INDUSTRIAL ENGINEERING | |||||
Bachelor | TR-NQF-HE: Level 6 | QF-EHEA: First Cycle | EQF-LLL: Level 6 |
Course Code | Course Name | Semester | Theoretical | Practical | Credit | ECTS |
BME1071 | Introduction to Biomedical Engineering | Fall Spring |
2 | 2 | 3 | 6 |
This catalog is for information purposes. Course status is determined by the relevant department at the beginning of semester. |
Language of instruction: | English |
Type of course: | Non-Departmental Elective |
Course Level: | Bachelor’s Degree (First Cycle) |
Mode of Delivery: | Face to face |
Course Coordinator : | Dr. Öğr. Üyesi HAKAN SOLMAZ |
Course Lecturer(s): |
Dr. Öğr. Üyesi HAKAN SOLMAZ |
Recommended Optional Program Components: | None |
Course Objectives: | The objectives of this course are; - To introduce students to the field of Biomedical Engineering (BME) with the excitement of this rapidly growing field - To communicate students to the academic preparation needed for successful study and professional careers in the different sub-disciplines of BME - To guide and advise students for their future plans and studies - Providing students with information and support for other engineering or life sciences programs or different sub-disciplines of BME |
The students who have succeeded in this course; Students who succeeded this course will; - Have basic knowledge about the applications of engineering principles in biomedical engineering - Know the definition of biomedical engineering and learn the areas of interest of biomedical engineers - Know the applications of basic sciences in physics, chemistry, biology and mathematics in the field of biomedical engineering - Know the definition and working fields of the clinical engineer - Know to make research for providing solutions and methods to solve basic problems and interpret the results. |
- Fundamentals of biomedical engineering, - To understand the relationship between biomedical engineering and clinical engineering, - Fundamentals of physics, biology, physiology, mechanics and electricity and electronics, - Fundamentals of biomedical instrumentation, - Biosensors and their working principles, - Optics and Photonics in medical applications, - Medical imaging modalities. |
Week | Subject | Related Preparation |
1) | Introduction to Biomedical Engineering | |
2) | Biomedical Equipment Technology | |
3) | Fundamentals of Physics in Biomedical Engineering | |
4) | Fundamentals of Mechanics in Biomedical Engineering | |
5) | Fundamentals of Biology in Biomedical Engineering | |
6) | Fundamentals of Human Physiology | |
7) | Electrical Fundamentals of Biomedical Engineering | |
8) | Midterm Exam | |
9) | Biological Signals | |
10) | Bioinstrumentation | |
11) | Biosensors | |
12) | Biomedical Optics | |
13) | Principles of Medical Imaging | |
14) | Clinical Engineering |
Course Notes / Textbooks: | Power Point slides will be available for student review. |
References: | 1. G.S. Sawhney, “Fundamentals Of Biomedical Engineering” ISBN (13) : 978-81-224-2549-9, (2007). 2. Joseph D. Bronzino, “The Biomedical Engineering Handbook Third Edition Medical Devices and Systems” (2006). 3. John G. Webster, "Medical Instrumentation, Application and Design" Fourth Edition, (2009) |
Semester Requirements | Number of Activities | Level of Contribution |
Attendance | 10 | % 10 |
Midterms | 1 | % 30 |
Final | 1 | % 60 |
Total | % 100 | |
PERCENTAGE OF SEMESTER WORK | % 40 | |
PERCENTAGE OF FINAL WORK | % 60 | |
Total | % 100 |
Activities | Number of Activities | Duration (Hours) | Workload |
Course Hours | 14 | 3 | 42 |
Study Hours Out of Class | 14 | 7 | 98 |
Midterms | 1 | 2 | 2 |
Final | 1 | 2 | 2 |
Total Workload | 144 |
No Effect | 1 Lowest | 2 Low | 3 Average | 4 High | 5 Highest |
Program Outcomes | Level of Contribution | |
1) | Build up a body of knowledge in mathematics, science and industrial engineering subjects; use theoretical and applied information in these areas to model and solve complex engineering problems. | |
2) | Identify, formulate, and solve complex engineering problems; select and apply proper analysis and modeling methods for this purpose. | |
3) | Design a complex system, process, device or product under realistic constraints and conditions, in such a way as to meet the desired result; apply modern design methods for this purpose. The ability to apply modern design methods to meet this objective. | |
4) | Devise, select, and use modern techniques and tools needed for solving complex problems in industrial engineering practice; employ information technologies effectively. | |
5) | Design and conduct experiments, collect data, analyze and interpret results for investigating the complex problems specific to industrial engineering. | |
6) | Cooperate efficiently in intra-disciplinary and multi-disciplinary teams; and show self-reliance when working independently. | |
7) | Demonstrate effective communication skills in both oral and written English and Turkish. Writing and understanding reports, preparing design and production reports, making effective presentations, giving and receiving clear and understandable instructions. | |
8) | Recognize the need for lifelong learning; show ability to access information, to follow developments in science and technology, and to continuously educate him/herself. | |
9) | Develop an awareness of professional and ethical responsibility, and behaving accordingly. Information about the standards used in engineering applications. | |
10) | Know business life practices such as project management, risk management, and change management; develop an awareness of entrepreneurship, innovation, and sustainable development. | |
11) | Know contemporary issues and the global and societal effects of modern age engineering practices on health, environment, and safety; recognize the legal consequences of engineering solutions. | |
12) | Develop effective and efficient managerial skills. |