Photonics Systems - Introduction

Photonics Systems - Introduction

Photonics Systems - Introduction Sergiusz Patela, Dr Sc Room I/48, Th. 13:00-16:20, Fri. 9:20-10:50 [email protected] eportal.pwr.wroc.pl Copying and processing permitted for non- www.patela.net commercial purposes, on condition that proper reference to the source is given. © Sergiusz Patela, 2001-6 Fiber-optic-transmission milestones 1854 - Demonstration of optical waveguide principle in water jets (J. Tyndal) 1960 - Laser (ruby, T. Maiman) 1972 - 4 dB/km multimode fiber 1982 - Single mode fiber reported 1991 - SONET telecommunications standards created 1995 - DWDM deployment began 1998 - > 1 Tb/s in one fiber 2000 - L-band system introduced (1570-1610nm) 40 Gb/s transmission in one channel. © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 2/23 Fiber optic link Light detector Light source „noise” (receiver) (transmitter) Electrical output signal Electrical input signal Lightguide with splices connectors and couplers © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 3/23 Light wave Light wave: electromagnetic wave (signal carrier) characterized by intensity, phase (coherence level), wavelength (frequency), polarization and propagation direction. Physical phenomena and effects that explain how waveguide works: • Light wave frequency Light = electromagnetic wave of frequency 3x1014Hz, (almost million GHz). • Total internal reflection effect and extremely low glass attenuation Fibers can guide light at long distances without regeneration • Wave nature of light and fiber modes Many waveguide parameters and construction details can be explained only if one takes into account that light is a wave guided by a structure of very low cross-section. © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 4/23 Construction of optical fiber Core Cladding Cover © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 5/23 Total internal reflection n2 n1 Total internal reflection at the border core-cladding Fiber diameter: 10 to 50 µm at 1 m distance creates 10 000 reflections. For the reflection coefficient of 99% after 1 m the signal will be attenuated by 0.9910 000 = 10-44 © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 6/23 Waveguides’ classification 1. Mode structure (SM, MM) 2. Material (silica, plastic, …) 3. Geometry: planar and fiber waveguides 4. Refractive index distribution (step, gradient index) © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 7/23 Optical fibers Multimode step index fiber Cladding Core Multimode graded index fiber Cladding Core Single mode (step index) Cladding Core © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 8/23 Lightwave spectrum Wavelength (µm) Wavelength (nm) 1014 6 13 1625 - 1650 10 10 1012 × 4 Far L : 1570-1620 4 10 1011 10 C : 1525-1560 6×103 Middle 10 109 S : 1450-1510 1: 1550 1.5×103 Radio waves 108 2: 1300 Near 7 770 10 3: 850 IR 106 Red 5 622 Microwaves 10 Fiber optics 104 587 Orange 103 telecomm bands Yellow 102 Fiber optics 577 Infrared 10 windows Green 1 492 Visible 10-1 Blue Ultraviolet 10-2 455 10-3 X-rays 10-4 390 10-5 Violet 10-6 Gamma rays -7 300 UV 10 Note: 1625 - 1650 band 10-8 Near -9 is used to continuously 250 10 monitor the integrity of 10-10 -11 the fiber without Far 10 200 Cosmic rays 10-12 interfering with the 10-13 signals at 1550 or 1310 10 10-14 © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 9/23 Attenuation of optical fibers [dB/km] 50 30 10 5 I window II window 3 Attenuation 1 III transmission window 0.5 0.3 0.1 0.6 0.8 1.0 1.2 1.4 1.6 1.8 [µm] wavelength Spectral attenuation of silica glass fiber © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 10/23 10 advantages of optical fibers 1. High information capacity of a single fiber 2. Low loss = repeaterless transmission at long distances 3. Total immunity for EMI (electro magnetic interference) 4. Low weight 5. Small dimensions (diameter) 6. High work safety (low risk of fire, explosion, ignition) 7. Transmission safety (data taping almost impossible). 8. Relatively low cost (getting lower). 9. High reliability 10 Simplicity of installation. © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 11/23 Optical fiber networks - technology enablers and stimuli 1. Gigabit Ethernet, 2. vertical-cavity surface-emitting lasers (VCSELs), 3. 