| Course Name |
Industrial Embedded Systems
|
|
Code
|
Semester
|
Theory
(hour/week) |
Application/Lab
(hour/week) |
Local Credits
|
ECTS
|
|
MCE 350
|
FALL
|
2
|
2
|
3
|
6
|
| Prerequisites | MCE 202 To succeed (To get a grade of at least DD) | |||||
| Course Language | English | |||||
| Course Type | ELECTIVE_COURSE | |||||
| Course Level | First Cycle | |||||
| Mode of Delivery | Face-to-face | |||||
| Teaching Methods and Techniques of the Course |
Group Work Problem Solving Q&A Simulation Application: Experiment / Laboratory / Workshop Lecture / Presentation |
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| National Occupational Classification Code | - | |||||
| Course Coordinator |
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| Course Lecturer(s) |
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| Assistant(s) |
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| Course Objectives | The aim of this course is to teach the basic architectural features and working principles of microcontrollers involving software and hardware design, which are commonly used in the industry. It is also aimed to design, manufacture and run microcontroller-based electronic printed circuit boards containing communication, input-output, control interfaces and display with respect to given design criteria. | |||||||||||||||||||||||||||||||||||||||||||||
| Learning Outcomes |
The students who succeeded in this course;
|
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| Course Description | This course teaches designing industrial embedded systems, programming microcontrollers, utilizing input/output and communication ports. This course also covers designing and producing a printed circuit board with respect to a given design criteria for an industrial embedded system. | |||||||||||||||||||||||||||||||||||||||||||||
| Related Sustainable Development Goals |
12
|
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|
|
Core Courses |
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| Major Area Courses |
X
|
|
| Supportive Courses |
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|
| Media and Managment Skills Courses |
|
|
| Transferable Skill Courses |
|
| Week | Subjects | Required Materials | Learning Outcome |
| 1 | Introduction to Microcontrollers and Embedded Control | Noviello C., Mastering STM32, Lean Publishing, 2018. Chapter 1. | 8182b532-7d97-47ef-8947-68c0ff20f0b8 |
| 2 | STM32, Atmel, Renesas, etc. Family and Arm Cortex Architecture | Noviello C., Mastering STM32, Lean Publishing, 2018. Chapter 1. | acb0de1b-6b24-4cb3-b43d-8335d8fa1ec4 |
| 3 | STM32CubeMX Tool and Debugging | Noviello C., Mastering STM32, Lean Publishing, 2018. Chapter 3 ve 4. | acb0de1b-6b24-4cb3-b43d-8335d8fa1ec4 |
| 4 | C Language in General | Lecture Notes | acb0de1b-6b24-4cb3-b43d-8335d8fa1ec4 |
| 5 | General Purpose Input / Output (GPIO) | Noviello C., Mastering STM32, Lean Publishing, 2018. Chapter 6. | 8182b532-7d97-47ef-8947-68c0ff20f0b8 |
| 6 | Analog to Digital Conversion | Noviello C., Mastering STM32, Lean Publishing, 2018. Chapter 12. | 345b1fe2-0df0-43cb-b2b8-56a4ae374c1d |
| 7 | Digital to Analog Conversion | Noviello C., Mastering STM32, Lean Publishing, 2018. Chapter 13. | 345b1fe2-0df0-43cb-b2b8-56a4ae374c1d |
| 8 | Interrupt management and use of DMA units in embedded systems | Noviello C., Mastering STM32, Lean Publishing, 2018. Chapter 7-9-10. | d79dff81-2873-4488-8c8b-7fc6fe7e2df1 |
| 9 | Timers; Basic and General Purpose Timers | Noviello C., Mastering STM32, Lean Publishing, 2018. Chapter 11. | acb0de1b-6b24-4cb3-b43d-8335d8fa1ec4 |
| 10 | Midterm Exam | - | |
| 11 | UART-I2C-SPI Communication | Noviello C., Mastering STM32, Lean Publishing, 2018. Chapter 8-14-15. | 345b1fe2-0df0-43cb-b2b8-56a4ae374c1d |
| 12 | Printed Circuit Board Design Requirements | Lecture Notes | d79dff81-2873-4488-8c8b-7fc6fe7e2df1 |
| 13 | Printed Circuit Board Design Commands, Grounding Methods | Lecture Notes | d79dff81-2873-4488-8c8b-7fc6fe7e2df1 |
| 14 | Printed Circuit Board Production Methods | Lecture Notes | d79dff81-2873-4488-8c8b-7fc6fe7e2df1 |
| 15 | Semester Review | - | |
| 16 | Final Exam | - |
| Course Notes/Textbooks | Carmine Noviello Mastering STM32 Lean Publishing 2018 |
| Suggested Readings/Materials | Discovering the STM32 Microcontroller Geoffrey Brown Creative Commons 2016 |
| Semester Activities | Number | Weighting | LO1 | LO2 | LO3 | LO4 |
| Laboratory / Application | 1 | 20 | X | X | X | X |
| Project | 1 | 20 | X | X | X | X |
| Midterm | 1 | 20 | X | X | X | |
| Final Exam | 1 | 40 | X | X | X | X |
| Total | 4 | 100 |
| Semester Activities | Number | Duration (Hours) | Workload |
|---|---|---|---|
| Participation | - | - | - |
| Theoretical Course Hours | 16 | 2 | 32 |
| Laboratory / Application Hours | 16 | 2 | 32 |
| Study Hours Out of Class | 14 | 3 | 42 |
| Field Work | - | - | - |
| Quizzes / Studio Critiques | - | - | - |
| Portfolio | - | - | - |
| Homework / Assignments | - | - | - |
| Presentation / Jury | - | - | - |
| Project | 1 | 44 | 44 |
| Seminar / Workshop | - | - | - |
| Oral Exams | - | - | - |
| Midterms | 1 | 15 | 15 |
| Final Exam | 1 | 15 | 15 |
| Total | 180 |
| # | PC Sub | Program Competencies/Outcomes | * Contribution Level | ||||
| 1 | 2 | 3 | 4 | 5 | |||
| 1 |
Engineering Knowledge: Knowledge of mathematics, science, basic engineering, computation, and related engineering discipline-specific topics; the ability to apply this knowledge to solve complex engineering problems. |
