Welcome,
Guest
.
Login
.
Türkçe
NİNOVA
COURSES
HELP
ABOUT
Where Am I:
Ninova
/
Courses
/
Faculty of Electrical and Electronic Engineering
/
EHB 307
/
Course Informations
Return to Faculty
Home Page
Course Information
Course Weekly Lecture Plan
Course Evaluation Criteria
Course Information
Course Name
Turkish
Haberleşme I
English
Communication I
Course Code
EHB 307
Credit
Lecture
(hour/week)
Recitation
(hour/week)
Laboratory
(hour/week)
Semester
5
3
3
-
-
Course Language
Turkish
Course Coordinator
Mehmet Can
Course Objectives
1. To teach amplitude and exponential modulation types and their analysis methods.
2. To teach the modeling and effects of noise in communication systems.
3. To teach the pulse modulation techniques.
Course Description
Introduction, spectral analysis, transmission through linear systems. Amplitude modulation techniques:
Carrier amplitude (AM), double sideband (DSB), single sideband (SSB) and vestigial sideband
(VSB)/demodulation. Exponential modulation techniques: Frequency and phase (FM and PM)
modulation/demodulation. Frequency division multiplexing (FDM). Stereo transmission.
Superheterodyne receivers. Introduction to random processes, noise modeling and AWGN channel.
Noise analysis in amplitude and exponential modulation systems. Sampling, pulse amplitude, width and
position modulations (PAM, PWM, PPM). Quantization, pulse code modulation (PCM). Delta
modulation, differential PCM. Digital PAM, PWM, PPM. Time division multiplexing (TDM)
Course Outcomes
Students who pass the course will be able to:
I. Understand basic concepts and constraints in communications, analyze spectral properties of
signals.
II. Understand transmission through linear systems and describe distortions such as noise and
interference in transmission channels.
III. Understand types of amplitude (AM, DSB, SSB, VSB) modulations, analyze of amplitude
modulated signals in time and frequency domains, design of modulator/demodulator structures.
IV. Understand types of exponential modulations (FM, PM), analyze of exponential modulated signals in time and frequency domains, design of modulator/demodulator structures.
V. Understand frequency division multiplexing (FDM), stereo transmission and superheterodyne
receiver.
VI. Evaluate the performances of amplitude and exponential modulation systems under noise.
VII. Learn sampling theorem and its applications.
VIII. Have competence in the pulse modulation techniques (PAM, PWM, PPM, PCM, DM)
Pre-requisite(s)
Required Facilities
Other
Textbook
Other References
Courses
.
Help
.
About
Ninova is an ITU Office of Information Technologies Product. © 2026