Optical transceivers are integrated circuit chips that send and receive data. These optical transceivers use fiber circuits to send and receive data rather than common electrical wire. The term for routing messages through cable wire and fiber interfaces is fiber optic circuits. Central hubs are attached to end users at extremely fast speeds with these transceiver chips. An easy way to understand their function: these transceivers can connect your home and office networks as well as things like television and phone services at record times.
The quick speed of data routing rates is what makes this transceiver chip a vital technology. Tests have shown that these chips can transfer data up to 160 Gbps. In comparison, these transceivers can join you to the internet at a transmission of 1,600 times quicker than Ethernet. Production used to make these small transceiver chips involves semi-conductor materials. They are slight in size but huge in power. There is more use to this advancing technology than simply signing on to the internet. They are also useful for local and wide range networks, home and office use, and downloading motion pictures in record times.
Built by industry standards, these transceivers are physical form factors. Under the Multi-Source Agreement, all professional designers are held to the same design laws. These transceivers are grouped into support routing speeds. These transmissions range from 1 Gbps to 10 Gbps, with each fiber designed to support specific speeds. 1 Gbps transceiver form factors are normally known as SFP modules and SFP modules. These special modules support rate ranges from 100 Mbps all the way to 4 Gbps. Form factors with other identities are X2, XFP and Xenpak. These optics support a speed range of up to 10 Gbps.
As an example, a GBIC module is employed with one end plugged into an Ethernet port and another end that connects a fiber optic patch cord with a fiber optic network. The fiber optic network and Ethernet data is transformed by this type of transceiver. This optic is grouped by its optical wavelength, transmission rate, power and working distance. They are a hot pluggable which allows a port to be moved from one 10g sfp+ transceiver module type of external interface to another easily.
Xenpak modules are another transceiver example. Created within the MSA Agreement, these pluggable fibers were built by standards developed by Agilent Tech and Agere Systems. Functioning in multimode and single mode optical fiber, and copper lines, there is a wider range of these modules. This 10G transceiver fiber module is the broadest in size, and contains a dual SC fiber interface. A typical copper line has a max span of 15 meters, while multimode fiber line works up to 300 meters.
You will continuously see further developments of fiber optic interfaces that will continue to improve their rates and power abilities, linking you to networks and entertainment sources faster. With the continuous support of the Multi-Source Agreement, this technology will remain at the forefront of the industry.