Network Engineer Masters Degree

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1 Plan No. 2009 Curriculum Master of Science in Computer and Network Engineering (Dissertation) I. General Terms and Conditions 1. This plan complies with the general framework for graduate study programs at the University of Jordan. 2. Applicants for admission to this program have a bachelor’s degree in the following specializations (fourth policy): a) Computer engineering b) Electrical engineering c) Network engineering d) Communication engineering e) Electronics engineering f) Mechatronics engineering II. Curriculum: Study (33) credit hours as follows: 1. Required courses listed in Table 1; (15) Credit hours. Course number Course name Random variables and random processes Communication network analysis Credit hrs. Preschool Advanced Design Networked Systems Computer Architecture Distributed Systems

2 Lesson No. 2. Selected lessons from the list given in Table 2; (9) Credit hours. Course name Credit hours. Fundamentals of Digital Communications I Wireless Systems Multimedia Streaming Data Systems Computer Performance Evaluation Wireless Networks and Security Advanced Embedded Systems Parallel Processing Special Topics in Computer and Network Engineering 3-3. master thesis; (9) Credit hours. 2

Network Engineer Masters Degree

Network Engineer Masters Degree

3 Plan Number 2009 Curriculum Master of Science in Computer and Network Engineering (Non-Dissertation Track) I. General Terms and Conditions 1. This plan complies with the general framework regulations for graduate programs of study at the University of Jordan. 2. Applicants for admission to this program have a bachelor’s degree in the following specializations (fourth policy): a) Computer engineering b) Electrical engineering c) Network engineering d) Communication engineering e) Electronics engineering f) Mechatronics engineering II. Curriculum: Study (33) credit hours is as follows: 1. Required courses listed in Table 3; (24) Credit hours. Course number Course name Random variables and random processes Communication network analysis Credit hrs. Basics of wireless communication systems. Network systems. Network design and security. Systems of wireless networks. Advanced computer architecture. Distributed systems.

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4 Lesson No. (9) Credit hours. Course name Credit hours. Background Digital Communications I Streaming Multimedia Data Communication Systems Computer Performance Estimating Computer Performance Advanced Embedded Systems Parallel Processing Special Topics in Computing and Networking 3-3. Comprehensive examination ( ). 4

5 III. Random and stochastic variables Course description (3 credit hours) Probability processes and random variables. Distribution and density functions. Functions of random variables. Two random variables and series of random variables. Multidimensional random variables. Random processes. Markov chains. Spectral representation of random processes. Spectral evaluation. Digital Communications Project I (3 credit hours) Introduction to communication systems. Basic and band digital modulation technologies: sequential codes, ASK, FSK, PSK, DPSK, QAM. Performance indicators: power, bandwidth, bit error rate. Synchronization of carrier and symbol. Signal design for channels with limited bandwidth. Signal design for curved channels. Communication Network Analysis Project (3 credit hours) Prerequisite: Introduction to mass service theory and traffic organization. Markov chains, equations of steady state and equilibrium. Continuous and discrete income models. The main ranking systems. Erlang formulas. Application of telephone systems and data transmission networks, performance parameters (probability of blocking, delay, throughput and reliability). Systems with holidays, priority systems, voting and reservation systems. Network modeling. Design of wireless communication systems (3 credit hours) Overview of multiple access methods: TDMA, FDMA, CDMA, OFDMA. Design of wireless communication systems: modulation, propagation, channel estimation, equalization and coding. Cellular systems (GSM / 3G / 4G), synchronous and asynchronous CDMA and code synchronization. CDMA performance and multi-user interference elimination. satellite communication systems. Internal communication systems, wireless LANs and wireless protocols Data transmission systems (3 credit hours) Introduction to communication and transmission networks. Asynchronous and synchronous transmission, SDH/SONET. Design and engineering of telephone systems. Technologies of broadband access. Working on the Internet and Internet Protocol (IP), routing in IP. Quality of Service (QOS). Voice over IP (VoIP). Audio and video transmission. IP network planning. Data integration and cellular/wireless networks. Security issues. Procedure. 5

6 events of streaming multimedia information (3 credit hours). Adding audio-video data. Effectiveness of integration technologies and speed analysis functions. A mathematical introduction to number theory. Cyclic codes, BCH and CRC. Convolutional and turbo codes. LDBC codes. Performance of error correction codes. Packet Data Transmission and Formatting for Computer Performance Evaluation of Audio and Video Data (3 credit hours) Issues in Performance Evaluation and Benchmarking. Tools and techniques for measurement, driving simulation, tracking and performance. Metric selection. Reference indicators. Statistical methods of productivity assessment. Generation and verification, synthetic traces, verification of simulators. Design of experiments. Analytical modeling of processes, statistical modeling, hybrid methods. Application of sequence theory, Markov models, and probabilistic models to computer system evaluation. Designing Operational Network Systems (3 credit hours) This course provides a comprehensive overview of the current state of computer networking research. Topics include: Internet Architecture; Internet Routing: Border Gateway Protocol (BGP), routing specification, routing security, AS connectivity to the Internet, engineering traffic, end-host congestion control; quality of service, network security: intrusion detection systems, worms and decoys; mobile and wireless networks; peer-to-peer and overlay network; content distribution networks; sensor networks; Critical network infrastructure services: domain name server (DNS), mail servers, etc.; Network measurement: distance estimation, bandwidth measurement, troubleshooting tools; network administration Network and systems security (3 credit hours) Prerequisite: computer network monitoring. Number theory and field arithmetic. Sources of network threats. Data encryption: cryptography and encryption. Risk management. Key management. Protocols and algorithms of security systems. and web security and firewalls. Evaluation of the performance of security systems. 6

