Data Cabling
This section talks about
the cabling used in today's networks. There's a lot of different type of
cabling in today's networks and I am not going to cover all of them, but I will
be talking about the most common cables used , which include UTP CAT5 straight through and crossover,
Coax and a few more.
Cabling is very important if we want a
network to work properly with minimum problems and bandwidth losses. There are
certain rules which must never be broken when you're trying to design networks;
otherwise you'll have problems when computers try to communicate.
In the near future, cabling will
probably be something old and outdated since wireless communication seems to be
gaining more ground, day by day. With that in mind, around 95% of companies still
rely on cables.
Network
Topology
The network’s topology refers to the physical layout of the nodes and hubs
that make up the network. Choosing the right topology is important because the
topology affects the type of networking equipment, cabling, growth path, and
network management.
Today’s
networking architectures fall into one of three categories:
- Star
- Bus
- Ring
Star Topology
All computers are connected to a
single, centrally located point. This central point is usually a hub. All
cabling used in a star topology is run from the point where the network nodes
are located back to a central location.
Star Topology with a Central Hub
Bus Topology
The bus topology is the simplest network topology. Also known as a linear bus, all computers are connected
to a contiguous cable or a cable joined together to make it contiguous. Figure above
illustrates a bus topology. Ethernet is a common example of a bus topology.
Each
computer determines when the network is not busy and transmits data as needed.
Computers in a bus topology listen only for transmissions from other computers;
they do not repeat or forward the transmission on to other computers.
Bus Topology
Ring Topology
A ring topology requires that all computers be connected in a
contiguous circle, as shown in Figure above the ring has no ends or hub. Each
computer in the ring receives signals (data) from its neighbor, repeats the
signal, and passes it along to the next node in the ring. Because the signal
has to pass through each computer on the ring, a single node or cable failure
can take the entire ring down.
Ring Topology
Type of Cables
Technically,
when you begin the planning stages of a new cabling installation, you should
not have to worry about the types of applications used. The whole point of
structured cabling Standards such as ANSI/TIA/EIA-568-B and ISO/IEC 11801 is
that they will support almost any networking or voice application in use today.
Still,
it is a good idea to have an understanding of the networking application you
are cabling for and how that can affect the use of the cabling system. Further,
because cabling that’s related to data also connects to various types of
network devices, it is a good idea to have an understanding of the networking
hardware used in common installations.
UTP (Unshielded Twisted Pair)
Unshielded
Twisted Pair (UTP) cable is most certainly by far the most popular cable around
the world. UTP cable is used not only for networking but also for the
traditional telephone (UTP-Cat 1). There are 6 different types of UTP
categories and, depending on what you want to achieve, you would need the
appropriate type of cable. UTP-CAT5 is the most popular UTP cable; it came to
replace the good old coaxial cable which was not able to keep up with the
constant growing need for faster and more reliable networks.
Category
1/2/3/4/5/6 – a specification for the type of copper wire (most telephone and
network wire is copper) and jacks. The number (1, 3, 5, etc) refers to the
revision of the specification and in practical terms refers to the number of
twists inside the wire (or the quality of connection in a jack).
UTP
Category
|
Speed
|
Example
|
Cat 1
|
1 Mbps
|
Traditional telephone & ISDN
|
Cat 2
|
4 Mbps
|
Token Ring
|
Cat 3
|
10 Mbps
|
Token Ring & 10BaseT
|
Cat 4
|
16 Mbps
|
Token Ring
|
Cat 5
|
100 Mbps
|
Ethernet (10Mbps)
Fast Ethernet (100Mbps)
Token Ring (16Mbps)
|
Cat 5e
|
1000 Mbps
|
Gigabit Ethernet
|
Cat 6
|
1000 Mbps
|
Gigabit Ethernet
|
6 different UTP Categories
UTP Cat 5
There are 2 popular wiring schemes
that most people use today: the T-568A and T-568B, that differ only in which
color coded pairs are connected - pair 2 and 3 are reversed. Both work equally
well, as long as you don't mix them! If you always use only one version, you're
OK, but if you mix A and B in a cable run, you will get crossed pairs!
UTP
Cat 5 can be used in 3 different color codes depending on the situation:
1)
Straight
Thru
2)
Cross
Over
3)
Roll
Over – to used with maintenance router only
T568A & T568B Color Code
Straight Thru
Cross Over
Roll Over
So,
which cable do I need? The table below helps us determine which type of cable
we need for the setup:
|
|||||||||||||||||||||||||||||||||
568-A Wiring
Pair #
|
Wire
|
Pin #
|
1-White/Blue
|
White/Blue
|
5
|
Blue/White
|
4
|
|
2-White/Green
|
White/Green
|
1
|
Green/White
|
2
|
|
3-White/Orange
|
White/Orange
|
3
|
Orange/White
|
6
|
|
4-White/Brown
|
White/Brown
|
7
|
Brown/White
|
8
|
|
< 568-A Diagram
|
||
Patch Cable Assembly Instructions
1. Skin off the cable jacket
approximately 1" or slightly more.
2. Un-twist each pair, and straighten each wire between the fingers.
3. Place the wires in the order of one of the two diagrams shown above (568B or 568A). Bring all of the wires together, until they touch.
4. At this point, recheck the wiring sequence with the diagram.
5. Optional: Make a mark on the wires at 1/2" from the end of the cable jacket.
2. Un-twist each pair, and straighten each wire between the fingers.
3. Place the wires in the order of one of the two diagrams shown above (568B or 568A). Bring all of the wires together, until they touch.
