History of Fiber Optics By James Buckner The Sage Group.

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Presentation transcript:

History of Fiber Optics By James Buckner The Sage Group

1854 – John Tyndall First Guided transmission of light Used basin with hole in bottom to direct stream of water. Sunlight was refracted through the stream of water.

1880 – William Wheeling Used mirrored pipes to carry light from one source to many rooms. Did not take off because of Edison’s incandescent light bulb gained widespread popularity.

1880 – Alexander Graham Bell Invented the photophone, a device to carry voice signals through the air instead of wires. While the photophone did not materialize, it became the forerunner to a networking technology called Free Space Optics, or FSO. FSO uses lasers and detectors to transmit data between buildings without wires.

1920 – First attempt with optical transmissions John Logie Baird (England) and Clarence W. Hansell (U.S.) jointly file patent for a method to carry television images through transparent pipes. Images were transmitted in It was a very short distance, but the quality was very, very low.

1954 – Invention of modern optical fiber Abraham van Heel covered a bare glass fiber with a transparent coating. This coating, later called cladding, had a lower refractive index than the bare fiber. The result was that the light was contained in the fiber and did not leak out.

1960 – Medial Imaging & Invention of the Laser Fiberscope allowed for the inspection of boilers and medical imaging. Laser was invented this year. Optical Fibers had losses of 1 dB/meter. instruments.com/products/optical/industrial.shtml

Telephone company demands Telephone companies were interested in optical fiber. Possible bandwidth increases were possible with the invention of the videophone. Telephone companies wanted losses of no more than 10 – 20 dB/km.

The proposal that started it all Charles K. Kho was an engineer with Standard Telecommunications Laboratories. He proposed in 1966 that communications were possible with single mode fiber. This presentation was made to the Institute of Electrical Engineers (now IEEE) Attenuation of less than 20 dB/km was possible with optical fiber

1970 – Corning Glass Invents Optical Fiber Inventors: Keck, Maurer, Schultz Single mode fiber at 633 nm wavelength Attenuation below 20 dB/km

1977 – Phone Companies Use Optical Fiber Used multimode fibers at first Transmission rates of 6.2 Mb/s and 45 MB/s First generation systems: 850 nm wavelength; 2 dB/km attenuation Second generation systems: 1300 nm wavelength; 0.4 dB/km

1980 – Bell Labs Proposes First Fiber Transatlantic Cable TAT-8 transatlantic cable proposed Uses single mode fiber Speed: 565 Mb/second over 2-pair fiber

1984 – Everything Changes Modified Final Judgment splits AT&T into seven Regional Bell Operating Companies First wave of deregulation hits telephone industry Microwave Communications Inc. (MCI) looks to single mode fiber for its communications MCI terrestrial systems operate at 1300 nm at 400 Mb/sec. Amplifiers are spaced every 50 kilometers.

1988 AT&T activates TAT nm becomes standard for fiber optic systems.

nm systems appear for the first time. Transatlantic cable TAT-10 activated Fiber attenuation now at 0.2 dB/km at 1550 nm

New optical amplifiers appear Erbium Doped Fiber Amplifiers are now available. EDFAs allow for optical amplification without conversion to electrical and back again. Wave Division Multiplexing now possible.

Fiber Optic Cable Attenuation (Long-haul fiber)

1996 – The Internet boom begins Transatlantic cable TAT-12/13 activated. Data rate is 5 Gb/second. Netscape, maker of the Netscape browser, goes public and starts the Dot.Com boom. Telecommunications Act of 1996 signed into law. The Act forces the incumbent telephone companies to open their networks to competition. Competitive Local Exchange Carriers open for business.

1998 – More innovations Dense Wave Division Multiplexing (DWDM) systems become widely available. Some systems have an aggregate capacity of 10 Gb/second. Optical fiber is placed in the ground at phenomenal rates. Digital Subscriber Lines become available at much faster rates than dial-up connections. Dot.com boom shows no signs of stopping.

Wave Division Multiplexing Systems

Projected Internet Growth through 2005

2001 – The bubble bursts DWDM systems can now transmit 100 waves at 10 Gb/sec. The aggregate capacity is now 1 terabit per second. Telecom bubble bursts Global Crossing, Worldcom, and Enron see heavy losses. Enron files for bankruptcy.

2002 – Present Stronger companies like Level(3) and Qwest bought up smaller players and assets of bankrupt fiber communications companies. More households have high speed connections than the dot.com era. MCI merges with Verizon. Verizon also launches FiOS, which is fiber to the home. SBC manages to unite four of the seven RBOCs and AT&T into one company.

Questions