SECTION I: GENERAL INFORMATION ABOUT THE COURSE

Course Code	Course Name	Year	Semester	Theoretical	Practical	Credit	ECTS
60714MEEOZ-ELE3103	Introduction to Electrical and Electronics Engineering Laboratory	2	Fall	0	2	1	2

Course Type :	Compulsory
Cycle:	Bachelor      TQF-HE:6. Master`s Degree      QF-EHEA:First Cycle      EQF-LLL:6. Master`s Degree
Language of Instruction:	English
Prerequisities and Co-requisities:	60714MEEOZ-ELE3113 - Introduction to Electrical and Electronics Engineering
Mode of Delivery:	Face to face
Name of Coordinator:	Dr. Öğr. Üyesi ÖZLEM FEYZA ERKAN
Dersin Öğretim Eleman(lar)ı:	Dr. Öğr. Üyesi ÖZLEM FEYZA ERKAN Instructor RUMEYSA SELÇUK AKSOY
Dersin Kategorisi:	Programme Specific

SECTION II: INTRODUCTION TO THE COURSE

Course Objectives & Content

Course Objectives:

The aim of this course is to make experiments related to the theoretical issues in Introduction to Electrical and Electronics Engineering course.

Course Content:

Experiment-1: Simple Resistive circuits and Kirchhoff's Voltage Law 2: Kirchhoff's Current Law; Experiment-3: Analysis of superposition and multiplicity theorems; Experiment-4: Thévenin, Norton, maximum power theorem and circuit parameters; Experiment-5: Useage of oscilloscope; Experiment-6: Operational amplifiers and their applications; Experiment-7: Transient analysis of RL, RC and RLC Circuits; Experiment-8: Steady State Analysis of RLC Circuits; Experiment-9: Analysis of Dynamic Circuits in Frequency domain, Frequency characteristics and Bode diagrams. This course employs the project-based learning approach. In this respect aside from the conventional content the course has a project-based learning component. The project based-learning component aims realising one or more projects designed for learning purposes involving the development of certain intermediary and final deliverables in a step-by-step mannerby the students individually or in project teams. The evaluation of the project-based learning component involves grading the project deliverables and the project works by the instructor and/or a jury.

Course Learning Outcomes (CLOs)

Course Learning Outcomes (CLOs) are those describing the knowledge, skills and competencies that students are expected to achieve upon successful completion of the course. In this context, Course Learning Outcomes defined for this course unit are as follows:

Knowledge (Described as Theoritical and/or Factual Knowledge.)

1) Students compare and interpret theoretical analyzes, computer simulations and experimental results.

Skills (Describe as Cognitive and/or Practical Skills.)

1) Students will be able to prepare pre-experiment, experiment and prepare an experimental report.

2) Students make the experimental proofs of laws and theorems in related courses.

3) Students set up the electrical circuit.

4) Students measure electrical signals.

Competences (Described as "Ability of the learner to apply knowledge and skills autonomously with responsibility", "Learning to learn"," Communication and social" and "Field specific" competences.)

Weekly Course Schedule

Week	Subject	Materials Sharing *
		Related Preparation	Further Study
1)	Laboratory Meeting	Reading assignment, Preparatory study	Project work, Homework assignment
2)	Simple resistive circuits and Kirchhoff's Voltage Law	Reading assignment, Preparatory study	Project work, Homework assignment
3)	Kirchhoff's Current Law	Reading assignment, Preparatory study	Project work, Homework assignment
4)	Analysis of superposition and multiplication theorems	Reading assignment, Preparatory study	Project work, Homework assignment
5)	Thévenin, Norton, maximum power theorem and circuit parameters	Reading assignment, Preparatory study	Project work, Homework assignment
6)	Usage of osiloscope	Reading assignment, Preparatory study	Project work, Homework assignment
7)	Usage of osiloscope	Reading assignment, Preparatory study	Project work, Homework assignment
8)	Midterm	Preparatory study
9)	Operational amplifier and applications	Reading assignment, Preparatory study	Project work, Homework assignment
10)	Analysis of transient response of RL, RC and RLC circuits	Reading assignment, Preparatory study	Project work, Homework assignment
11)	Analysis of transient response of RL, RC and RLC circuits	Reading assignment, Preparatory study	Project work, Homework assignment
12)	Steady-State Analysis of RLC circuits	Reading assignment, Preparatory study	Project work, Homework assignment
13)	Analysis of dynamic circuits in frequency domain, frequency characteristics and Bode diagrams	Course notes will be given at the beginning of each lesson; course notes will be shared on the course web page.
14)	Makeup Experiment	Preparatory study
15)	Submission of the final delivery of the project and presentation	Preparatory study

*These fields provides students with course materials for their pre- and further study before and after the course delivered.