7 Wireless Networks (3 credit hours) Prerequisite: Introduction to Wireless Networks: Physical Layer, MAC and IEEE, HIPERLAN, Bluetooth, Channel Assignment and Switching, Power and Rate Control, Multi-Radio, Network Layer, Mobile IP and Naming, Routing in Mobile networks, transport protocol in wireless networks; types of wireless networks: wireless mesh networks, sensor networks, cellular networks, delay-tolerant networks, RFID and WiMax; Wireless Network Management and Security: Localization, Network Utilization Research, Network Diagnostics, Network Security Advanced Computer Architecture (3 credit hours) Topics in scientific methodologies, overview of computer design principles, process design, RISC processes, pipelines and memory hierarchies yati Instruction Level Parallelism (ILP), dynamic scheduling, multiplexing, speculative execution, and branch prediction. Limitations on ILP and programmatic approaches for further use of ILP. VLIW and EPIC approaches. Thread-level parallelism, multiprocessors, multiprocessors, and multithreading. Cache coherence and memory coherence. Advanced memory hierarchy design, cache and memory optimization, and memory technologies. Advanced topics in storage systems. Design and evaluation of input/output systems. Advanced Embedded Systems (3 credit hours) System Specifications. Computational concepts and models including state diagrams, SDL, Petri nets, message flow diagrams, UML. Network processing, Java, VHDL. SystemC, Verilog and System Verilog, and SpecC. Integrated system hardware, input/output, communication, processors, memory. Embedded operating systems, middleware and programming. Execution time forecasting. Scheduling in real-time systems. Embedded operating systems. Implementation of embedded systems: hardware / software code. Concurrent task-level control. High-level optimizations. Hardware/Software Sharing. Compiler for embedded systems. Voltage measurement and power management. Smooth real-world design and tools. Audit. Simulation. Rapid prototyping and emulation. Examination. incorrect modeling. Wrong needle. Analysis of risks and reliability. Official check. 7

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8 Parallel Processing (3 credit hours) An in-depth study of the design, development, and evaluation of modern parallel computers. Basic Design: Coding, Timing, Delay and Bandwidth. Architectural development and technological driving forces. Parallel programming models, communication primitives, programming and compilation techniques, multiprogramming workloads, and quantification methodology. Avoiding latency due to replication in small and large shared memory structures; cache coherence, protocols, directors and models of memory coherence. Message Passing: Protocols, Storage Management, and Locking. Efficient networking, security, events, active messages, and coprocessors in large architectures. Lookahead delay tolerance, multithreading, dynamic instruction scheduling, and programming techniques. Network design: topology, packing, k-n-cubes, performance discussed. Synchronization: global operations, mutual exclusion, and events. Alternative architectures: Dataflow, SIMD, systolic sequences. Distributed Systems (3 credit hours) Prerequisite: Introduction to distributed systems. Distributed operating systems. Process and inter-process communication (IPC). Distributed file systems. Remote Procedure Calls (RPC). Security models. Distributed architectures and technologies. Middleware. Object-oriented distributed systems. Messages and message-oriented systems. Agent systems. Distributed Application Project Special Topics in Computer Engineering. and (3 credit hours) Networks Special topics of interest in computer engineering and network issues. The course description is indicated by the department in each course proposal. 8

Curriculum for the Master’s Degree in Electrical Engineering / Wireless Communications The Master’s Degree in Electrical Engineering / Wireless Communications is awarded by the Faculty of Graduate Studies.

MEngg Course List (Computer Systems) Course no.

Network Engineer Masters Degree

CONTENTS Table of Contents Introduction v vii xvii Chapter 1 Extending Wireless Networks 1.1 1.2 1.3 1.4 1.5 1.6 1.7 Signal Transmission Mechanisms 1.2.1 Multipath 1.2.2 Delay

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Master of Science (Electrical Engineering) MS(EE) 1. Mission: The mission of the Department of Electrical Engineering is to provide quality education to prepare students who will play an important role.

Master of Science in Computer Engineering Curriculum The Master of Science in Computer Engineering is offered by the Faculty of Postgraduate Education at the Jordan University of Science and Technology (JUST).

Master of Science in Computer Science Background/Intelligence The MSCS program aims to provide breadth and depth of knowledge in relevant concepts and methods.

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