CATALOG DATA
Review of Fourier theory, linear system theory, probability and random processes. Modulation and detection. Noise in modulation systems. Introduction to digital data transmission.
TEXTBOOK
Lathi, B.P., Modern Digital and Analog Communication Systems, Third Edition, Oxford University Press, 1998. ISDN: 0-19-511009-9
COORDINATOR
Eugene E. McGaugh, Associate Professor of Electrical Engineering
COURSE OBJECTIVES
-
to familiarize students with the fundamentals of analog and digital communication systems
-
to provide students with tools for communication signal analysis
-
to familiarize students with various techniques for amplitude modulation and demodulation of analog signals
-
to develop the students’ ability to determine the effects of receiver frequency and phase errors in synchronous modulation systems
-
to familiarize students with techniques for generating and demodulating narrow-band and wide-band frequency and phase modulated signals
-
to familiarize students with basic techniques for generating and demodulating pulse code modulated signals
-
to familiarize students with issues pertaining to the transmission of digital signals over bandwidth-limited communication channels
PREREQUISITE BY TOPIC
Signals and Systems II
TOPICS
-
Introduction to Signals (3 classes)
-
Analysis and Transmission of Signals (5 classes)
-
Amplitude Modulation (5 classes)
-
Angle Modulation (4 classes)
-
Sampling and Pulse Code Modulation (4 classes)
-
Digital Data Transmission (4 classes)
-
Tests (3 classes)
COURSE OUTCOMES
Upon completion of this course, students should be able to do the following:
-
apply Fourier analysis to communication signals
-
explain how channel imperfections distort signals
-
derive the energy or power spectral density of signals
-
sketch the spectrum of amplitude modulated signals, given the baseband spectrum
-
design simple systems for generating and demodulating amplitude modulated signals
-
explain the difference between narrow-band and wide-band angle modulation
-
design basic systems for the indirect and direct generation of FM signals
-
explain how a simple differentiator FM demodulator operates
-
explain how phase-locked loops are used for FM demodulation
-
determine the Nyquist sampling rate of a given signal
-
explain aliasing
-
determine the number of levels in a quantizer given signal-to-noise ratio and maximum input voltage
-
describe the different types of line codes
-
describe the use of controlled intersymbol interference to achieve maximum data rates
COMPUTER USAGE
Students use MALAB for analysis, problem solving and design
DESIGN CONTENT
0.5 credit or 16.7%
CLASS SCHEDULE
Lecture 3 hours per week
PROFESSIONAL CONTRIBUTION
Engineering Science: 2.5 credits or 83.3%
Engineering Design: 0.5 credit or 16.7%
RELATIONSHIP BETWEEN COURSE AND PROGRAM OUTCOMES
Course outcomes fulfill the following program objectives:
a. Knowledge of scientific principles that are fundamental to the following application areas: Circuits, Communications, Computers, Controls, Digital Signal Processing, Electronics, Electromagnetics, Power and Solid State.
b. An ability to design and conduct experiments, analyze and interpret data, design a system, component, or process using the techniques, skills, and modern engineering tools, incorporating the use of design standards and realistic constraints that include most of the following considerations: economic, environmental, sustainability, manufacturability, ethical, health and safety, social and political.
d. An ability to identify, formulate and solve engineering problems
e. An ability to communicate effectively and possess knowledge of contemporary issues and a commitment to continue developing knowledge and skills after graduation
COURSE PREPARER AND DATE OF PREPARATION
Eugene E. McGaugh
Share with your friends: |