Lysleder

Nærbillede af uindpakkede optiske fibre ledende synligt hvidt lys.

En lysleder eller et optisk fiber, også kaldt fibernet, er lavet af glas eller plastik og er designet til at transportere data som lysimpulser langs det indre af fiberens kerne.

Lysledere anvendes først og fremmest til telekommunikation – og i visse sensorer.

Lyslederes anvendelse indenfor telekommunikation skyldes lysledernes lave optiske tab ved de anvendte lysbølgelængder og for lysledere med tynde kerner (ca. 10 µm i diameter) kan signaler med store båndbredder sendes ca. 350–1000 km med normal digital amplitudemodulation ^[2] - og mere end 4.000 km med adaptive specielt designede pulser der udbreder sig som solitoner ned gennem fiberen. ^[3] ^[4] En solitons egenskab er, at pulsens form ikke tværes ud, uanset tilbagelagt afstand. Begge uden signalregenerering og signalforstærkning.

En enkel lysleder kan overføre flere lysbølgelængder og kan på denne måde overføre n*(10Gbit/s). F.eks. vil 320 passende valgte lysbølgelængder kunne overføre 3.200 Gbit/s. ^[5]

Elektriske koaksialkabler og parsnoede kabler klarer normalt kun 100 meter uden signalregenerering og signalforstærkning af store båndbredder på f.eks. 10Gbit/s.

Historie[redigér | rediger kildetekst]

Lyslederes principielle lys-guidende effekt blev først demonstreret af Daniel Colladon og Jaques Babinet i 1840'erne. ^[6] I 1952 udførte fysikeren Narinder Singh Kapany eksperimenter som ledte til opfindelsen af den optiske fiber, baseret på Tyndall's tidligere forskning; moderne optiske fibre, hvor glasfiberen er overtrukket med en gennemsigtig overtræk for at lave den refraktive overgang dukkede op senere i årtiet. ^[6]

I 1965 foreslog Charles K. Kao og George A. Hockham fra det Britiske firma Standard Telephones and Cables at optiske fibres dæmpning blev forårsaget af urenheder, som kunne fjernes. De spekulerede i at optiske fibre kunne blive et anvendeligt medium for kommunikation, hvis dæmpningen kunne reduceres til under 20 dB per kilometer (Hecht, 1999, p. 114). Dette dæmpningsmål blev nået i 1970, af forskerne Robert D. Maurer, Donald Keck, Peter C. Schultz og Frank Zimar, der arbejdede for det amerikanske glasmager Corning Glass Works, nu Corning Inc.. De demonstrerede et optisk fiber med en optisk dæmpning på 17 dB per kilometer af titanium-doteret Siliciumbaseret glas. Et par år senere producerede de et fiber med kun 4 dB/km ved anvendelse af germaniumoxider som kernedotering. Disse lave dæmpninger bebudede optiske fibres anvendelse til telekommunikation og muliggjorde internettet. I dag er optiske fibres dæmpning langt mindre end elektriske kobberkabler, hvilket ledte til fiberforbindelser på op til 500 – 800 km uden repeater.

Kilder/referencer[redigér | rediger kildetekst]

^ 2004-05-24, Sciencedaily: Tightly Focused Laser Light Generates Nonlinear Effects And Rainbow Of Color Citat: "..."supercontinuum generation in nonlinear fibers." The phenomenon can be observed in a new class of optical fibers, called photonic crystal fibers. PCFs consist of a tiny solid glass core surrounded by a cladding, or casing, that contains air holes along the length of the fiber...As the IR light propagates, or spreads, through a 1-meter-long fiber, the light appears, first orange, then yellow and finally green...The visible lightwaves emerge from the fiber as white light, which contains all the colors of the spectrum..."
^ Webarchive backup: telecommagazine.com: March 2001, Ultralong-Haul DWDM: The Big Tradeoff Citat: "...Today's optical networks use electrical regenerators approximately every 500 km along installed fiber, but they are expensive and power consuming..."
^ williamson-labs.com: The Revolution. Optical Fibers, Optical Recording, and the ultimate, Optical Computing Citat: "...Data transport using Soliton Pulses in Dispersion-Shifted Fiber Single Fiber: Errorless data transmission: 50 Gb/s, at over 19,000 km, No Repeaters. This technology is no longer a laboratory oddity, but has been in place and Growing for the last > 6 years..."
^ Webarchive backup: marconi.com: The Soliton Story Citat: "...At the heart of its pioneering work are “dispersion managed solitons” — a concept that has already enabled world-record transmission distances — a standard fiber carrying 10 Gbit/s across 16,000 km, for example, and 40 Gbit/s carried over 1,000 km...Solitons are essentially “stable pulses” that travel without changing their shape...Conventional optical networks lose 25 dB to 30 dB of signal per span between amplifiers, restricting a total span to around 1,000 km. Marconi SOLSTIS' goal is to achieve far longer distances with the same amplifier span, or enable longer spans over the original distance..."
^ 3/19/2001, lightreading.com: Corvis announces industry-leading 3.2 terabits per second optical transport system Citat: "...CorWave LR is a dense-wavelength-division-multiplexing (DWDM) transmission system that can transport up to 320 STM-64 (10 Gbps) wavelengths for up to 800 km or 160 STM-64 (10 Gbps) wavelengths in each direction for up to 2,000 km...CorWave XL and CorWave XF ¾ Repeaterless terrestrial or undersea festoon links used to build, expand and link national and regional networks. CorWave XL and XF can transmit up to 800 gigabits per fibre for distances as long as 350 km, eliminating the use of in-line amplifiers...", backup
^ ^a ^b Bates, Regis J (2001). Optical Switching and Networking Handbook. New York: McGraw-Hill. s. p10. ISBN 0-07-137356-X. {{cite book}}: |pages= har ekstra tekst (hjælp)

