ISTANBUL OKAN UNIVERSITY INFORMATION PACKAGE / COURSE CATALOGUE
| Mechatronics Engineering (English) | |||||
| Bachelor | TR-NQF-HE: Level 6 | QF-EHEA: First Cycle | EQF-LLL: Level 6 | ||
General course introduction information
| Course Code: | GST455 | ||||||||
| Course Name: | Coffee Scıence and Applıcatıons | ||||||||
| Course Semester: | Fall | ||||||||
| Course Credits: |
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| Language of instruction: | TR | ||||||||
| Course Requisites: | |||||||||
| Does the Course Require Work Experience?: | No | ||||||||
| Type of course: | Compulsory | ||||||||
| Course Level: |
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| Mode of Delivery: | Face to face | ||||||||
| Course Coordinator : | Öğr.Gör. HAKAN ATAKAN | ||||||||
| Course Lecturer(s): |
Öğr.Gör. HAKAN ATAKAN Assoc. Prof. İLKAY GÖK |
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| Course Assistants: |
Course Objective and Content
| Course Objectives: | The aim of this course is to enable students to understand the process from the agricultural origins of coffee to the cup in its scientific, technical and sensory dimensions. Within the scope of the course, students are expected to gain theoretical knowledge and practical skills regarding coffee botany, processing methods, roasting, grinding, brewing techniques, sensory analysis, chemical components and professional coffee applications. |
| Course Content: | -The history and cultural development of coffee -Coffea species (Arabica, Robusta, etc.) and botanical characteristics -Coffee cultivation, harvesting methods -Green coffee processing techniques (wet, dry, honey, etc.) -Roasting principles and roasting profiles -Grind sizes and their relationship to extraction -Brewing methods (espresso, filter, immersion, cold brew, etc.) -Chemical components in coffee (caffeine, polyphenols, antioxidants) -Sensory analysis and cupping -Coffee defects and quality classification -Professional barista practices -Sustainability and the third wave coffee approach |
Learning Outcomes
The students who have succeeded in this course;
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Lesson Plan
| Week | Subject | Related Preparation |
| 1) | Practice | no data |
| 1) | Discussion of the Course Content and Determination of Homework Topics | No data |
| 2) | • Coffee History | No data |
| 3) | • Coffeehouse Culture | No data |
| 4) | • Coffee bean | No data |
| 5) | • Espresso | No data |
| 6) | • Espresso | No data |
| 7) | • Filter coffee | No data |
| 8) | • Midterm exam | No data |
| 9) | • Coffee Machines and Equipment | No data |
| 10) | practice | No data |
| 11) | practice | No data |
| 12) | practice | No data |
| 13) | Practice | No data |
| 14) | • Homework Presentations | No data |
| 15) | • Repetition of the subject | No data |
| 16) | Final Exam | No data |
Sources
| Course Notes / Textbooks: | Öğretim elemanı tarafından hazırlanan ders slaytları Lecture slides prepared by teaching staff Kahve işleme ve demleme şemaları Coffee processing and brewing diagrams Cupping formları ve duyusal analiz tabloları Cupping forms and sensory analysis tables Reçete ve ekstraksiyon hesaplama tabloları Recipe and extraction calculation tables Video ve görsel destekli uygulama materyalleri Video and visual support application materials |
| References: | Clarke, R. J. & Macrae, R. Coffee: Chemistry Illy, A. & Viani, R. Espresso Coffee: The Science of Quality Specialty Coffee Association (SCA). Coffee Skills Program – Foundation & Brewing Materials Girginol, C. Kahve & Topraktan Fincana |
Course-Program Learning Outcome Relationship
| Learning Outcomes | 1 |
2 |
3 |
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|---|---|---|---|---|---|---|---|---|---|---|
| Program Outcomes | ||||||||||
| 1) A solid foundation in mathematics, natural sciences, and mechatronics engineering; the ability to apply both theoretical and practical knowledge in these fields to model and solve complex engineering problems. | ||||||||||
| 2) The ability to identify, define, formulate, and solve complex mechatronics engineering problems; and to select and apply appropriate analysis and modeling methods for this purpose. | ||||||||||
| 3) The ability to design complex mechatronics engineering systems, processes, devices, or products to meet specified requirements under realistic constraints and conditions; and to apply modern design methodologies for this purpose. (Realistic constraints and conditions may include economic, environmental, sustainability, manufacturability, ethical, health, safety, social, and political factors depending on the nature of the design.) | ||||||||||
| 4) The ability to develop, select, and use modern techniques and tools required for the analysis and solution of complex problems encountered in mechatronics engineering, robotics, autonomous systems, and automation applications; and the ability to effectively utilize information technologies. | ||||||||||
