An important part of designing and installing an
Ethernet is selecting the appropriate Ethernet medium. There are four major
types of media in use today: Thickwire for 10BASE5 networks; thin coax for
10BASE2 networks; unshielded twisted pair (UTP) for 10BASE-T networks; and
fiber optic for 10BASE-FL or Fiber-Optic Inter-Repeater Link (FOIRL) networks.
This wide variety of media reflects the evolution of Ethernet and also points
to the technology’s flexibility. Thickwire was one of the first cabling systems
used in Ethernet, but it was expensive and difficult to use. This evolved to
thin coax, which is easier to work with and less expensive. It is important to
note that each type of Ethernet, Fast Ethernet, Gigabit Ethernet, 10 Gigabit
Ethernet, has its own preferred media types.
The most popular wiring schemes are 10BASE-T and
100BASE-TX, which use unshielded twisted pair (UTP) cable. This is similar to telephone
cable and comes in a variety of grades, with each higher grade offering better
performance. Level 5 cable is the highest, most expensive grade, offering
support for transmission rates of up to 100 Mbps. Level 4 and level 3 cable are
less expensive, but cannot support the same data throughput speeds; level 4
cable can support speeds of up to 20 Mbps; level 3 up to 16 Mbps. The
100BASE-T4 standard allows for support of 100 Mbps Ethernet over level 3
cables, but at the expense of adding another pair of wires (4 pair instead of
the 2 pair used for 10BASE-T). For most users, this is an awkward scheme and
therefore 100BASE-T4 has seen little popularity. Level 2 and level 1 cables are
not used in the design of 10BASE-T networks.
For specialized applications, fiber-optic, or
10BASE-FL, Ethernet segments are popular. Fiber-optic cable is more expensive,
but it is invaluable in situations where electronic emissions and environmental
hazards are a concern. Fiber-optic cable is often used in inter-building applications
to insulate networking equipment from electrical damage caused by lightning.
Because it does not conduct electricity, fiber-optic cable can also be useful
in areas where heavy electromagnetic interference is present, such as on a
factory floor. The Ethernet standard allows for fiber-optic cable segments up
to two kilometers long, making fiber-optic Ethernet perfect for connecting
nodes and buildings that are otherwise not reachable with copper media.
Cable Grade Capabilities
Cable Name
|
Makeup
|
Frequency Support
|
Data Rate
|
Network Compatibility
|
Cat-5
|
4 twisted pairs of copper wire — terminated by RJ45 connectors
|
100 MHz
|
Up to 1000Mbps
|
ATM, Token Ring,1000Base-T, 100Base-TX, 10Base-T
|
Cat-5e
|
4 twisted pairs of copper wire — terminated by RJ45 connectors
|
100 MHz
|
Up to 1000Mbps
|
10Base-T, 100Base-TX, 1000Base-T
|
Cat-6
|
4 twisted pairs of copper wire — terminated by RJ45 connectors
|
250 MHz
|
1000Mbps
|
10Base-T, 100Base-TX, 1000Base-T
|
Topologies
Network topology is the geometric arrangement of
nodes and cable links in a LAN. Two general configurations are used, bus and
star. These two topologies define how nodes are connected to one another in a
communication network. A node is an active device connected to the network,
such as a computer or a printer. A node can also be a piece of networking
equipment such as a hub, switch or a router.
A bus topology consists of nodes linked together in
a series with each node connected to a long cable or bus. Many nodes can tap
into the bus and begin communication with all other nodes on that cable
segment. A break anywhere in the cable will usually cause the entire segment to
be inoperable until the break is repaired. Examples of bus topology include
10BASE2 and 10BASE5.
General Topology Configurations
10BASE-T Ethernet and Fast Ethernet use a star
topology where access is controlled by a central computer. Generally a computer
is located at one end of the segment, and the other end is terminated in
central location with a hub or a switch. Because UTP is often run in conjunction
with telephone cabling, this central location can be a telephone closet or
other area where it is convenient to connect the UTP segment to a backbone. The
primary advantage of this type of network is reliability, for if one of these
‘point-to-point’ segments has a break; it will only affect the two nodes on
that link. Other computer users on the network continue to operate as if that
segment were non-existent.
Collisions
Ethernet is a shared medium, so there are rules for
sending packets of data to avoid conflicts and to protect data integrity. Nodes
determine when the network is available for sending packets. It is possible
that two or more nodes at different locations will attempt to send data at the
same time. When this happens, a packet collision occurs.
Minimizing collisions is a crucial element in the
design and operation of networks. Increased collisions are often the result of
too many users on the network. This leads to competition for network bandwidth
and can slow the performance of the network from the user’s point of view.
Segmenting the network is one way of reducing an overcrowded network, i.e., by
dividing it into different pieces logically joined together with a bridge or
switch.
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