100Base-SX, 4. small-form-factor (SFF) connectors, 5. quick-cure adhesives, 6. mechanical connectors, 7. centralized cabling, 8. reduced cost of ferrules, 9. reduced cable costs, 10. preterminated cables Eric R. Pearson, Lightwave Magazine, Ten Reasons Fiber is Becoming More Cost-Effective in the Horizontal © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 12/23 Installations cost, comparison Comparison of 50 m fiber waveguide and copper links (Cat. 5 UTP). Category 5 UTP Fiber Socket $5.35 $5.70 Patch panel $5.06 $5.19 Connectors Not needed $18.24 Cabel (50 m) $41.58 $43.56 Installation cost $71.25 $66.75 Total $123.24 $139.44 © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 13/23 Light sources - definitions Light Emitting Diode (LED) A semiconductor junction device that emits incoherent optical radiation when biased in the forward direction Laser Acronym for Light Amplification by Stimulated Emission of Radiation. A device that produces a coherent beam of optical radiation by stimulating electronic, ionic, or molecular transitions to higher energy levels so that when they return to lower energy levels they emit energy Laser Diode (LD, Synonyms - injection laser diode, semiconductor laser ) A laser that uses a forward biased semiconductor junction as the active medium © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 14/23 Light sources - types Light Emitting Diode (LED) Surface Light Emitting Diode (SLED) Edge Light Emitting Diode (ELED) Resonance Cavity Enhanced (RCE) LED Laser FP (Fabry-Perot) DFB (Distributed Feed-Back) DBR (Distributed Bragg Reflectors) VCSEL (Vertical Cavity Surface Emitting Lasers) © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 15/23 Light sources - LED parameters Both LED’s and LD’s emitting wavelengths are set by material selection: AlGaAs: 780-860 nm, InGaAsP: 1300, 1550 nm. LED parameters type material wave- fiber coupled power spectral width bandwidth length - fiber type (FWHM) 3 dB nm µW nm MHz SLED AlGaAs 860 95 - 62.5/125 50 50 60 - 50/125 2.5 - 9/125 ELED InGaAsP 1300 20 - 9/125 60 350 ELED InGaAsP 1550 8 - 9/125 © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 16/23 Light sources - LD parameters Fiber optics LD are available in pigtailed versions and with standard fiber optic receptacles LD type wave- laser fiber coup- fiber type length power led power nm mW mW FP 1310 5 1 9/125 FP 1310 5 2 62.5/125 FP 1550 5 1 9/125 DFB 1550 5 1 9/125 © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 17/23 Detectors - definition Definition A device that is responsive to the presence or absence of a stimulus Stimulus Detector Output In an optical communications receiver is a device that converts the received optical signal to another form. Note: Currently, this is conversion is from optical to electrical power, however optical-to-optical techniques are under development © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 18/23 Detector - construction For fiber optic applications detectors are available in standardized packages, • pigtailed or • combined with standard receptacles ST SC FC © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 19/23 Detectors - parameters Detector wavelength responsivity dark current type (high respons. range) material nm A/W nA InGaAs 1300 (1000-1700) 0.75 0.1 Si 850 (400-1100) 0.45 1 Ge 1300 (800-1500) 0.65 350 detectors are available as pin or APD structures © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 20/23 Splices and connectors Standard and SFF connectors (~ 1dB) Fiber splicing (~0.1dB) electric arc Fusion splicing fiber fiber index matching gel Mechanical splice fiber fiber alignment sleeve © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 21/23 Literature G. P. Agrawal, Fiber-optic communications systems, John Willey & Sons 1992 © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 22/23 Summary Creating fiber optic networks is an adventure not comparable to any other technical task today . Designer have to select everything - hardware type, „standards“, topology and protocols. On the other hand, properly designed and build networks can be in use even after 20 years - they can be used and evaluated by our children. © Sergiusz Patela, 2001-6 Photonics Systems - Introduction 23/23.

View Full Text

Details

  • File Type
    pdf
  • Upload Time
    -
  • Content Languages
    English
  • Upload User
    Anonymous/Not logged-in
  • File Pages
    23 Page
  • File Size
    -

Download

Channel Download Status
Express Download Enable

Copyright

We respect the copyrights and intellectual property rights of all users. All uploaded documents are either original works of the uploader or authorized works of the rightful owners.

  • Not to be reproduced or distributed without explicit permission.
  • Not used for commercial purposes outside of approved use cases.
  • Not used to infringe on the rights of the original creators.
  • If you believe any content infringes your copyright, please contact us immediately.

Support

For help with questions, suggestions, or problems, please contact us