Download Digital Electronics syl.

Department of Computer Engineering
Faculty of Engineering
Islamic University Of Gaza
Course:
EELE 3321 Digital Electronics
Semester:
2nd 2009
Prerequisites: Electronics I, Digital Design
Textbook:
Digital Integrated Circuits by DeMassa and Ciccone, John Wiley, 1996.
Instructor: Eng. Abdessalam Elahabbash
Room: I217, Phone: 2877,
Home page: http://www.iugaza.edu.ps/emp/ahabbash , Email: [email protected]
Office Hours: NT, 11-12
TA:
Eng. Mahmoud Elhabbash
Course Description: In an analog design course, you have learned how to design and analyze analog
circuits. Although analog electronics is a major part of electronics, many of today electronic systems are
based on digital circuits, from hand held calculators to the most sophisticated computers. There has been a
tremendous development in digital circuits over the past three decades, and there are a number of
approaches for implementation of digital circuits. This course intends to give you a background on digital
electronics.
This course will cover various circuit families, including diode-transistor logic (DTL), transistor-transistor
logic (TTL), emitter-coupled logic (ECL), NMOS, PMOS, and CMOS logic. In addition, various other
circuits used in digital world will be covered. These include regenerative circuits, Schmitt-triggers,
mutivibrators, RAMs, ROMs and Multiplexing circuits.
Course Objectives: EELE 3321 is intended to provide the electrical and computer engineering student
with a familiarity to and an understanding of the analytical and computer skills required for the analysis,
computer simulation, and design, and the capacity to apply this knowledge with creative skill to a variety of
applications in electrical and computer engineering. Analysis and Design of Digital Electronics is
preparatory for study in the field of Very Large Scale Integrated (VLSI) digital circuits and engineering
practice. The course focuses upon the systematic analysis and design of basic digital integrated circuits in
CMOS technology, with a brief description of bipolar integrated circuit technologies. Problem solving and
creative circuit design techniques are emphasized throughout.
References:
 Microelectronic Circuit Design, R.C. Yaeger, McGraw-Hill, New York, NY, 1997.
 Microelectronic Circuits, 3rd edition, Sedra and Smith, Sounders, 1991.
 Electronic Devices and Circuit Theory. Bylestand and Nashelsky. Prentice Hall, Englewood Cliffs, 1996.
 Digital Integrated Circuits: A Design Perspective. Jan M. Rabaey, Prentice Hall, 1996.
 Digital Microelectronics, H. Haznedar, Benjamin/Cummings Publishing Company, New York, 1991.
Course Grading:
Midterm exam: 25%, Sunday, May 3, 2009, 11:00-12:30
Final exam:
45%,
Project:
10%
Quizzes:
10%
Homeworks:
10%,
- Homeworks will be advertised on the home page.
- No late homework will be accepted.
- In case of cheating, you will receive zero grade.
1
Course Outcomes:
Students who successfully complete this course will be able to:
1. work productively with others toward the successful completion of group assignments.
2. develop individual problem solution methods and present these methods to members of the
assignment team.
3. demonstrate engineering self-learning skills.
4. design, implement, and document laboratory experiments with investigating analysis.
5. complete the design of a practical digital system application within constraints of capital and time
investment.
6. understand and explain the structure of commercially available digital integrated circuit families.
7. calculate the critical voltages and plot the voltage transfer characteristics of commercial available
integrated circuit families.
8. estimate the transient characteristics of commercial available integrated circuit families using
interface models.
9. calculate power dissipation, fan-out, fan-in, noise margins of commercial available integrated
circuit families.
10. make device and logic family selections and evaluations for design purposes.
11. critique system design and make solution suggestions for digital noise reduction.
12. Use computer simulation to estimate the effective of temperature, fan-out, interconnection, and
structure on the static and dynamic characteristics of commercially available digital integrated
circuits.
Detailed Course Syllabus
Page
1-11
15-23
31-50
56-67
72-80
83-92
155
221-234
234-373
556
498
Chapter
1
2
3-4
5
6
7
11
16-17
18-23
22,24,28
25
26-29
32-33
31
Topic
Properties and definitions of Digital ICs
Diodes (2.1-4 short), Diode Resistor Logic (2.5, 2.6)
BJTs (3.7-3.9). The Ebers-Moll model, Introduction to Bipolar Digital Circuits
RTL
DTL
TTL
Basic Emitter-Coupled Logic
MOSFETs, Introduction to MOS Digital Circuits
Loaded NMOS Inverter
CMOS Combinational Logic Gates
Transmission Gates
Interfacing Logic Families
Random Access Memories (RAMs), Read-Only Memories (ROMs)
Latches & FF
Exams
2
Hrs.
2
2
2
3
2
2
3
1.5
4
3
1.5
6
3
4
3