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Terrestrial Free-Space Optical Communications Popoola, W.O. Optical Communication Research Group, NCRLab. Supervision Team: Fary Ghassemlooy – Director of studies Joseph Allen Erich Leitgeb ( University of Technology, Graz, Austria) Popoola, W.O. 2009 1 Outline Part 1 Introduction to FSO Part 2 My Research Discussions and Remarks Popoola, W.O. 2009 2 Part 1: Introduction Free-space optics (FSO) started around 18781 and was made popular by the photo phone experiment of Alexander G. Bell in 18802 involving the modulation of sun radiation with voice signal. Radiation from the sun The photophone schematic Alexandra Graham Bell’s Photophone experiment 1http://modulatedlight.org/Modulated_Light_DX/ModLightBiblio.html 2Alexander Graham Bell, "On the production and reproduction of sound by light," American Journal of Sciences, Series 3, pp. 305 - 324, Oct. 1880. Popoola, W.O. 2009 3 FSO witnessed a tremendous growth in the 1960s fuelled by the discovery of lasers. Variants of FSO Indoor Applications Including TV and Sound system remote controls – very low data rate (Source: Boston University) Outdoor Applications (Deep space and terrestrial) Emphasis on outdoor FSO…. Popoola, W.O. 2009 4 In the early days, terrestrial FSO (civil) The early terrestrial applications were mainly for analogue signals (mostly sound) applications stalled because In the 1970s, the main attention was for deep space application . existing communications were adequate to handle Notable space FSO flagship systems projects : • NASA’s Mars Laser Communication Demonstration (MLCD) and ESA’s Semiconductor-laser Inter-satellite Link Experiment (SILEX). the• demands of the time. Popoola, W.O. 2009 5 But…. ….the increasing demand for more bandwidth in the face of new and emerging applications implies that the old practice of relying on just one access technology to connect with the end users has to give way. This among others, led to the resurgence of terrestrial FSO for various applications including sound, data and video transmission. Popoola, W.O. 2009 6 Terrestrial FSO block diagram Transmitter Transmit Telescope Atmospheric Channel Absorption Receiver Receive Telescope Turbulence Scattering Optical Source (LED/LASER) Message Background radiation noise Optical Filter Driver Circuit Photodetector Modulator Post detection Processor Popoola, W.O. 2009 Estimated Message 7 Features of FSO No trenches No license fee No electromagnetic interference Complements other access network technologies Huge bandwidth similar to fibre Quick to install; only takes few hours Requires no right of way Achievable range limited by thick fog to ~500m Over 3 km in clear atmosphere Popoola, W.O. 2009 8 Terrestrial FSO Challenges The main challenges are due to the nature of the atmospheric channel Rain snow The resulting effects: Signal attenuation/power loss Received optical power fluctuation (fading) Popoola, W.O. 2009 9 Rain and snow A heavy rainfall of 15 cm/hour causes 20 - 30 dB/km loss in optical power light snow about 3 dB/km power loss Blizzard could cause over 60 dB/km power loss Popoola, W.O. 2009 10 Aerosols and Gases Effects: Scattering - Change in direction of photons Absorption - Photons extinguished and energy lost into the aerosol in form of heat. Both contribute to signal attenuation, ( ) () m () a () m () a (). Absorption coefficient Scattering coefficient (molecular and aerosol) (molecular and aerosol) Popoola, W.O. 2009 11 Within the wavelength band used in FSO, (0.5 μm – 2 μm) scattering dominates the attenuation process. That is: () a () a () 3.91 V 550 Scattering coefficient in terms of visibility, V, and wavelength, λ. Scattering process at λ = 850 nm Type Radius(µm) Size parameter, Scattering process xo Air Molecules 0.0001 0.00074 Rayleigh Haze particle 0.01 – 1 0.074 – 7.4 Rayleigh – Mie Fog droplet 1 – 20 7.4 – 147.8 Mie - Geometrical Rain 100 – 10000 740 – 74000 Geometrical Snow 1000 – 5000 7400 –37000 Geometrical Hail 5000 –50000 37000 – 370000 Geometrical Popoola, W.O. 2009 Kim model, 1.6 1.3 0.16V 0.34 V 0.5 0 V 50 6 V 50 1V 6 0. 