CE334-6-PT-CA:
Telecommunication Networks and Systems
2020/21
Computer Science and Electronic Engineering (School of)
Colchester Campus & Apprenticeship Location
Spring Special
Undergraduate: Level 6
Current
Sunday 17 January 2021
Friday 02 July 2021
15
29 July 2020
Requisites for this module
(none)
(none)
(none)
(none)
(none)
The module describes the fundamental principles of telecommunication systems and networks covering both RF/MW and optical fibre communications by a unified approach. Following an overview of modern and future telecommunication networks and an introduction to basic principles of information and its processing in communications, the main transmission and demodulation techniques of the information-carrying analog and digital signals are considered in depth for RF/MW and optical systems.
Lightwave communication systems, their key components and operation principles are discussed next. This provides an integral understanding of how modern communication systems operate at all levels from top to bottom. The analysis is extended to consider multi-channel optical fibre transmission system employing wavelength division multiplexing (WDM) optical technology, the cornerstone of modern photonic networks. Operation of key elements and switching sub-systems such as optical cross-connects (OXCs) and optical add-drop multiplexers (OADMs) and the others are studied in detail.
The concluding part of the module deals with transmission system engineering, including analysis of the effect of various impairments on the system performance, system optimisation, and power budget. Consideration of basic issues of telecommunication network deployment, management and network survivability and protection completes the module.
The aim of this module is to describe the fundamental principles of telecommunications and networks for both RF, wired and optical fibre communications.
After completing this module, student will be expected to be able to:
1. Discuss the main features of modern telecommunication networks.
2. Explain the principles of information, its measure, coding, transmission, and detection.
3. Explain signal transmission fundamentals.
4. Describe the main components of lightwave telecommunication systems and their operation.
5. Describe multi-channel optical fibre transmission systems and explain their elements.
6. Discuss transmission system engineering.
7. Explain basics of network deployment and management and network survivability.
Outline Syllabus
Modern Telecommunication Networks:
Telecommunication network evolution. Hierarchical network architectures. Network topologies.
Services. Circuit switching and Packet switching in networks.
Modern and emerging technologies (RF and fibre-optic, channel multiplexing (WDM, TDM)).
Brief overview of optical networks (Generations of optical networks).
Principles of Information:
Concepts of information, messages, signals.
Analog and digital messages. Sampling and PAM. Analog-to-digital conversion (PCM) technique.
Information entropy. Data compression and source coding. Huffman coding algorithm.
Channel coding. Hamming coding algorithm.
Signals and noise.
Channel capacity.
Fundamental limitations of communication systems. Shannon-Hartley law and Shannon bound.
Signal Transmission Fundamentals:
Basic elements of communication systems.
Signals and spectra.
Non-coherent and coherent communication systems (RF/Microwave and Optical Systems).
Principles of modulation and demodulation (detection) of analog and digital signals.
Baseband and bandpass transmission.
Digital modulation techniques (ASK, PSK, DPSK, QPSK, QAM, FSK).
Transmission formats (RZ and NRZ), their advantages and drawbacks.
Demodulation and detection. Noise; SNR; BER in communication systems.
Optical signal processing.
Components of Lightwave Telecommunication Systems:
Main active and passive components of the optical-fibre links and their operation:
(i) Fibres: Waveguiding; Attenuation; Dispersion; Non-linear effects. Recent developments in fibre technology (Photonic crystal fibres; Plastic fibres).
(ii) Optical transmitters: Semiconductor laser diodes (FP multimode laser; DBR and DFB single-mode lasers; Wavelength tunable laser diodes). LEDs. Direct and external modulation of optical signals.
(iii) Optical fibre amplifiers: EDFA; Raman and Brillouin amplifiers.
(iv) Optical receivers/detectors: p-i-n photodiode; Avalanche photodiode (APD).
(v) Optoelectronic regenerators.
Multi-Channel Optical Fibre Transmission Systems:
Optical Time Division Multiplexing (OTDM) and Wavelength Division Multiplexing (WDM).
WDM network elements:
(i) Optical multiplexers and de-multiplexers.
(ii) Optical filters.
(iii) Optical couplers.
(iv) Optical cross-connects (OXCs).
(v) Optical Add-Drop Multiplexers (OADMs).
(vi) Optical switches. Recent advanced switching technologies: 2D and 3D MEMS; Electro-Optics; Liquid crystals.
Transmission System Engineering:
Impairments in optical links and their effect on signal transmission (attenuation, dispersion, non-linearity, interference, crosstalk).
System optimisation and performance enhancement.
Power budget in communication systems and networks.
Network Management and Network Survivability:
Deployment considerations. Architectural choices. Designing transmission layer: Long-haul networks; Metropolitan area networks (MANs); Access network; Local area networks (LANs).
Network management functions: Performance; Faults; Configuration; Security.
Network survivability: Basic concepts and layer protection
- Carlson, A. Bruce; Crilly, Paul. (2009) Communication Systems, London: McGraw-Hill Education - Europe.
- Couch, Leon W.; Kulkarni, Muralidhar; Acharya, U. Sripati. (2013) Digital and analog communication systems, Harlow: Pearson Education.
- Ramaswami, Rajiv; Sivarajan, Kumar N.; Sasaki, Galen H. (2008) Optical Networks, San Francisco: Elsevier Science & Technology.
- Agrawal, G. P. (c2010) Fiber-optic communication systems, Hoboken, NJ: Wiley.
The above list is indicative of the essential reading for the course. The library makes provision for all reading list items, with digital provision where possible, and these resources are shared between students. Further reading can be obtained from this module's reading list.
Assessment items, weightings and deadlines
| Coursework / exam |
Description |
Deadline |
Coursework weighting |
| Coursework |
Progress Test - week 24 |
|
33.33% |
| Coursework |
Assignment 1 - Written Report |
|
66.67% |
| Exam |
Main exam: 180 minutes during Summer (Main Period)
|
Exam format definitions
- Remote, open book: Your exam will take place remotely via an online learning platform. You may refer to any physical or electronic materials during the exam.
- In-person, open book: Your exam will take place on campus under invigilation. You may refer to any physical materials such as paper study notes or a textbook during the exam. Electronic devices may not be used in the exam.
- In-person, open book (restricted): The exam will take place on campus under invigilation. You may refer only to specific physical materials such as a named textbook during the exam. Permitted materials will be specified by your department. Electronic devices may not be used in the exam.
- In-person, closed book: The exam will take place on campus under invigilation. You may not refer to any physical materials or electronic devices during the exam. There may be times when a paper dictionary,
for example, may be permitted in an otherwise closed book exam. Any exceptions will be specified by your department.
Your department will provide further guidance before your exams.
Overall assessment
Reassessment
Module supervisor and teaching staff
Dr Nick Zakhleniuk, email: naz@essex.ac.uk.
Dr Nick Zakhleniuk, Dr Jianhua He
School office, email: csee-schooloffice (non-Essex users should add @essex.ac.uk to create full e-mail address), Telephone 01206 872770
No
No
No
Dr Yunfei Chen
University of Warwick
Associate Professor
Dr Xu Wang
Heriot-Watt University
Associate Professor
Available via Moodle
No lecture recording information available for this module.
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