Professor Z Ghassemlooy EN554 Photonic Networks Lecture 1: Introduction Professor Z Ghassemlooy Northumbria Communications Laboratory School of Informatics, Engineering and Technology The University of Northumbria U.K. http://soe.unn.ac.uk/ocr

Contents Reading List Lecture 1: Introduction Transmission Media History Communication Technologies Applications System Challenges Ahead Lecture 2: Components for Photonic Networks Lecture 3: Optical Amplifier Lecture 4: System Limitation and Non-linear effect Lecture 5: Transmission System Engineering Part 1 Lecture 6: Transmission System Engineering Part 2 Lecture 7: Photonic Networks Lecture 8: Photonic Switching Lecture 9: Wavelength Routing Networks Part 1 Lecture 10: Wavelength Routing Networks Part 2 Lecture 11: Access Network Lecture 12: Revision Tutorials and Solutions: Visit http://soe.unn.ac.uk/ocr

Reading List Essential Reading List Optional Reading List lyas, Mohammad and Mouftah, Hussien: The Handbook of Optical Communication Networks, CRC Press, 2004, ISBN 0-84-931333-3  Ramasawami, R and Sivarajan, K.N: Optical network: A practical perspective, Morgan Kaufmann, 2001, ISBN 1-55-860655-6  Donati, Silvano: Photodetectors: Devices, Circuits and Applications, Prentice Hall, 2000, ISBN 0-13-020337-8 Optional Reading List  Stern, T.E. and Bala, K: Multiwavelength Optical Networks: A layered approach, Addison Wesley, 1999, ISBN 0-20-130967-X  Sabella, R and Lugli, P:High speed optical communications, Kluwer Academic, 1999, ISBN 0-41-280220-1

Transmission Media Transmission Medium, or channel, is the actual physical path that data follows from the transmitter to the receiver. Copper cable is the oldest, cheapest, and the most common form of transmission medium to date. Optical Fiber is being used increasingly for high-speed applications.

Transmission by Light: why? Growing demand for faster and more efficient communication systems Internet traffic is tripling each year It enables the provision of Ultra-high bandwidth to meet the growing demand Increased transmission length Improved performance etc.

Typical data bandwidth requirement Demand for Bandwidth Bandwidth Demand 1990 2000 2010 Raw text = 0.0017 Mb Word document = 0.023 Mb Word document with picture = 0.12 Mb Radio-quality sound = 0.43 Mb Low-grade desktop video = 2.6 Mb CD-quality sound = 17 Mb Good compressed (MPEG1) video = 38 Mb Typical data bandwidth requirement 20,000 x

Historical Developments 800 BC Use of fire signal by the Greeks 400 BC Fire relay technique to increase transmission distance 150 BC Encoded message 1880 Invention of the photophone by Alexander Graham Bell

Historical Developments - contd. 1930 Experiments with silica fibres, by Lamb (Germany) 1950-55 The birth of clad optical fibre, Kapany et al (USA) 1962 The semiconductor laser, by Natan, Holynal et al (USA) 1960 Line of sight optical transmission using laser: - Beam diameter: 5 m - Temperature change will effect the laser beam Therefore, not a viable option 1966- A paper by C K Kao and Hockham (UL) was a break through - Loss < 20 dB/km  - Glass fibre rather than crystal (because of high viscosity) - Strength: 14000 kg /m2. Contd.

Historical Developments - contd. 1970 Low attenuation fibre, by Apron and Keck (USA) from 1000 dB/km - to - 20 dB/km - Dopent added to the silica to in/decrease fibre refractive index. Late 1976 Japan, Graded index multi-mode fibre - Bandwidth: 20 GHz, but only 2 GHz/km Start of fibre deployment. 1976 800 nm Graded multimode fibre @ 2 Gbps/km. 1980’s - 1300 nm Single mode fibre @ 100 Gbps/km - 1500 nm Single mode fibre @ 1000 Gbps/km - Erbium Doped Fibre Amplifier

Historical Developments - contd. - Soliton transmission (exp.): 10 Gbps over 106 km with no error - Optical amplifiers - Wavelength division multiplexing, - Optical time division multiplexing (experimental) OTDM 2000 and beyond - Optical Networking - Dense WDM, @ 40 Gbps/channel, 10 channels - Hybrid DWDM/OTDM ~ 50 THz transmission window > 1000 Channels WDM > 100 Gbps OTDM Polarisation multiplexing - Intelligent networks

Lightwave Evolution * Systems Research Experiments Capacity (Gb/s) Single Channel (ETDM) Multi-Channel (WDM) Single Channel (OTDM) WDM + OTDM WDM + Polarization Mux * Soliton WDM Capacity (Gb/s) 10,000 300 100 30 10 3 1 0.3 0.1 0.03 1000 3000 84 86 88 90 Year 92 94 96 98 80 82 00 02 04 Systems Research Experiments SLIDE 12: Here are the capacities of systems research experiments. As you know, these are usually called hero experiments and are presented as PD papers at ECOC or OFC. The average rate of increase is the factor of 100 every 10 years we talked about. 1996 is the year when 3 labs broke through the Tb/s barrier. In 2001, right on schedule, 2 labs achieved 10 Tb/s. However many of us are wondering whether the next factor of 10, due in 2006, will be accomplished on schedule. It appears that attention is currently shifting to achieving ULH distances and lowering the cost for shorter haul applications. Courtesy: A. Chraplyvy Chraplyvy11-30-00