5 V 1 V 0.5 Kruse model, 1.6 1.3 1 0.585V 3 V 50 6 V 50 V 6 12 Signal Attenuation Attenuation coefficient at λ = 850 nm. Thick fog Thick fog causes the most attenuation of over 100 dB/km. Limits link range to ~500 km. Clear air In clear atmosphere, the attenuation is as low as 0.4 dB/km. Longer ranges of over 3 km therefore practical. Weather conditions and their visibility range values3 Weather condition Thick fog Moderate fog Light fog Thin fog/heavy rain (25mm/hr) Haze/medium rain (12.5mm/hr) Clear/drizzle (0.25mm/hr) Very clear Popoola, W.O. 2009 3Free-space Visibility range (m) 200 500 770 – 1000 1900 – 2000 2800 – 40000 18000 – 20000 23000 – 50000 optics by Willebrand and Ghuman, 2002 13 Experimental attenuation measurement in Milan (11th January 2005)5 1000 900 Visibility Range ( m ) 800 700 600 500 400 300 Low visibility, high attenuation 200 100 250 160 300 350 400 450 500 550 600 650 700 750 Tim e ( m in ) Sp. Attenuation (dB/km ) 140 120 100 80 Measured laser attenuation (red curve) and the estimate from the visibility values(blue curve). 60 40 20 0 250 300 350 400 450 500 550 600 650 700 750 Tim e ( m in ) Popoola, W.O. 2009 5Courtesy: TU Graz Collaborator – Prof. Erich Leitgeb 14 Scintillation Effect Channel temperature fluctuation = changes in refractive index of the channel P: Te: n: λ: Channel pressure Channel temperature Channel refractive index Beam wavelength Effects: Signal fluctuation (fading) Complete loss of signal Loss of signal coherence Wave front deformation Scintillation Refraction and diffraction of beam Popoola, W.O. 2009 Image dancing 15 Other Challenges Pointing Alignment Line of sight Building sway Popoola, W.O. 2009 16 Part 2: My Research Research Theme Combating FSO channel (fading) effect using: 1. Robust modulation technique 2. Spatial diversity and 3. Temporal diversity Popoola, W.O. 2009 17 Research Objectives: To investigate, model and analyse: 1. On-Off keying (OOK) modulated FSO (existing technique) 2. Subcarrier intensity modulated (SIM) FSO 3. Compare 1 and 2 above 4. Spatial and Temporal diversity schemes on FSO 5. Laser non-linearity effects Link budget analysis To design an FSO test bed Recommendations Popoola, W.O. 2009 18 Laboratory investigation Simplified diagram of the experimental setup Laser Turbulence simulation chamber Popoola, W.O. 2009 19 Rm E105 BPSK modulator •Carrier 1.5 MHz •Data rate 200 kbps Turbulence chamber •Dimension 140 x 30 x 30 cm •Temp. range 24oC – 60oC Laser Module (Direct Modulation) Power = 3mW λ = 785nm Reflecting mirror OOK & BPSK Mod. +Dem. Turbulence chamber Reflecting mirror Thermometers PIN Detector + Amplifier Optical power meter head Heaters + Fans Popoola, W.O. 2009 20 Turbulence Simulation Received mean signal + Noise + Scintillation Input signal : Pure sinusoid with zero mean Popoola, W.O. 2009 21 Turbulence Simulation - Signal distribution With signal scintillation Histogram of mean - no scintillation Lognormal Gaussian fit fit Mean =1 Mean = -0.0012 16 Variance = 9e-3 = 5e-5 2.5Variance Gaussian fit 14 2 Lognormal fit 10 Bin Size Bin Size 12 1.5 6 1 8 4 0.5 Observations 2 Total fluctuation variance = 9.10-3 (V2) 0 0 0.85 0.9 1 0 -0.05 -0.04 Lognormal -0.03 -0.020.95 -0.01 • Weak Scintillation obeys Signal level Signal level distribution (variance < 1) • Scintillation dominates over noise • Simulated turbulence is very weak. Popoola, W.O. 2009 1.05 0.01 0.021.1 0.03 1.150.04 22 OOK: Data bit 1: Transmission of an optical pulse + Noise Data bit 0: No pulse + Noise In turbulent channels ith depends on: No atmospheric turbulence Noise level and • Turbulence strength Bit “1” Threshold position. ith Signal Distribution Bit “0” • 0 2 2 ((ir RI ) ir ) exp 2 2 0 ln( I / I ) 2 / 2 0 l exp 2 2 l Eg 2 1 2 l 2 1 . I dI Bit separation ith = Eg/2 Popoola, W.O. 2009 23 OOK threshold level against the turbulence strength Noise level 0.5 2 = 5*10-3 2 = 10-2 0.45 2 = 3*10-2 2 = 5*10-2 Threshold level, i th 0.4 For optimum performance, threshold level must adapt to the channel noise and fading. 0.35 0.3 0.25 That, is a tough call. 0.2 0.15 0.1 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 Log Intensity Standard Deviation, l 0.8 0.9 1 Fading strength All commercially available FSO systems use OOK with fixed threshold which results in suboptimal performance in turbulence regimes Popoola, W.O. 2009 24 OOK with Scintillation effect Received Signal 8 7.5 7 No Scintillation Threshold position. ith Bin Percentage 6.5 6 5.5 5 4.5 4 3.5 3 2.5 2 1.5 Received Transmitted 1 0.5 0 -0.2492 -0.1992 -0.1492 -0.0992 -0.0492 0.0008 0.0508 Signal Level 1.4 0.1008 0.1508 0.2008 0.2492 Received Signal ≈ 400mV p-p With Scintillation 1.3 1.2 Threshold range 1.1 Bin Percentage 1 0.9 0.8 Observation: The optimum symbol decision position in OOK depends on scintillation level and noise 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 -0.3488 -0.2488 -0.1487 -0.0487 0.0513 Signal Level 0.1513 0.2513 0.35130.3987 Popoola, W.O. 2009 25 Subcarrier Intensity Modulation (SIM) + + - - Data Standard RF BPSK modulator Popoola, W.O. 2009 26 Subcarrier Intensity Modulation (SIM) a1c g(t) X m1c(t) cos(ωc1t+φ1) g(t) X m1s(t) . . . . . aNc . . . . . g(t) sin(ωc1t+φ1) . . . X mNc(t) m(t) Σ Σ Driver circuit Serial-to-parallel converter and encoder d(t) a1s bo DC bias Atmospheric channel cos(ωcNt+φN) aNs g(t) X mNs(t) sin(ωcNt+φN) Subcarrier multiplexing for increased throughout or capacity Popoola, W.O. 2009 27 BPSK-SIM signal distribution In turbulent channel Bit “0” Signal Distribution Threshold position. ith Bit “1” -Eg ith = 0 Threshold level does not depend on turbulence Eg Popoola, W.O. 2009 Bit separation 28 BPSK-SIM with Scintillation Effect Received Signal Demodulated (No low Pass filtering) Before demodulation Subcarrier phase preserved Demodulated Signal ≈ 400mV p-p Popoola, W.O. 2009 29 BPSK-SIM with Scintillation Effect 3.5 3.4 No Scintillation 3.2 3 2.8 Threshold position. ith 2.6 BIn Percentage 2.4 2.2 2 1.8 1.6 1.4 1.2 1 0.8 0.6 0.4 0.2 0 -0.2 -0.15 -0.1 -0.05 0 0.05 Singal Level 0.1 0.15 0.2 3.5 3.4 With Scintillation 3.2 3 2.8 2.6 Threshold position. ith Observation: Scintillation does not affect the symbol decision position in BPSK-SIM Bin Percentage 2.4 2.2 2 1.8 1.6 1.4 1.2 1 0.8 0.6 0.4 0.2 0 -0.25 -0.2 -0.15 Popoola, W.O. 2009 -0.1 -0.05 0 0.05 Signal Level 0.1 0.15 0.2 0.25 30 Error performance of OOK Vs BPSK-SIM -1 10 Fixed threshold OOK -2 10 -3 Performance based on similar electrical SNR 10 BER -4 10 -5 10 -6 10 Log irradiance Variance = 0.2 OOK Threshold Level -7 10 -8 10 0.2 0.5 Adaptive BPSK-SIM 10 15 20 25 Electrical SNR (dB) 30 35 Atmospheric turbulence, σl2 = 0.2. Popoola, W.O. 2009 31 BPSK-SIM BER against the normalised SNR in atmospheric turbulence. -2 10 -4 10 -6 BER 10 -8 10 Fading strength -10 10 2l = 0.1 2l = 0.3 2l = 0.5 -12 10 Fading penalty 2l = 0.7 No fading 15 20 25 30 Normalised SNR (dB) Popoola, W.O. 2009 35 40 45 32 BPSK-SIM BER against turbulence strength for SNR (dB) = [5, 20, 25, 30]. 