Recommended or Required Reading & Other Learning Resources/Tools

Course Notes / Textbooks:	Circuit Laboratory Test Booklet R. C. Dorf, and J. A. Svoboda, Introduction to Electric Circuits, John Wiley, 9e, 2014.
References:	D. Irwin and R. M. Nelms, Basic Engineering Circuit Analysis, John Wiley, 11e, 2015.

SECTION III: RELATIONSHIP BETWEEN COURSE UNIT AND COURSE LEARNING OUTCOMES (CLOs)

(The matrix below shows how the course learning outcomes (CLOs) associates with programme learning outcomes (both KPLOs & SPLOs) and, if exist, the level of quantitative contribution to them.)

Relationship Between CLOs & PLOs

(KPLOs and SPLOs are the abbreviations for Key & Sub- Programme Learning Outcomes, respectively. )

CLOs/PLOs	KPLO 1	KPLO 2				KPLO 3										KPLO 4				KPLO 5
	1	1	2	3	4	1	2	3	4	5	6	7	8	9	10	1	2	3	4	1	2	3	4	5	6	7	8	9	10	11	12
CLO1
CLO2
CLO3
CLO4
CLO5

Level of Contribution of the Course to PLOs

No Effect	1 Lowest	2 Low	3 Average	4 High	5 Highest

	Programme Learning Outcomes	Contribution Level (from 1 to 5)
1)	Uses and applies theoretical and applied sciences in the field of basic science subjects for the solution of computer engineering problems.	4
	1.1 Has sufficient knowledge in mathematics, science, computer science and computer engineering; use theoretical and applied knowledge in these fields together to solve computer engineering problems	4
2)	Analyzes computer engineering applications, designs and develops models to meet specific requirements under realistic constraints and conditions. For this purpose, selects and uses appropriate methods, tools and technologies.	4
	2.1 Identify, define, formulate and solve complex computer engineering problems; for this purpose select and apply appropriate analytical and modeling methods	4
	2.2 Designs a complex computer and software based system, process, device or product to meet certain requirements under realistic constraints and conditions, including economics, environmental issues, sustainability, manufacturability, ethics, health, safety, social and political issues; For this purpose, it applies modern design methods.	3
	2.3 Selects and effectively uses modern techniques and tools and information technologies required for computer science and computer engineering applications.	3
	2.4 Designs and conducts experiments, collects data, analyzes and interprets the results for the study of computer science and computer engineering problems and research topics.	4
3)	Owns the competencies required by the constantly developing field of computer engineering and the global competitive environment.	4
	3.1 Works effectively individually and in multi-disciplinary teams, takes responsibility.	4
	3.2 Accesses the information and for this purpose searches for resources, uses databases and other information resources.	3
	3.3 Awares of the necessity of lifelong learning, follows developments in science and technology and renews itself continuously.
	3.4 Communicates effectively in Turkish, both orally and in writing, has at least one foreign language knowledge at the level of European Language Portfolio B1.	2
	3.5 Manage projects, has conscious of workplace practices, employee health, environmental and work safety; aware of the legal consequences of engineering applications.
	3.6 Has awareness of the universal and social effects of engineering solutions and applications; has awareness of entrepreneurship and innovativeness and knowledgeable about contemporary issues.
	3.7 Has professional and ethical responsibility.
	3.8 Has information about the standards used in computer engineering applications.	1
	3.9 Has quality consciousness.
	3.10 Has the capacity to work in at least one of the important application areas of computer science and computer engineering.
4)	Applies the theoretical knowledge in business life during a semester.
	4.1 Experiences all processes in business life.
	4.2 Takes part in activities related to the field of education in a business operating in the field.
	4.3 Questions the application with theoretical knowledge.
	4.4 Compiles the knowledge and experience gained in the field.
5)	S/he acquires the competencies that develop by the expectations of business world and the society defined as the institutional outcomes of our university on the advanced level in relation with his/her field.
	5.1 Acquires the analyzing solving the problems and managing the conflicts.
	5.2 Participates as a team member and takes responsibility in the environments that require the solving of the conflicts and acts as a leader when necessary.
	5.3 Has awareness for ethical and social responsivity.
	5.4 By supporting the learnt courses with quantitative and qualitative data; and by using verbal and visual communication means, s/he transfers them to the groups within and outside his/her group in a systematical and effective way.
	5.5 Evaluates the norms and standards present in the works in which s/he takes responsibility in a critical point of view.
	5.6 Develops strategical, innovative and entrepreneurial ideas.
	5.7 Acquires competence of managing the change.
	5.8 Shows development personally and socially with and awareness for lifelong learning.
	5.9 Follows advanced technologies and developments about digital transformation.
	5.10 Has cultural awareness and s/he transfers this to the groups within and outside his/her field.
	5.11 Has awareness about citizenship competency.
	5.12 Acquires communication in a Foreign Language (English) competence defined on the level of at least B1 in European Language Portfolio. (In programs whose medium of instruction is English, on the level of B2/B2+).

