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Course Title: |
SIGNALS AND SYSTEMS I |
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Course Code: |
EEM2401 |
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Type of Course: |
Compulsory |
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Level of Course: |
First Cycle |
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Year of Study: |
2 |
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Semester: |
3 |
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ECTS Credits Allocated: |
4 |
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Theoretical (hour/week): |
3 |
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Practice (hour/week) : |
0 |
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Laboratory (hour/week) : |
0 |
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Prerequisites: |
None |
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Recommended optional programme components: |
None |
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Language: |
Turkish |
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Mode of Delivery: |
Face to face |
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Course Coordinator: |
Prof. Dr. ERDOĞAN DİLAVEROĞLU |
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Course Lecturers: |
Prof. Dr. Erdoğan Dilaveroğlu
Doç. Dr. Ersen Yılmaz |
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Contactinformation of the Course Coordinator: |
Prof. Dr. Erdoğan Dilaveroğlu
E-mail: dilaver@uludag.edu.tr
Tel: (224) 294 2012
Elektrik-Elektronik Müh. Böl., 3. Kat, 324. |
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Website: |
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Objective of the Course: |
Giving to the students the fundamentals of the signals and systems area of electrical engineering. Also, preparing the students to some higher level courses in such areas of signal processing, circuits, communication and control. |
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Contribution of the Course to Professional Development |
To be able to follow innovations and apply them in the field by using the competence of collecting information, researching and analyzing them. |
| Week |
Theoretical |
Practical |
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Presentation and organization of the course. Mathematical review: Complex numbers. |
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Mathematical review (continued): Polar representation of complex numbers and the triangle inequality. De Moivre's Theorem and roots. The complex exponential, Euler's formula. |
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Continuous Time Signals and Systems
a. continuous time signals
b. continuous time complex exponential and sinusoidal signals
c. delta and step functions |
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Continuous Time Signals and Systems
d. continuous time systems
e. basic system features |
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Linear and Time-Invariant (LTI) Systems
a. LTI continuous time systems, convolution integral
b. Features of LTI systems |
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Linear and Time-Invariant (LTI) Systems
c.systems explained by differential equations
d. singular functions |
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Fourier Series Representation of Continuous Time Periodic Signals
a. Fourier series representation of continuous time periodic signals
b. Properties of continuous time Fourier series |
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Fourier Series Representation of Continuous Time Periodic Signals
c. Fourier series and LTI systems
d. filtering |
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Continuous Time Fourier Transform
a. Derivation of continuous time Fourier transform
b. Properties of the continuous time Fourier transform |
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Continuous Time Fourier Transform
c. convolution and multiplication properties
d. systems defined by a linear constant coefficient differential equation |
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Time and Frequency Definitions of Continuous Time Signals and Systems
a. Amplitude and phase representations of the frequency response of LTI continuous time systems
b. Time and frequency domain properties of frequency selective continuous time filters |
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Time and Frequency Definitons of Continuous Time Signals and Systems
c. first and second order continuous time systems |
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Laplace Transform
a. Definition of Laplace transform, region of convergence, inverse Laplace transform
b. Properties of the Laplace transform
c. Analysis of LTI systems with Laplace transform |
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Laplace Transform
d. Representation of systems with block diagram
to. Unilateral Laplace transform |
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