0 10 -5 10 -10 10 Increasing power helps to combat fading but only during very weak fading. -15 BER 10 -20 10 -25 10 -30 10 Normalised SNR 5 dB 20 dB 25 dB 30 dB -35 10 -40 10 -2 10 -1 0 10 10 Fading strengthvariance, 2l Log irradiance Popoola, W.O. 2009 33 Diversity scheme: Exploiting the spatial variations in the channel characteristics Combiner It1 It2 d(t) BPSK ModuLator and . . . Laser driver ItH F S O i1 (t ) C H A N N E L i2 (t ) iN (t ) a1 a2 . . . . a iT BPSK Subcarrier Demodulator dˆ (t ) N ai is the scaling factor Diversity Combining Techniques Maximum Ratio Combining (MRC) [Complex but optimum] ai ii Equal Gain Combining (EGC) Selection Combining (SELC). No need for phase information a1 a2 ... a N Popoola, W.O. 2009 iT (t ) max( i1 (t ), i2 (t )...i N (t )) 34 Spatial Diversity Gain: 30 Log Intensity Turbulence variance strength Spatial Diversity Gain (dB) 25 1 20 MRC EGC 15 0.52 10 5 0 0.22 1 2 3 4 5 6 No of Receivers 7 8 9 10 Four detectors: Good compromise between performance and complexity Popoola, W.O. 2009 35 Diversity scheme: Exploiting the temporal variations in the channel characteristics Retransmission on different subcarriers Other possibilities: different wavelengths different polarisations Delay ≥ Channel coherence time This process is reversed at the receiver side to recover the data Popoola, W.O. 2009 36 Temporal Diversity Gain: No fading No TDD 1-TDD 3-TDD 5-TDD 2-TDD -2 10 -4 BER 10 -6 10 -8 10 BER =10-9 -10 10 Rb = 155Mbps Log irradiance var =0.3 -32 -30 -28 -26 -24 -22 -20 Receiver sensitivity, Io (dBm) -18 -16 No TDD -17.17 Single delay path is the optimum Io (dBm) (no fading: -27.05) Fading penalty (dB) 9.88 Diversity gain (dB) 0 (gain / path) (0) Popoola, W.O. 2009 1-TDD 2-TDD -19.17 -19.85 3-TDD -20.13 5-TDD -20.3 7.88 2 (2) 6.92 2.96 (0.99) 6.75 3.13 (0.63) 7.2 2.68 (1.34) 37 Research Output Refereed Journal Articles 1. W. O. Popoola, Z. Ghassemlooy,: “BER and Outage Probability of DPSK Subcarrier Intensity Modulated Free Space Optics in Fully Developed Speckle” Journal of Communications (In print) 2. W. O. Popoola, and Z. Ghassemlooy,: “BPSK Subcarrier Modulated Free-Space Optical Communications in Atmospheric Turbulence” IEEEJournal of Lightwave Technology, Vol. 27. No 8, pp. 967-973, April 15 2009. 3. W. O. Popoola, Z. Ghassemlooy, and V. Ahmadi,: “Performance of sub-carrier modulated Free-Space optical communication link in negative exponential atmospheric turbulence environment,” International Journal of Autonomous and Adaptive Communications Systems, Vol. 1, No. 3, pp.342–355, 2008. 4. *W. O. Popoola, Z Ghassemlooy, J I H Allen, E Leitgeb, S Gao: “ Free-Space Optical Communication employing Subcarrier Modulation and Spatial Diversity in Atmospheric Turbulence Channel” IET Optoelectronics, Vol. 2, Issue 1, Feb. 2008, pp.16 – 23. 5. Ghassemlooy, Z., Popoola, W. O., and Aldibbiat, N. M.: “Equalised Dual Header Pulse Interval modulation for diffuse optical wireless communication system”, Mediterranean J. of Electronics and Communications, Vol. 2, No. 1, pp. 56-61, 2006. 6. W. Popoola, Z. Ghassemlooy, C. G. Lee, and A. C. Boucouvalas “Scintillation Effect on Intensity Modulated Laser Communication Systems A Laboratory Demonstration”, Elsevier’s Optics and Laser Technology Journal (Under review) *According to IET, this paper ranked No. 2 in terms of the number of full text downloads within IEEE Xplore in 2008, from the hundreds of papers published by IET Optoelectronics since 1980. Conference Articles 7. Z. Ghassemlooy, W. O. Popoola, V. Ahmadi, and E Leitgeb: “MIMO Free-Space Optical Communication Employing Subcarrier Intensity Modulation in Atmospheric Turbulence Channels” Invited paper. The First International ICST Conference on Communications Infrastructure, Systems and Applications in Europe (EuropeComm 2009) 11 -13 August, 2009, London, UK 8. W. Popoola, Z. Ghassemlooy, M. S. Awan, and E. Leitgeb: “Atmospheric Channel Effects on Terrestrial Free Space Optical Communication Links” Invited paper. 