System Evolution Research Systems Commercial Systems Fiberization Digitization SONET rings and DWDM linear systems Optical networking Wavelength Switching TOTDM Research Systems Commercial Systems 0.1 1 10 100 1000 10000 1985 1990 1995 2000 Year Capacity (Gb/s) 2004 cisco

Existing Systems - 1.2 Tbps WDM DWDM Typical bit rate 40 Gbps / channel ~ 8 THz (or 60 nm) Amplifier bandwidth 32 channels (commercial) with 0.4 nm (50 GHz) spacing 2400 km, no regeneration (Alcatel) Total bandwidth = (Number of channels) x (bit-rate/channel) OTDM Typical bit rate 6.3 Gbps / channel ~ 400 Amplifier bandwidth 16 channels with 1 ps pulse width

Commercial Systems H. Kogelnik, ECOC 2004 System Year WDM chan - nels Bit rate/ channel Fibre Voice channels per fibre Regen spans FT3 1980 1 45 Mb/s 672 7 km FTG 1.7 1987 Gb/s 1.7 Gb/s 24,192 50 km FT 2000 1992 2.5 2.5 Gb/s 32,256 NGLN 1995 8 20 258,000 360 km WaveStar TM 400G 1999 80 40 10 Gb/s 200 Gb/s 400 Gb/s 2,580,000 5,160,000 640 km 1.6T 2001 160 1.6 Tb/s 20,640,000 LambdaXtreme 2003 128 64 40 Gb/s 1.28 Tb/s 2.56 Tb/s 16,512,000 33,0 24,000 4000 km 1000 km SLIDE 13: The emphasis on ULH is also reflected in this table of commercial transmission systems. It is not just the capacity per fiber that’s increasing, but also the regenerator spans. They have increased from 7 km to 4000 km. Of course the transmission capacities are also impressive. The 2.5 Tb/s imply 33 M voice channels per fiber. This means you can carry all of Scandinavia’s phone calls on one fiber. H. Kogelnik, ECOC 2004

Communications Technologies Year Service Bandwidth distance product 1900 Open wire telegraph 500 Hz-km 1940 Coaxial cable 60 kHz-km 1950 Microwave 400 kHz-km 1976 Optical fibre 700 MHz-km 1993 Erbium doped fibre amplifier 1 GHz-km 1998 EDFA + DWDM > 20 GHz-km 2001- EDFA + DWDM > 80 GHz-km 2001- OTDM > 100 GHz-km

Optical Technology - Advantages High data rate, low transmission loss and low bit error rates High immunity from electromagnetic interference Bi-directional signal transmission High temperature capability, and high reliability Avoidance of ground loop Electrical isolation Signal security Small size, light weight, and stronger 448 copper pairs 5500 kg/km 62 mm 21mm 648 optical fibres 363 kg/km

Optics is here to stay for a long time. Applications Electronics and Computers Broad Optoelectronic Medical Application Instrumentation Optical Communication Systems High Speed Long Haul Networks  (Challenges are transmission type) Metropolitan Area Network (MAN) ? Access Network (AN)? Challenges are: - Protocol - Multi-service capability - Cost Optics is here to stay for a long time.

Undersea Cables

System Block Diagram Photonics Institute

Source Source coding Modulation Multiplexing External Internal Analogue Digital Frequency Time Pulse shaping Channel coding Encryption etc.

Receiver Sampler & detector 1st-stage amplifier 2nd-stage Pre-detection filtering Demultiplexer Equalizer Demodulator Output signal Decoder Decryption

Open Optical Interface All Optical Network SDH ATM IP Open Optical Interface Other All Optical Networks Challenges ahead: Network protection Network routing True IP-over-optics

Challenges Ahead Modulation and detection and associated high speed electronics Multiplexer and demultiplexer Fibre impairments: . Loss . Chromatic dispersion . Polarization mode dispersion . Optical non-linearity . etc. Optical amplifier . Low noise . High power . Wide bandwidth . Longer wavelength band S

Challenges Ahead - contd. Dedicated active and passive components Optical switches All optical regenerators Network protection Instrumentation to monitor QoS

Chromatic Dispersion It causes pulse distortion, pulse "smearing" effects Higher bit-rates and shorter pulses are less robust to Chromatic Dispersion Limits "how fast“ and “how far” data can travel 10 Gbps t 60 Km SMF-28 40 Gbps cisco t 4 Km SMF-28

Dispersion Compensating Fibre By joining fibres with CD of opposite signs (polarity) and suitable lengths an average dispersion close to zero can be obtained; the compensating fiber can be several kilometers and the reel can be inserted at any point in the link, at the receiver or at the transmitter

Polarization Mode Dispersion (PMD) Ex Ey Input pulse Spreaded output pulse nx ny The optical pulse tends to broaden as it travels down the fibre; this is a much weaker phenomenon than chromatic dispersion and it is of some relevance at bit rates of 10Gb/s or more cisco

Combating PMD Factors contributing to PMD Solutions for PMD Bit Rate Fiber core symmetry Environmental factors Bends/stress in fiber Imperfections in fiber Solutions for PMD Improved fibers Regeneration Follow manufacturer’s recommended installation techniques for the fiber cable

Optical Transport Network Global Network Wide Area Network Metropolitan/Regional Area Optical Network Corporate/ Enterprise Clients Cable modem Networks Client/Access FTTH Mobile SDH/ SONET ATM PSTN/IP ISP Gigabit Ethernet Cable FTTB < 10000 km < 10 Tbit/s < 100 km < 1 Tbit/s < 20 km 100M - 10 Gbit/s Courtesy: A.M.J. Koonen