Abstract :
The global telecommunications and networking backbone contains millions of kilometers of fiber-optic cabling, but we use only one ten-thousandth of the potential bandwidth of those cables. One reason is that a single converter from electrical to optical signals can only make use of a small amount of the optical spectrum, limiting the achievable bandwidth to about 2.5 Gbit/s. Wavelength division multiplexing (WDM) helps to resolve this disparity. WDM takes advantage of the fact that multiple wavelengths (or frequencies) of IR light can be transmitted simultaneously down a single optical fiber, and each of those frequency channels can carry independent information. With the use of WDM, the capacity of a single strand of fiber, 250 microns in diameter, can carry between 10 and 80 Gbps; a typical cable of 18 mm in diameter contains up to 200 fibers
Keywords :
optical fibre communication; wavelength division multiplexing; 10 to 80 Gbit/s; 125 micron; 2.5 Gbit/s; 9 mm; IR light transmission; bandwidth; electrical-to-optical signal conversion; fiber-optic cabling; global telecommunications backbone; networking backbone; ultra-high-speed fiber optics; wavelength division multiplexing; Bandwidth; Frequency; Glass; Optical fiber cables; Optical fibers; Plastics; Repeaters; Time division multiplexing; Wavelength division multiplexing; Wire;