Eksterne henvisninger[redigér | rediger kildetekst]

Wikimedia Commons har flere filer relateret til Lysleder
The Fiber Optic Association
FOA color code for connectors
Lennie Lightwave's Guide To Fiber Optics Arkiveret 18. oktober 2005 hos Wayback Machine
How Fiber Optics are made Arkiveret 7. marts 2016 hos Wayback Machine In video
Introduction to Fiber Optics free pdf books

[1] 2004-05-24, Sciencedaily: Tightly Focused Laser Light Generates Nonlinear Effects And Rainbow Of Color Citat: "..."supercontinuum generation in nonlinear fibers." The phenomenon can be observed in a new class of optical fibers, called photonic crystal fibers. PCFs consist of a tiny solid glass core surrounded by a cladding, or casing, that contains air holes along the length of the fiber...As the IR light propagates, or spreads, through a 1-meter-long fiber, the light appears, first orange, then yellow and finally green...The visible lightwaves emerge from the fiber as white light, which contains all the colors of the spectrum..."

[2] Webarchive backup: telecommagazine.com: March 2001, Ultralong-Haul DWDM: The Big Tradeoff Citat: "...Today's optical networks use electrical regenerators approximately every 500 km along installed fiber, but they are expensive and power consuming..."

[3] williamson-labs.com: The Revolution. Optical Fibers, Optical Recording, and the ultimate, Optical Computing Citat: "...Data transport using Soliton Pulses in Dispersion-Shifted Fiber Single Fiber: Errorless data transmission: 50 Gb/s, at over 19,000 km, No Repeaters. This technology is no longer a laboratory oddity, but has been in place and Growing for the last > 6 years..."

[4] Webarchive backup: marconi.com: The Soliton Story Citat: "...At the heart of its pioneering work are “dispersion managed solitons” — a concept that has already enabled world-record transmission distances — a standard fiber carrying 10 Gbit/s across 16,000 km, for example, and 40 Gbit/s carried over 1,000 km...Solitons are essentially “stable pulses” that travel without changing their shape...Conventional optical networks lose 25 dB to 30 dB of signal per span between amplifiers, restricting a total span to around 1,000 km. Marconi SOLSTIS' goal is to achieve far longer distances with the same amplifier span, or enable longer spans over the original distance..."

[5] 3/19/2001, lightreading.com: Corvis announces industry-leading 3.2 terabits per second optical transport system Citat: "...CorWave LR is a dense-wavelength-division-multiplexing (DWDM) transmission system that can transport up to 320 STM-64 (10 Gbps) wavelengths for up to 800 km or 160 STM-64 (10 Gbps) wavelengths in each direction for up to 2,000 km...CorWave XL and CorWave XF ¾ Repeaterless terrestrial or undersea festoon links used to build, expand and link national and regional networks. CorWave XL and XF can transmit up to 800 gigabits per fibre for distances as long as 350 km, eliminating the use of in-line amplifiers...", backup

[regis-6] Bates, Regis J (2001). Optical Switching and Networking Handbook. New York: McGraw-Hill. s. p10. ISBN 0-07-137356-X. {{cite book}}: |pages= har ekstra tekst (hjælp)

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