| 5) The ability to design and conduct experiments, collect data, analyze and interpret results for the investigation of complex problems in mechatronics engineering, robotics, autonomous systems, and automation. | ||||||||||
| 6) The ability to work effectively both individually and in disciplinary and multidisciplinary teams (particularly with mechanical, electrical-electronics, and computer engineering). | ||||||||||
| 7) The ability to communicate effectively in both Turkish and English, both orally and in writing; including effective report writing and comprehension of written reports, preparation of design and production reports, delivering effective presentations, and the ability to give and receive clear and understandable instructions. | ||||||||||
| 8) Awareness of the necessity of lifelong learning required by mechatronics engineering; the ability to access, interpret, and develop knowledge, to follow advancements in science and technology, and to continuously update oneself. | ||||||||||
| 9) The ability to act in accordance with ethical principles; awareness of professional and ethical responsibilities, and knowledge of standards used in mechatronics engineering practices. | ||||||||||
| 10) Knowledge of project management and mechatronics engineering practices such as risk management and change management; awareness of entrepreneurship, innovation, and sustainable development. | ||||||||||
| 11) Knowledge of the impacts of mechatronics engineering applications on health, environment, and safety at universal and societal levels; awareness of contemporary issues and the legal implications of engineering solutions. | ||||||||||
Course - Learning Outcome Relationship
| No Effect | 1 Lowest | 2 Low | 3 Average | 4 High | 5 Highest |
| Program Outcomes | Level of Contribution | |
| 1) | A solid foundation in mathematics, natural sciences, and mechatronics engineering; the ability to apply both theoretical and practical knowledge in these fields to model and solve complex engineering problems. | |
| 2) | The ability to identify, define, formulate, and solve complex mechatronics engineering problems; and to select and apply appropriate analysis and modeling methods for this purpose. | |
| 3) | The ability to design complex mechatronics engineering systems, processes, devices, or products to meet specified requirements under realistic constraints and conditions; and to apply modern design methodologies for this purpose. (Realistic constraints and conditions may include economic, environmental, sustainability, manufacturability, ethical, health, safety, social, and political factors depending on the nature of the design.) | |
| 4) | The ability to develop, select, and use modern techniques and tools required for the analysis and solution of complex problems encountered in mechatronics engineering, robotics, autonomous systems, and automation applications; and the ability to effectively utilize information technologies. | |
| 5) | The ability to design and conduct experiments, collect data, analyze and interpret results for the investigation of complex problems in mechatronics engineering, robotics, autonomous systems, and automation. | |
| 6) | The ability to work effectively both individually and in disciplinary and multidisciplinary teams (particularly with mechanical, electrical-electronics, and computer engineering). | |
| 7) | The ability to communicate effectively in both Turkish and English, both orally and in writing; including effective report writing and comprehension of written reports, preparation of design and production reports, delivering effective presentations, and the ability to give and receive clear and understandable instructions. | |
| 8) | Awareness of the necessity of lifelong learning required by mechatronics engineering; the ability to access, interpret, and develop knowledge, to follow advancements in science and technology, and to continuously update oneself. | |
| 9) | The ability to act in accordance with ethical principles; awareness of professional and ethical responsibilities, and knowledge of standards used in mechatronics engineering practices. | |
| 10) | Knowledge of project management and mechatronics engineering practices such as risk management and change management; awareness of entrepreneurship, innovation, and sustainable development. | |
| 11) | Knowledge of the impacts of mechatronics engineering applications on health, environment, and safety at universal and societal levels; awareness of contemporary issues and the legal implications of engineering solutions. |
Learning Activity and Teaching Methods
Assessment & Grading Methods and Criteria
Assessment & Grading
| Semester Requirements | Number of Activities | Level of Contribution |
| Midterms | 1 | % 40 |
| Final | 1 | % 60 |
| total | % 100 | |
| PERCENTAGE OF SEMESTER WORK | % 40 | |
| PERCENTAGE OF FINAL WORK | % 60 | |
| total | % 100 | |
Workload and ECTS Credit Grading
| Activities | Number of Activities | Workload |
| Course Hours | 16 | 48 |
| Midterms | 1 | 1 |
| Final | 1 | 1 |
| Total Workload | 50 | |