Course Code	Semester	Course Name	LE/RC/LA	Course Type	Language of Instruction	ECTS
TET4002	4	DIGITAL DESIGN	2/1/0	CC	TURKISH	3

Course Goals
Prerequisite(s)	Course Code Course Name…
Corequisite(s)	Course Code Course Name…
Special Requisite(s)	The minimum qualifications that are expected from the students who want to attend the course.(Examples: Foreign language level, attendance, known theoretical pre-qualifications, etc.)
Instructor(s)	LecturerFaruk KARA
Course Assistant(s)
Schedule	Wednesday 13.00-16:00 cats meeting platform
Office Hour(s)	Cats meeting platform after the class
Teaching Methods and Techniques	-Microprocessor systems, hardware and software structure of the organization and architecture, programming techniques, programs, stresses the understanding of fault finding and programming languages. Internal structure of the microprocessor, instruction set, microprocessor timing diagrams, machine threads and command cycles, the memory address or input / output port address resolution, the main memory system and input / output unit interfaces with a basic microprocessor design, microprocessor hardware peripherals, and programming interfaces, based on microprocessor based system applications
Principle Sources	-Course material and hand out lab sheets
Other Sources	-

Course Schedules
Week	Contents	Learning Methods
1. Week	Introduction to high level microprocessor	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
2. Week	Introduction to high level microprocessor	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
3. Week	Microprocessor-Based System Structure and Operation	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
4. Week	Microprocessor-Based System Structure and Operation	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
5. Week	Microprocessor Architecture	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
6. Week	Microprocessor Architecture	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
7. Week	Main Memory System Design	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
8. Week	Main Memory System Design	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
9. Week	Microprocessor Software	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
10. Week	Microprocessor Software	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
11. Week	Microprocessor Programming Techniques	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
12. Week	Microprocessor Programming Techniques	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
13. Week	Microprocessor Programming Techniques	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
14. Week	Microprocessor Programming Techniques	Presentation, question-answer, discussion, problem solving, observation trips, laboratory (experimental), with case study methods, brainstorming, demonstration, bilateral and group work, One or more computer-based instructional techniques will be used
15. Week
16. Week
17. Week

Assessments
Evaluation tools	Quantity	Weight(%)

Program Outcomes PO-1 Installation of electrical and electronic systems PO-2 Taking baseline measurements PO-3 Setting up digital circuits PO-4 Setting up analog circuits PO-5 Ability to set up microprocessor circuits and program PO-6 Installation of electric motors and experiments PO-7 Setting up systems of control circuits PO-8 Gaining professional experience and manual dexterity PO-9 Gaining practical circuit installation experience

Learning Outcomes

Course Assessment Matrix:

	PO 1	PO 2	PO 3	PO 4	PO 5	PO 6	PO 7	PO 8	PO 9