George Mason University
Course Description

CS455 Computer Communications and Networking

Sections 001 Fall 2008: Friday 1:30 pm - 4:10 pm, Innovation Hall 133

updated Sep 12, 2008


Instructor: Nagesh Kakarlamudi
Mail drop ST2-335
Office hours Fridays 16:15 to 18:00 and by appointment
Preferred contact is email:


Current Catalog Description

Data communication and networking protocols, with study organized to follow layers of the Internet Protocol Suite (TCP/IP family of protocols). Topics include role of various media and software components, local and wide area network protocols, network performance, and emerging advanced commercial technologies.


The course will present techniques and systems for communication of data between computational devices and the layers of the Internet Protocol Suite. Topics include the role of various media and software components, local and wide area network protocols, network design, performance and cost considerations, and emerging advanced commercial technologies. Emphasis is on the TCP/IP family of protocols. The ISO 7-layer reference model to organize the study. Students will program simplified versions of the protocols as part of the course project.


* Larry Peterson and Bruce Davie, Computer Networks, A Systems Approach, 4th Edition, Morgan-Kaufmann
* Pullen, Understanding Internet Protocols, Wiley, 2000.

James Kurose and Keith Ross, Computer Networking - A Top-Down Approach Featuring the Internet, Addison Wesley, 2004.

Course Outcomes
1. Explain basic electrical engineering principles that enable communication at the physical layer
2. Demonstrate an understanding of wired and wireless data link layer protocols for shared medium and point-to-point communication
3. Demonstrate an understanding of the graph theory concepts required for unicast and multicast routing
4. Demonstrate an understanding of distributed routing protocols
5. Describe how protocols and applications use ARQ algorithms for distributed reliability
6. Demonstrate an understanding of end-to-end transport layer protocols
7. Explain basic concepts in cryptography and networking security protocols.
8. Illustrate fundamental understanding of networking by programming portions of the entire network stack.
9. Demonstrate a basic understanding of performance analysis for computer networking

Prerequisites by Topic
CS 310 (Data Structures)
CS 365 (Computer Systems Architecture)
STAT 344 (Probability and Statistics for Engineers and Scientists)

Major Topics Covered in the Course
1. OSI 7-layer model
2. Flow/error control
3. Medium access control
4. Ethernet
5. Routing
6. Multicasting
7. Internet architecture
8. TCP/UDP protocols
9. Multimedia networking
10. Security

The grading breakdown is as follows:
* 20% Projects
* 20% Assignments
* 25% Midterm exam
* 35% Final exam

Project: We will use the Java Network Workbench (JNW), software developed at GMU that simulates a protocol stack and displays the results, using a text interface. Students will create modules for Internet stack layers and run them in the JNW environment. The projects will be coordinated by author Prof Mark Pullen (email: JNW will be available for download from Well documented code must be submitted to Prof Mark Pullen for grading via an upload webpage at Additional projects will be available for extra credit. Student problems with the project are to be addressed to Prof Mark Pullen;

The project is documented in one of the required texts. Additional project information will be found at

Project credit breakout: JDLC1, JDLC2, JLAN1, JWAN2, JTRN1 amd JTRN2 five points each; extra credit assignments to be announced.

Missed exams must be arranged with the instructor BEFORE the exam date.

Assignments are due by 14:00 on assigned date. Late assignments lose 10% per class credit. No project submission will be accepted after last lecture day (12/5/2008).

All students are expected to abide by the Honor Code as stated in the GMU catalog and elaborated for Computer Science. Students should be aware that their submissions may be checked by plagiarism detection software.

Grading is proficiency-based (no curve), cutoffs will be in the vicinity of (but not higher than) A  93; A- 90; B+ 87; B 83; B- 80; C 70.

Extra credit is available by doing extra projects; however, no student who fails the final exam will receive a grade higher than C, regardless of extra credit earned.

SYLLABUS (subject to revision)
date and topic/readings in Peterson text/project assignment

8-29 Course introduction; network concepts; 7-layer and 5-layer models / Sections 1.1 to 1.4 / JNW Setup introduced

9-5 Physical layer: analog telecommunications / Section 1.5 / Project JDLC1: bit stuffing introduced

9-12 Physical layer: digital telecommunications / Sections 2.1 & 2.2

9-19 Data compression, security principles, integrity, appropriate use / Sections 2.3, 2.4 & 7.2 / Project JDLC1 due

9-26 Data link control; discrete event simulation / Section 2.5 / Project JDLC2: CRC introduced

10-3 Mid-term exam

10-10 Local area networks / Sections 2.6 to 2.9 / Project JLAN1: CSMA/CD LAN introduced

10-17 Network Layer: WANs, X.25, routing / Chapter 3 except Section 3.3; Project JDLC2 due

10-24 Internet Architecture (IPv4); Metcalfe’s Law /Chapter 4/ Project JWAN2: Forwarding and Routing introduced; Project JLAN1 due

10-31 Queueing basics; transport layer: TCP and UDP; IPv6 / Chapter 5 & Sections 6.1 to 6.4 / Project JTRN1: Reliable Transport introduced

11-7 Multicast, multimedia and ATM networking /Section 6.5, 7.1 & 3.3 / Project JTRN2: congestion window introduced; Project JWAN2 due

11-14 Network Security and Network Management / Chapter 8 / Project JTRN1 due

11-21 No class; work on project

11-28 No class; Thanks Giving Break

12-5 Higher layer protocols / Chapter 9; Project JTRN2 due; any extra credit projects due; no project submission accepted after this day

12-12 Final exam (comprehensive) / all chapters listed above / Exam location: classroom

Course communication: we will use email extensively. Students are responsible to read email daily. Announcements will be sent to the class email list, which consists of GMU email accounts.

Course notices and assignments will be provided via email. Course materials (for example, homework solutions) will be available though the course webpage, Students are responsible for assigned readings and all material outlined in lecture slides.

University Requirements

  • Academic Honesty and Honor Code Statement.

  • Disability Statement
  • CS Department Honor Code