4. At this point, recheck the wiring sequence with the diagram.
5. Optional: Make a mark on the wires at 1/2" from the end of the cable jacket.
6. Hold the grouped (and sorted) wires together tightly, between the
thumb, and the forefinger.
7. Cut all of the wires at a perfect 90 degree angle from the cable at 1/2" from the end of the cable jacket. This is a very critical step. If the wires are not cut straight, they may not all make contact. We suggest using a pair of scissors for this purpose.
8. Conductors should be at a straight 90 degree angle, and be 1/2" long, prior to insertion into the connector.
9. Insert the wires into the connector (pins facing up).
10. Push moderately hard to assure that all of the wires have reached the end of the connector. Be sure that the cable jacket goes into the back of the connector by about 3/16".
11. Place the connector into a crimp tool, and squeeze hard so that the handle reaches it's full swing.
12. Repeat the process on the other end. For a straight through cable, use the same wiring. For a "crossover" cable, wire one end 568A, and the other end 568B.
13. Use a cable tester to test for proper continuity.
7. Cut all of the wires at a perfect 90 degree angle from the cable at 1/2" from the end of the cable jacket. This is a very critical step. If the wires are not cut straight, they may not all make contact. We suggest using a pair of scissors for this purpose.
8. Conductors should be at a straight 90 degree angle, and be 1/2" long, prior to insertion into the connector.
9. Insert the wires into the connector (pins facing up).
10. Push moderately hard to assure that all of the wires have reached the end of the connector. Be sure that the cable jacket goes into the back of the connector by about 3/16".
11. Place the connector into a crimp tool, and squeeze hard so that the handle reaches it's full swing.
12. Repeat the process on the other end. For a straight through cable, use the same wiring. For a "crossover" cable, wire one end 568A, and the other end 568B.
13. Use a cable tester to test for proper continuity.
Optical Fiber Cable
Fiber-optic media (or optical-fiber,
or fibers, for short) are any network-transmission media that use glass, or in
some cases, plastic, fiber to transmit network data in the form of light
pulses. Within the last decade, fiber optics has become an increasingly popular
type of network transmission media.
Fiber Optic Cable
The
following advantages of fiber over other cabling systems explain why it is
currently enjoying popularity as a network-cabling medium:
- Immunity to electromagnetic interference (EMI)
- Higher data rates
- Longer maximum distances
- Better security
Type of Fiber
Once light enters an
optical fiber, it travels in a stable state called a mode. There can be from
one to hundreds of modes depending on the type of fiber. Each mode carries a portion
of the light from the input signal.
Generally speaking, the number of
modes in a fiber is a function of the relationship between core diameter,
numerical aperture, and wavelength. Every telecommunications fiber falls into
one of two categories: single-mode or multimode.
1) Single-mode
- allows
for only one pathway, or mode, of light to travel within the fiber. The core
size is typically 8.3 µm. Single-mode fibers are used in applications where low
signal loss and high data rates are required, such as on long spans where
repeater/amplifier spacing needs to be maximized.
Single Mode Fiber
2) Multimode
- allows
more than one mode of light. Common MM core sizes are 50 µm and 62.5 µm.
Multimode fiber is better suited for shorter distance applications. Where
costly electronics are heavily concentrated, the primary cost of the system
does not lie with the cable. In such a case, MM fiber is more economical
because it can be used with inexpensive connectors and LED transmitters, making
the total system cost lower. This makes MM fiber the ideal choice for short
distance, lower bandwidth applications.
Multi Mode Fiber
There
is a lot of connector that available for Fiber Optic:
Legend:
LC
- Lucent Connector
SC - Subscriber Connector
FC - Fix Connection
ST - Straight Tips
Connector
Coaxial Cable
Coaxial cables
may be rigid or flexible. Rigid types have a solid sheath, while flexible types
have a braided sheath, usually of thin copper wire. The inner insulator, also
called the dielectric, has a significant effect on the cable's properties, such
as its characteristic impedance and its attenuation. The dielectric may be
solid or perforated with air spaces. Connections to the ends of coaxial cables
are usually made with RF connectors.
Coaxial Cable
There is 2 type of coaxial cable that
is commonly used :
1) Thin coaxial cable – 2.5C 2V
(Speed Of 2Mbps)
2) Thick coaxial cable – 3C 2W
(Speed of 34Mbps)
Coaxial Connectors
There is a lot of coaxial
connector available at the market. 2 of the commonly used are:
1)
BNC (Bayonet Neill-Concelman) - type of RF connector used for
terminating coaxial cable.
 |
|
Female Connector
2) L-Shape Connector – Consist of Male
connector (used as a jumper on DDF) and Female connector (used at DDF to
connect with male jumper).
L-Shape Connector
Other Cable Connection
1) G.703
Cable - G.703
is a CCITT standard for transmitting voice over digital carriers such as T1 and
E1. G.703 provides the specifications for pulse code modulation (PCM) at data
rates from 64 Kbps to 2.048 Mbps. G.703 service is typically used for
interconnecting data communications equipment such as bridges, routers, and
multiplexers.
G.703 Cable
2) V.35
Cable - is
a high-speed serial interface designed to support both higher data rates and
connectivity between DTEs (data-terminal equipment) or DCEs (data-communication
equipment) over digital lines. V.35 is
connect to NT for a WAN connection.
There are 2
types of V.35 available at market:
·
V.35 (Serial Type)
V.35 (Serial Type)
·
V.35 (Smart Serial)