SECTION IV: TEACHING-LEARNING & ASSESMENT-EVALUATION METHODS OF THE COURSE

Teaching & Learning Methods of the Course

(All teaching and learning methods used at the university are managed systematically. Upon proposals of the programme units, they are assessed by the relevant academic boards and, if found appropriate, they are included among the university list. Programmes, then, choose the appropriate methods in line with their programme design from this list. Likewise, appropriate methods to be used for the course units can be chosen among those defined for the programme.)

Teaching and Learning Methods defined at the Programme Level	Teaching and Learning Methods Defined for the Course
Lectures
Discussion
Case Study
Problem Solving
Demonstration
Views
Laboratory
Reading
Homework
Project Preparation
Thesis Preparation
Peer Education
Seminar
Technical Visit
Course Conference
Brain Storming
Questions Answers
Individual and Group Work
Role Playing-Animation-Improvisation
Active Participation in Class

Assessment & Evaluation Methods of the Course

(All assessment and evaluation methods used at the university are managed systematically. Upon proposals of the programme units, they are assessed by the relevant academic boards and, if found appropriate, they are included among the university list. Programmes, then, choose the appropriate methods in line with their programme design from this list. Likewise, appropriate methods to be used for the course units can be chosen among those defined for the programme.)

Aassessment and evaluation Methods defined at the Programme Level	Assessment and Evaluation Methods defined for the Course
Midterm
Presentation
Final Exam
Quiz
Report Evaluation
Homework Evaluation
Oral Exam
Thesis Defense
Jury Evaluation
Practice Exam
Evaluation of Implementation Training in the Workplace
Active Participation in Class
Participation in Discussions

Relationship Between CLOs & Teaching-Learning, Assesment-Evaluation Methods of the Course

(The matrix below shows the teaching-learning and assessment-evaluation methods designated for the course unit in relation to the course learning outcomes.)

Contribution of Assesment & Evalution Activities to Final Grade of the Course

Measurement and Evaluation Methods	# of practice per semester	Level of Contribution
Laboratory	4	% 16.00
Quizzes	4	% 16.00
Project	2	% 10.00
Midterms	1	% 8.00
Semester Final Exam	1	% 50.00
Total		% 100
PERCENTAGE OF SEMESTER WORK		% 50
PERCENTAGE OF FINAL WORK		% 50
Total		% 100

SECTION V: WORKLOAD & ECTS CREDITS ALLOCATED FOR THE COURSE

WORKLOAD OF TEACHING & LEARNING ACTIVITIES
Teaching & Learning Activities	# of Activities per semester	Duration (hour)	Total Workload
Course	0	0	0
Laboratory	9	2	18
Application	10	2	20
Special Course Internship (Work Placement)	0	0	0
Field Work	0	0	0
Study Hours Out of Class	10	1	10
Presentations / Seminar	0	0	0
Project	0	0	0
Homework Assignments	0	0	0
Total Workload of Teaching & Learning Activities	-	-	48
WORKLOAD OF ASSESMENT & EVALUATION ACTIVITIES
Assesment & Evaluation Activities	# of Activities per semester	Duration (hour)	Total Workload
Quizzes	0	0	0
Midterms	0	0	0
Semester Final Exam	0	0	0
Total Workload of Assesment & Evaluation Activities	-	-	0
TOTAL WORKLOAD (Teaching & Learning + Assesment & Evaluation Activities)			48
ECTS CREDITS OF THE COURSE (Total Workload/25.5 h)			2