| Course Unit Title | Course Unit Code | Type of Course Unit | Level of Course Unit | Year of Study | Semester | ECTS Credits |
|---|---|---|---|---|---|---|
| Digital Electronics | OMP111 | Compulsory | Associate degree | 1 | Fall | 5 |
Name of Lecturer(s)
Associate Prof. Dr. İsmet KANDİLLİ
Associate Prof. Dr. Adnan SONDAŞ
Assistant Prof. Dr. Özgür YAKIŞAN
Lecturer Seyfullah BAŞKÖYLÜ
Lecturer Hakan KIRCI
Lecturer Ferhat SERTKAYA
Lecturer Remzi SÜERKAN
Lecturer Rasıh TOPUZ
Lecturer Kader YETİM
Lecturer Gülten YILMAZ
Learning Outcomes of the Course Unit
1) Describe The basic concepts of digital systems, number systems used in digital systems and their conversion.
2) Describe the code used in digital systems and the basic logic elements.
3) Perform a logic function by using the basic rules of Boolean algebra for simplifying it.
4) Describe the derivative logic elements and their gates.
5) Describe to perform logic functions by one type of gate and using Karnaugh map method for simplifying them.
6) Perform the logic functions by using a uniqe type of integrated circuit.
7) Perform the functional logic circuits .
Program Competencies-Learning Outcomes Relation
| Program Competencies | ||||||||||||||||||
| 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 | ||
| Learning Outcomes | ||||||||||||||||||
| 1 | High | High | No relation | No relation | High | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 2 | High | High | No relation | No relation | High | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 3 | High | High | No relation | No relation | High | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 4 | High | High | No relation | No relation | High | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 5 | High | High | No relation | No relation | High | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 6 | High | High | No relation | No relation | High | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
| 7 | High | High | No relation | No relation | High | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | No relation | |
Mode of Delivery
Face to Face
Prerequisites and Co-Requisites
None
Recommended Optional Programme Components
Mathematics I, Mathematics II.
Course Contents
Number systems, of the code used in digital systems, basic logicel ements and gates, The use of Boolean algebra and basic, derivative logic elements and gates, to performed the logic functions by using one type of gate, Karnaugh maps and function simplification method, Analysis and applications of functional Logic circuits (adders, subtractors, comparators, encoders, decoders, code converters, Mux., demux. etc.).
Weekly Schedule
1) Concepts of digital systems and analogue systems. Number systems and transformations used in digital systems2) Codes used in digital systems and transformations.
3) Basic logic elements and basic logic gates.
4) The basic rules of Boolean algebra.
5) The identification and realization of a logic function using the basic logic elements.
6) The basic rules of Boolean algebra and logic simplification of a function.
7) Derivative logic elements and their logic gates.
8) Midterm examination/Assessment
9) Realization logic functions with monotype logic gates (NAND or NOR).
10) Karnough map method of simplification and the use of logic functions.
11) Adaptation the number of logic gate inputs.
12) Functional logic circuits (addition, subtraction, comparison, coding, decoding, code conversion, multiple-selection MUX. Demux and distribute information.) design and applications.
13) Functional logic circuits (addition, subtraction, comparison, coding, decoding, code conversion, multiple-selection MUX. Demux and distribute information.) design and applications.
14) Functional logic circuits (addition, subtraction, comparison, coding, decoding, code conversion, multiple-selection MUX. Demux and distribute information.) design and applications.
15) Functional logic circuits (addition, subtraction, comparison, coding, decoding, code conversion, multiple-selection MUX. Demux and distribute information.) design and applications.
16) Final examination
Recommended or Required Reading
Planned Learning Activities and Teaching Methods
1) Lecture
2) Question-Answer
3) Group Study
4) Lab / Workshop
5) Project Based Learning
Assessment Methods and Criteria
Contribution of Semester Studies to Course Grade |
40% |
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Contribution of Final Examination to Course Grade |
60% |
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Total | 100% | |||||||||||
Language of Instruction
Turkish
Work Placement(s)
Not Required