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BASIC ELECTRONICKS II PROGRAMME COURSE DESCRIPTION

Code Name of the Course Unit Semester In-Class Hours (T+P) Credit ECTS Credit
HEE106 BASIC ELECTRONICKS II 2 3 3 4

GENERAL INFORMATION

Language of Instruction : Turkish
Level of the Course Unit : BACHELOR'S DEGREE, TYY: + 6.Level, EQF-LLL: 6.Level, QF-EHEA: First Cycle
Type of the Course : Compulsory
Mode of Delivery of the Course Unit -
Coordinator of the Course Unit Assist.Prof. BEDİA MERİH ÖZÇETİN
Instructor(s) of the Course Unit
Course Prerequisite No

OBJECTIVES AND CONTENTS

Objectives of the Course Unit: In this course, it is aimed to introduce the production and working properties and electrical properties of various semiconductor electronic devices and to provide them with skills to analyze and simulate the basic electronic circuits in which these elements are used.
Contents of the Course Unit: Basic electronics is one of the core courses of the program. He will use the materials he knows here in other vocational courses. A good understanding of the subjects is proportional to success in mathematics and direct current circuit analysis courses.

KEY LEARNING OUTCOMES OF THE COURSE UNIT (On successful completion of this course unit, students/learners will or will be able to)

LEARNING OUTCOMES OF THE COURSE (Students show the following knowledge, skills and/or competencies when they successfully complete this course.) Defines the applications of electronics in industry. (1)-Information Interprets electronic circuit elements and devices and their functions in electronic circuit. (2)-Grip Uses basic electronic circuit analysis methods. (3)-Application Uses electronic circuit simulation software with tools and devices in electronics laboratory (3)-Application Analyzes basic electronic circuits.(4)-Analysis

WEEKLY COURSE CONTENTS AND STUDY MATERIALS FOR PRELIMINARY & FURTHER STUDY

Week Preparatory Topics(Subjects) Method
1 Transistors Transistor symbols; Component definition and orientation; Transistor characteristics and properties; -
2 Transistors Transistor symbols; Component definition and orientation; Transistor characteristics and properties; -
3 Transistors Transistor symbols; Component definition and orientation; Transistor characteristics and properties; -
4 Transistors Structure and operation of PNP and NPN transistors; Base, collector and emitter configurations; Testing transistors; Basic understanding of other transistor types and their uses; Application of transistors: Amplifier classes (A, B, C); Simple circuits including bias, decoupling, feedback and stabilization; Multistage/multistage circuit principles; cascades/ cascades, push-pull/push-pull, oscillators, multivibrators, flip-flops/bistable circuits -
5 Transistors Structure and operation of PNP and NPN transistors; Base, collector and emitter configurations; Testing transistors; Basic understanding of other transistor types and their uses; Application of transistors: Amplifier classes (A, B, C); Simple circuits including bias, decoupling, feedback and stabilization; Multistage/multistage circuit principles; cascades/ cascades, push-pull/push-pull, oscillators, multivibrators, flip-flops/bistable circuits -
6 Transistors Structure and operation of PNP and NPN transistors; Base, collector and emitter configurations; Testing transistors; Basic understanding of other transistor types and their uses; Application of transistors: Amplifier classes (A, B, C); Simple circuits including bias, decoupling, feedback and stabilization; Multistage/multistage circuit principles; cascades/ cascades, push-pull/push-pull, oscillators, multivibrators, flip-flops/bistable circuits -
7 Transistors Structure and operation of PNP and NPN transistors; Base, collector and emitter configurations; Testing transistors; Basic understanding of other transistor types and their uses; Application of transistors: Amplifier classes (A, B, C); Simple circuits including bias, decoupling, feedback and stabilization; Multistage/multistage circuit principles; cascades/ cascades, push-pull/push-pull, oscillators, multivibrators, flip-flops/bistable circuits -
8 - MID-TERM EXAM -
9 Transistors Structure and operation of PNP and NPN transistors; Base, collector and emitter configurations; Testing transistors; Basic understanding of other transistor types and their uses; Application of transistors: Amplifier classes (A, B, C); Simple circuits including bias, decoupling, feedback and stabilization; Multistage/multistage circuit principles; cascades/ cascades, push-pull/push-pull, oscillators, multivibrators, flip-flops/bistable circuits -
10 Transistors Structure and operation of PNP and NPN transistors; Base, collector and emitter configurations; Testing transistors; Basic understanding of other transistor types and their uses; Application of transistors: Amplifier classes (A, B, C); Simple circuits including bias, decoupling, feedback and stabilization; Multistage/multistage circuit principles; cascades/ cascades, push-pull/push-pull, oscillators, multivibrators, flip-flops/bistable circuits -
11 Transistors Structure and operation of PNP and NPN transistors; Base, collector and emitter configurations; Testing transistors; Basic understanding of other transistor types and their uses; Application of transistors: Amplifier classes (A, B, C); Simple circuits including bias, decoupling, feedback and stabilization; Multistage/multistage circuit principles; cascades/ cascades, push-pull/push-pull, oscillators, multivibrators, flip-flops/bistable circuits -
12 Transistors Integrated Circuits Structure and operation of PNP and NPN transistors; Base, collector and emitter configurations; Testing transistors; Basic understanding of other transistor types and their uses; Application of transistors: Amplifier classes (A, B, C); Simple circuits including bias, decoupling, feedback and stabilization; Multistage/multistage circuit principles; cascades/ cascades, push-pull/push-pull, oscillators, multivibrators, flip-flops/bistable circuits Description and operation of logic circuits and linear circuits/operational amplifiers; Introduction to operation and function of operational amplifier used as integrator, differential, voltage follower, comparator; Working and amplifying stages connection methods: resistive, capacitive, inductive (transformer), inductive resistive (IR), direct; Advantages and disadvantages of plus and minus feedback -
13 Integrated Circuits Description and operation of logic circuits and linear circuits/operational amplifiers; Introduction to operation and function of operational amplifier used as integrator, differential, voltage follower, comparator; Working and amplifying stages connection methods: resistive, capacitive, inductive (transformer), inductive resistive (IR), direct; Advantages and disadvantages of plus and minus feedback -
14 Integrated Circuits Description and operation of logic circuits and linear circuits/operational amplifiers; Introduction to operation and function of operational amplifier used as integrator, differential, voltage follower, comparator; Working and amplifying stages connection methods: resistive, capacitive, inductive (transformer), inductive resistive (IR), direct; Advantages and disadvantages of plus and minus feedback -
15 - FINAL EXAM -
16 - FINAL EXAM -
17 - FINAL EXAM -

