaverse economics and concepts of ownership. |
The students who have succeeded in this course;
1) Understand the concept and components of the Metaverse. 2) Understand the role and impact of avatars in the Metaverse learning environment. 3) Explore tools and modalities for synchronous learning in the Metaverse. 4) Address accessibility and equity considerations in designing inclusive Metaverse learning experiences 5) analyze the impact of diverse perspectives and cultures on Metaverse learning. |
Week | Subject | Related Preparation |
1) | he concept and the evolving dynamics of Metaverse | |
2) | origins of metaverse and its impact on various industries | |
3) | understanding the Metaverse's interactive digital environments, virtual reality (VR), augmented reality (AR), and mixed reality (MR) | |
4) | understanding the Metaverse's interactive digital environments, virtual reality (VR), augmented reality (AR), and mixed reality (MR)_2 | |
5) | ethical, legal, and privacy considerations related to Metaverse | |
6) | leveraging Metaverse for business growth, virtual reality, gaming and social interactions_1 | |
7) | leveraging Metaverse for business growth, virtual reality, gaming and social interactions_2 | |
8) | midterm week | |
9) | 3D modeling, programming, blockchain understanding, virtual reality integration, and AR development | |
10) | concepts of dataspace management, virtual economies, digital asset creation, and setting up interactive experiences | |
11) | future possibilities and innovations in the Metaverse ecosystem | |
12) | Student presentations | |
13) | Student presentations | |
14) | Student presentations | |
15) | final week | |
16) | final week |
Course Notes / Textbooks: | Readings to be assigned and provided in class Access to VR headsets and library of VR experiences Computers capable of opening webVR sites |
References: | Readings to be assigned and provided in class Access to VR headsets and library of VR experiences Computers capable of opening webVR sites |
Course Learning Outcomes | 1 |
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Program Outcomes | |||||||||||
1) Adequate knowledge of mathematics, science and biomedical engineering disciplines; Ability to use theoretical and applied knowledge in these fields in solving complex engineering problems. | |||||||||||
2) Ability to identify, formulate and solve complex biomedical engineering problems; ability to select and apply appropriate analysis and modeling methods for this purpose. | |||||||||||
3) Ability to design a complex system, process, device or product to meet specific requirements under realistic constraints and conditions; ability to apply modern design methods for this purpose. | |||||||||||
4) Ability to select and use modern techniques and tools necessary for the analysis and solution of complex problems encountered in biomedical engineering practices; Ability to use information technologies effectively. | |||||||||||
5) Ability to design, conduct experiments, collect data, analyze and interpret results for the investigation of complex biomedical engineering problems or discipline-specific research topics. | |||||||||||
6) Ability to work effectively in disciplinary and multi-disciplinary teams; individual working skills. | |||||||||||
7) Ability to communicate effectively orally and in writing; knowledge of at least one foreign language, ability to write effective reports and understand written reports, to prepare design and production reports, to make effective presentations, to give and receive clear and understandable instructions. | |||||||||||
8) Awareness of the necessity of lifelong learning; the ability to access information, follow developments in science and technology, and constantly renew oneself. | |||||||||||
9) Knowledge of ethical principles, professional and ethical responsibility, and standards used in engineering practices. | |||||||||||
10) Knowledge of business practices such as project management, risk management and change management; awareness of entrepreneurship, innovation; information about sustainable development. | |||||||||||
11) Information about the effects of biomedical engineering practices on health, environment and safety in universal and social dimensions and the problems of the age reflected in the field of engineering; Awareness of the legal consequences of biomedical engineering solutions. |
No Effect | 1 Lowest | 2 Average | 3 Highest |
Program Outcomes | Level of Contribution | |
1) | Adequate knowledge of mathematics, science and biomedical engineering disciplines; Ability to use theoretical and applied knowledge in these fields in solving complex engineering problems. | |
2) | Ability to identify, formulate and solve complex biomedical engineering problems; ability to select and apply appropriate analysis and modeling methods for this purpose. | |
3) | Ability to design a complex system, process, device or product to meet specific requirements under realistic constraints and conditions; ability to apply modern design methods for this purpose. | |
4) | Ability to select and use modern techniques and tools necessary for the analysis and solution of complex problems encountered in biomedical engineering practices; Ability to use information technologies effectively. | |
5) | Ability to design, conduct experiments, collect data, analyze and interpret results for the investigation of complex biomedical engineering problems or discipline-specific research topics. | |
6) | Ability to work effectively in disciplinary and multi-disciplinary teams; individual working skills. | |
7) | Ability to communicate effectively orally and in writing; knowledge of at least one foreign language, ability to write effective reports and understand written reports, to prepare design and production reports, to make effective presentations, to give and receive clear and understandable instructions. | |
8) | Awareness of the necessity of lifelong learning; the ability to access information, follow developments in science and technology, and constantly renew oneself. | |
9) | Knowledge of ethical principles, professional and ethical responsibility, and standards used in engineering practices. | |
10) | Knowledge of business practices such as project management, risk management and change management; awareness of entrepreneurship, innovation; information about sustainable development. | |
11) | Information about the effects of biomedical engineering practices on health, environment and safety in universal and social dimensions and the problems of the age reflected in the field of engineering; Awareness of the legal consequences of biomedical engineering solutions. |
Semester Requirements | Number of Activities | Level of Contribution |
Project | 1 | % 40 |
Midterms | 1 | % 30 |
Final | 1 | % 30 |
total | % 100 | |
PERCENTAGE OF SEMESTER WORK | % 70 | |
PERCENTAGE OF FINAL WORK | % 30 | |
total | % 100 |
Activities | Number of Activities | Workload |
Course Hours | 14 | 42 |
Study Hours Out of Class | 14 | 14 |
Project | 5 | 21 |
Midterms | 3 | 21 |
Final | 3 | 21 |
Total Workload | 119 |