Future Of Fiber Optics Light example essay topic
ORIGIN OF FIBER OPTICS Information (data and voice) is transmitted through the fiber digitally by the use of high speed LASERs (Light Amplification through the Simulated Emissionof Radiation) or LEDs (Light Emitting Diodes). So, all of the data is sent light pulses. All of this seems to be a very 'modern' concept, and the technology we use is. The concept though, was the idea of Alexander Graham Bell in the late 1800's. He just didn't have a dependable light source... some days the sun doesn't shine! He thought of the idea that our voices could be transmitted by pulses of light.
The people who thought that audio, video, and other forms of data could be transmitted by light through cables, were present day scientists. Most of the things that are possible today, Alexander Graham Bell could never even have dreamed of. Although the possibility of light wave communications occurred to Alexander Graham Bell (who invented the telephone), his ideas couldn't be used until the LASER or LED had been invented. Most of these advances occurred in the 1970's, and by 1977 glass-purifying and other fiber-optic manufacturing techniques had also reached the stage where interoffice light wave communications were possible.
With further technological development, many intercity routes were in operation by 1985, and some transoceanic routes had been completed by 1990. Now, in the mid-90's, worldwide connections are possible through the Internet. The light is prevented from escaping the fiber by total internal reflection, a process that takes place when a light ray travels through a medium with an Index of Refraction higher than that of the medium surrounding it. Here the fiber core has a higher refractive index than the material around the core, and light hitting that material is reflected back into the core, where it continues to travel down the fiber. THE PROPAGATION OF LIGHT AND LOSS OF SIGNALS The glass fibers used in present-day fiber-optic systems are based on ultrapure fused silica (sand). Fiber made from ordinary glass is so dirty that impurities reduce signal intensity by a factor of one million in only about 16 ft of fiber.
These impurities must be removed before useful long-haul fibers can be made. But even perfectly pure glass is not completely transparent. It weakens light in two ways. One, occurring at shorter wavelengths, is a scattering caused by unavoidable density changes within the fiber. In other words, when the light changes mediums, the change in density causes interference. The other is a longer wavelength absorption by atomic vibrations.
For silica, the maximum transparency, occurs in wavelengths in the near infrared, at about 1.5 m (micrometers). APPLICATIONS Fiber-optic technology has been applied in many areas, although its greatest impact has come in the field of telecommunications, where optical fiber offers the ability to transmit audio, video, and data information as coded light pulses. Fiber optics are also used in the field of medicine, all of the wire-cameras and lights are forms of fiber optic cable. In fact, fiber optics have quickly become the preferred mode of transmitting communications of all kinds. Its advantages over older methods of transmitting data are many, and include greatly increased carrying capacity (due to the very high frequency of light), lower transmission losses, lower cost of basic materials, much smaller cable size, and almost complete immunity to any interference. Other applications include the simple transmission of light for illumination in awkward places, image guiding for remote viewing, and sensing.
ADVANTAGES OF FIBER OPTIC CABLET his copper cable contains 3000 individual wires. It takes two wires to handle one two-way conversation. That means 1500 calls can be transmitted simultaneously on each cable. Each fiber optic cable contains twelve fiber wires. Two fibers will carry the same number of simultaneous conversations as one whole copper cable.
Therefore, this fiber cables replace six of the larger ones. And 90,000 calls can be transmitted simultaneously on one fiber optic cable. LONG DISTANCE FIBER-OPTIC COMMUNICATIONS SYSTEM SAT&T's Northeast Corridor Network, which runs from Virginia to Massachusetts, uses fiber cables carrying more than 50 fiber pairs. Using a semiconductor LASER or a light-emitting diode (LED) as the light source, a transmitter codes the audio or visual input into a series of light pulses, called bits. These travel along a fiber at a bit-rate of 90 million bits per second (or 90 thousand kips). Pulses need boosting, about every 6.2 miles, and finally reach a receiver, containing a semiconductor photo diode detector (light sensor), which amplifies, decodes, and regenerates the original audio or visual information.
Silicon integrated circuits control and adjust both transmitter and receiver operations. THE FUTURE OF FIBER OPTICS Light injected into a fiber can adopt any of several zigzag paths, or modes. When a large number of modes are present they may overlap, for each mode has a different velocity along the fiber. Mode numbers decrease with decreasing fiber diameter and with a decreasing difference in refractive index between the fiber core and the surrounding area.
Individual fiber production is quite practical, and today most high-capacity systems use single fibers. The present pace of technological advance remains impressive, with the fiber capacity of new systems doubling every 18 to 24 months. The newest systems operate at more than two billion bits per second per fiber pair. During the 1990's optical fiber technology is expected to extend to include both residential telephone and cable television service. Currently Bell South is placing fiber cables containing up to 216 fibers, and manufacturers are starting to build larger ones. Bell South has been placing fiber cables in the Orlando area since the early 1980's, and currently has hundreds of miles in service to business and residential customers.
Bibliography
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