SOURCE MATERIALS & RECOMMENDED READING

ASSESSMENT

Assessment & Grading of In-Term Activities Number of Activities Degree of Contribution (%) Description
Level of Contribution
0 1 2 3 4 5

CONTRIBUTION OF THE COURSE UNIT TO THE PROGRAMME LEARNING OUTCOMES

KNOWLEDGE

Theoretical

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Applies the knowledge and skills related to the field by considering the legal dimension of occupational health and safety.
3
2
Can make applications related to aviation electricity.
4
3
Can make applications related to aviation electronics.
4
4
Learns the aviation applications of Electrical-Electronics subjects.
5
5
Relates the concepts of entrepreneurship and innovation to the field.
4

KNOWLEDGE

Factual

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Uses theoretical and applied knowledge about the field in business life by choosing appropriate analytical methods and modeling techniques.
4
2
Adapts to the environment in which works as a team member.(dişil)
3
3
Develops a suitable solution method when faced with a problem
4
4
Prepares written agreements with relevant institutions in accordance with the legislation.
3
5
As a team member, manages all stages from planning to implementation of aviation activities
5

SKILLS

Cognitive

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Since has technical dexterity in a negative situation in her field, she can take the necessary precautions and intervene in the situation.(dişil)
5
2
Makes the problem encountered in a study in the field appropriate within the team.
5

SKILLS

Practical

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Uses computer software, information and communication technologies at the level required by the field (use) Bloom 3
5
2
A sketch, diagram, graph, etc., describing the subject. reading and interpreting documents (interprent). (Bloom 2)
4

OCCUPATIONAL

Autonomy & Responsibility

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Since will graduate with a certificate from the recognized school, she has the necessary knowledge and dexterity in the fields of aviation electricity and electronics.
2
2
Develops solutions for unforeseen problems encountered in practice. (develop) (Bloom 6)
3

OCCUPATIONAL

Learning to Learn

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Determines the learning requirements related to the field (determine) (Bloom 3)
1
2
Uses lifelong learning principles in professional development (Bloom 3)
4

OCCUPATIONAL

Communication & Social

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Apply technical drawing knowledge effectively in business life (Bloom 3)
3
2
By informing the relevant people and institutions on the issues related to the field; states his thoughts and suggestions for solutions to problems in written and verbal form (state) (Bloom 1)
3
3
Discusses with experts (debate) by supporting their thoughts and solutions to problems with quantitative and qualitative data (Bloom 2)
4
4
Participates in training at international level (participate) (Bloom 3)
5
5
Organizes activities for the professional development of employees under his/her responsibility. (organized) (Bloom 6)
4

OCCUPATIONAL

Occupational and/or Vocational

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Graduates with a school certificate recognized by SHGM and the need for qualified electrical-electronic personnel in the aviation sector is met.
5
2
He uses the knowledge and skills he gained during his undergraduate education in business life. (Bloom 3)
4
3
Solves the problems encountered in the field. (solve) (Bloom 3)
5
4
Applies the necessary behavior culture on quality management and processes, environmental protection and occupational safety to the team (apply) (Bloom 3)
4
5
He places the safety factor awareness in himself and his team. (locate) Bloom 1)
4

WORKLOAD & ECTS CREDITS OF THE COURSE UNIT

Workload for Learning & Teaching Activities

Type of the Learning Activites Learning Activities (# of week) Duration (hours, h) Workload (h)
Lecture & In-Class Activities 14 3 42
Preliminary & Further Study 8 3 24
Land Surveying 0 0 0
Group Work 0 0 0
Laboratory 0 0 0
Reading 0 0 0
Assignment (Homework) 8 3 24
Project Work 0 0 0
Seminar 0 0 0
Internship 0 0 0
Technical Visit 0 0 0
Web Based Learning 0 0 0
Implementation/Application/Practice 0 0 0
Practice at a workplace 0 0 0
Occupational Activity 0 0 0
Social Activity 0 0 0
Thesis Work 0 0 0
Field Study 0 0 0
Report Writing 0 0 0
Final Exam 1 1 1
Preparation for the Final Exam 2 3 6
Mid-Term Exam 1 1 1
Preparation for the Mid-Term Exam 2 3 6
Short Exam 0 0 0
Preparation for the Short Exam 0 0 0
TOTAL 36 0 104
Total Workload of the Course Unit 104
Workload (h) / 25.5 4,1
ECTS Credits allocated for the Course Unit 4,0