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• Information on Degree Programmes COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
Signals and Systems EEE   314 6 4 4 5

 Prerequisites and co-requisites Recommended Optional Programme Components None

Language of Instruction English Course Level First Cycle Programmes (Bachelor's Degree)
Course Type
Course Coordinator
Instructors
 Doç. Dr. SAMİ ARICA 1. Öğretim Grup:A Doç. Dr. SAMİ ARICA 2. Öğretim Grup:A

Assistants
Goals
Signals and systems are two basic components of engineering.This course provides analysis and description methods of continuous-time (analog) signals and systems.
Content
Introduction: Definition of signals and systems. Transformation of independent variable. Properties of signals and systems. Linear, time-invariant systems. Convolution. Properties of linear, time-invariant (LTI) systems. Systems represented by differential equations. State-space analysis of LTI-causal systems described by differential equations. Fourier series. Fourier transform. Properties of Fourier series and Fourier transform. Filtering. Continuous-time modulation. Demonstration of amplitude modulation. The Laplace transform. Analysis of systems by using Fourier and Laplace transform. Continuous-time second-order systems. Butterworth filters. Feedback. Sampling. Interpolation.

Learning Outcomes
1) Understand signals and systems and classify according to their properties.
2) Understand and analyses linear systems.
3) Analyses signals and systems in the frequency domain by using Fourier transform.
4) Analyses signals and systems by using Laplace transform.
5) Understand filters.
6) Understand feedback systems.

Course's Contribution To Program
NoProgram Learning OutcomesContribution
12345
1
Has capability in those fields of mathematics and physics that form the foundations of engineering.
2
Grasps the main knowledge in the basic topics of electrical and electronic engineering.
3
Comprehends the functional integrity of the knowledge gathered in the fields of basic engineering and electrical-electronics engineering.
X
4
Identifies problems and analyzes the identified problems based on the gathered professional knowledge.
5
Formulates and solves a given theoretical problem using the knowledge of basic engineering.
X
6
Has aptitude for computer and information technologies
7
Knows English at a level adequate to comprehend the main points of a scientific text, either general or about his profession, written in English.
X
8
Has the ability to apply the knowledge of electrical-electronic engineering to profession-specific tools and devices.
9
Has the ability to write a computer code towards a specific purpose using a familiar programming language.
10
Has the ability to work either through a purpose oriented program or in union within a group where responsibilities are shared.
X
11
Has the aptitude to identify proper sources of information, reaches them and uses them efficiently.
X
12
Becomes able to communicate with other people with a proper style and uses an appropriate language.
13
Internalizes the ethical values prescribed by his profession in particular and by the professional life in general.
14
Has consciousness about the scientific, social, historical, economical and political facts of the society, world and age lived in.

Course Content
WeekTopicsStudy Materials _ocw_rs_drs_yontem
1 Introduction: Definition of signals and systems. Transformation of independent variable. Properties of signals and systems. Textbook reading/Problem solving. Lecture
2 Linear, time-invariant systems. Convolution Integral. Textbook reading/Problem solving. Lecture
3 Properties of linear, time-invariant (LTI) systems. Systems represented by differential equations. Textbook reading/Problem solving. Lecture
4 State-space analysis of LTI-causal systems described by differential equations. Textbook reading/Problem solving. Lecture
5 Fourier series. Textbook reading/Problem solving. Lecture
6 Fourier transform. Fourier transform properties Textbook reading/Problem solving. Lecture
7 Filtering. Textbook reading/Problem solving. Lecture
8 Midterm Exam I. Textbook reading/Problem solving. Testing
9 Continuous-time modulation. Demonstration of amplitude modulation. Textbook reading/Problem solving. Lecture
10 The Laplace transform Laplace transform properties Textbook reading/Problem solving. Lecture
11 Analysis of systems by using Fourier and Laplace transform. Textbook reading/Problem solving. Lecture
12 Midterm Exam II. Continuous-time second-order systems. Textbook reading/Problem solving. Lecture
Testing
13 Butterworth filters. Textbook reading/Problem solving. Lecture
14 Feedback systems. Textbook reading/Problem solving. Lecture
15 Sampling. Interpolation. Textbook reading/Problem solving. Lecture
16-17 Final Exam. Textbook reading/Problem solving. Testing  