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| 1 |
Mathematics |
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| 2 |
Science |
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| 3 |
Basic Engineering |
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| 4 |
Computation |
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| 5 |
Related engineering discipline-specific topics |
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| 6 |
The ability to apply this knowledge to solve complex engineering problems |
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| 2 |
Problem Analysis: Ability to identify, formulate and analyze complex engineering problems using basic knowledge of science, mathematics and engineering, and considering the UN Sustainable Development Goals relevant to the problem being addressed. |
LO3 | |||||
| 3 |
Engineering Design: The ability to devise creative solutions to complex engineering problems; the ability to design complex systems, processes, devices or products to meet current and future needs, considering realistic constraints and conditions. |
||||||
| 1 |
Ability to design creative solutions to complex engineering problems |
LO2 | |||||
| 2 |
Ability to design complex systems, processes, devices or products to meet current and future needs, considering realistic constraints and conditions |
LO1 | |||||
| 4 |
Use of Techniques and Tools: Ability to select and use appropriate techniques, resources, and modern engineering and computing tools, including estimation and modeling, for the analysis and solution of complex engineering problems, while recognizing their limitations. |
LO4 | |||||
| 5 |
Research and Investigation: Ability to use research methods to investigate complex engineering problems, including literature research, designing and conducting experiments, collecting data, and analyzing and interpreting results. |
||||||
| 1 |
Literature research for the study of complex engineering problems |
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| 2 |
Designing experiments |
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| 3 |
Ability to use research methods, including conducting experiments, collecting data. analyzing and interpreting results |
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| 6 |
Global Impact of Engineering Practices: Knowledge of the impacts of engineering practices on society, health and safety, economy, sustainability, and the environment, within the context of the UN Sustainable Development Goals; awareness of the legal implications of engineering solutions. |
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| 1 |
Knowledge of the impacts of engineering practices on society, health and safety, economy, sustainability, and the environment, within the context of the UN Sustainable Development Goals |
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| 2 |
Awareness of the legal implications of engineering solutions |
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| 7 |
Ethical Behavior: Acting in accordance with the principles of the engineering profession, knowledge about ethical responsibility; awareness of being impartial, without discrimination, and being inclusive of diversity. |
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| 1 |
Acting in accordance with the principles of the engineering profession, knowledge about ethical responsibility ethical responsibility |
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| 2 |
Awareness of being impartial and inclusive of diversity, without discriminating on any subject |
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| 8 |
Individual and Teamwork: Ability to work effectively, individually and as a team member or leader on interdisciplinary and multidisciplinary teams (face-to-face, remote or hybrid). |
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| 1 |
Ability to work individually and within the discipline |
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| 2 |
Ability to work effectively as a team member or leader in multidisciplinary teams (face-to-face, remote or hybrid) |
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| 9 |
Verbal and Written Communication: Taking into account the various differences of the target audience (such as education, language, profession) on technical issues. |
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| 1 |
Ability to communicate verbally |
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| 2 |
Ability to communicate effectively in writing |
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| 10 |
Project Management: Knowledge of business practices such as project management and economic feasibility analysis; awareness of entrepreneurship and innovation. |
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| 1 |
Knowledge of business practices such as project management and economic feasibility analysis |
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| 2 |
Awareness of entrepreneurship and innovation |
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| 11 |
Lifelong Learning: Lifelong learning skills that include being able to learn independently and continuously, adapting to new and developing technologies, and thinking questioningly about technological changes. |
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*1 Lowest, 2 Low, 3 Average, 4 High, 5 Highest
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