3rd International Conference on Computers and Artificial Intelligence (ECAI 2009), 3-5 July, 2009, Piteşti, Romania (To appear). 9. W. O. Popoola, Z. Ghassemlooy and E. Leitgeb “BER Performance of DPSK Subcarrier Modulated Free Space Optics in fully Developed Speckle”, IEEE - CSNDSP, 23-25 July 2008, Graz, Austria, pp. 273-277. Popoola, W.O. 2009 38 Research Output 10. Z. Ghassemlooy, W.O. Popoola, S. Rajbhandari, M. Amiri, S. Hashemi,: “A synopsis of modulation techniques for wireless infrared communication”, Invited paper. IEEE - International Conference on Transparent Optical Networks, Mediterranean Winter (ICTON-MW) Dec, 6-8, 2007 - Sousse, Tunisia, pp. 1-6. 11. W.O. Popoola and Z. Ghassemlooy.: “Free-Space optical communication in atmospheric turbulence using DPSK subcarrier modulation”, Ninth International Symposium on Communication Theory and Applications, ISCTA'07, 16th - 20th July, 2007, Ambleside, Lake District, UK. 12. Z. Ghassemlooy, W.O. Popoola, and E. Leitgeb. “Free-Space optical communication using subcarrier modulation in Gamma-Gamma atmospheric turbulence” Invited paper. IEEE - 9th International Conference on Transparent Optical Networks, July 1-5, 2007 - Rome, Italy. 13. W. O. Popoola, Z. Ghassemlooy and J. I. H. Allen. “Performance of subcarrier modulated Free-Space optical communications”, 8th Annual Post Graduate Symposium on the Convergence of Telecommunications, Networking and Broadcasting (PGNET), 28 th & 29th June 2007, Liverpool, UK. 14. S. Rajbhandari, Z. Ghassemlooy, N. M. Aldibbiat, M. Amiri, and W. O. Popoola: “Convolutional coded DPIM for indoor non-diffuse optical wireless link”, 7th IASTED International Conferences on Wireless and Optical Communications (WOC 2007), Montreal, Canada, May-Jun. 2007, pp. 286-290. 15. Popoola, W. O., Ghassemlooy, Z., and Amiri, M.: "Coded-DPIM for non-diffuse indoor optical wireless communications", PG Net 2006, ISBN: 1-9025-6013-9, Liverpool, UK, 26-27 June 2006. pp. 209-212. 16. W. O. Popoola, Z Ghassemlooy, and N. M. Aldibbiat,: "DH-PIM employing LMSE equalisation for indoor infrared diffuse systems", 14th ICEE 2006, Tehran, Iran. 17. W. O. Popoola, Z. Ghassemlooy and N. M. Aldibbiat: "Performance of DH-PIM employing equalisation for diffused infrared communications", LCS 2005, London, Sept. 2005, pp. 207-210. Posters 18. Popoola, W. O., and Ghassemlooy, Z.: “Free space optical communication”, UK GRAD Programme Yorkshire & North East Hub, Poster Competition & Network Event, Leeds, 9 May 2007, Poster No. 52. 19. Burton, A, Ghassemlooy, Z, Popoola, W.O., Simulation software for the evaluation of free space optical communications links, 19th International Scientific Conference, Mittweida, Germany, July 2008. Popoola, W.O. 2009 39 Summary FSO introduced and its challenges highlighted OOK and its pros and cons discussed Subcarrier intensity modulation and Diversity techniques discussed Popoola, W.O. 2009 40 Acknowledgement Supervision team members Fabulous Jolly Fary Ghassemlooy Joe Allen Exquisite Erich Leitgeb (TU Graz) – Director of study – 1st Supervisor – 2nd Supervisor My fellow research students apprentices Northumbria Univ. for funding my research Popoola, W.O. 2009 41 With plentiful: Patience Hard work & Due Diligence I look forward to (successfully) completing my Popoola, W.O. 2009 PhD Degree 42 Thank you. Questions/Remarks/Contributions Popoola, W.O. 2009 43