Ethernet Cables
Copper & Fiber Patch Cables, Network Cables, Adapters, Network Equipment & Installation Products
Our company offers networking products, such as ethernet cables, connectors, cable
adapters, hubs, switches, routers, wall plates, media converters, WLAN and BlueTooth and print servers. If you are a dealer/reseller, installer or a corporate end-user please contact us for a quick quote, a free catalog or to find out more about our computer hardware products. We
have competitive prices and quality products. Our team in the US facility will help you choose the right products for your applications.
 Ethernet Patch Cables
UTP Category 5e Cables, UTP Category 6 Cables, FTP Category 5e Cables, FTP Halogen Free Cables
Fibre Optic 50/125 µm Cables, Fibre Optic 62.5/125 µm Cables
Network Cables (Bulk)
Connectors & Adapters
RJ-45 Connectors, RJ-45 Boots, Network Line Doubler, Couplers, Modular Adapters (Ser./RJ-45), BNC Connectors & Adapters
IP Surveillance / Remote Power Switching
Wall Plates
Network Hubs, Switches & Routers
Media Converters / Transceivers
WLAN & Bluetooth
Print Servers
To help our customers choose the right cables we offer below a comparison between Category
5, Category 5E, Category 6 and Category 7 Cables
Comparison between CAT5, CAT5e, CAT6, CAT7 Cables
In the context of the 100-ohm UTP (Unshielded Twisted Pair) type of cable used for Ethernet
wiring the only categories of interest are Cat3, Cat4, Cat5, Cat5e, Cat6, and Cat7. CATx is an abbreviation for the category number that defines the performance of building
telecommunications cabling as outlined by the Electronic Industries Association (EIA) standards. Some specifications for these categories are shown further down.
Up until the late 1980s thick or thin coaxial cable was typically used for 10-Mbps Ethernet
networks, but around that time, UTP cabling became more commonly used because it was easier to install and less expensive. UTP CAT3 and CAT4 were used for a quite limited time
since the emergence of 100Base-TX networks meant a quick shift to CAT5. By the year 2000, moves to gigabit (1000Base-TX) Ethernet LANs created a need for another specification,
CAT5e. CAT5e is now being superseded by CAT6 cable and there is a developing standard for CAT7.
Specifications for Cat3, Cat4, Cat5, Cat5e, Cat6, and Cat7 Cables
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Category
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Type
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Spectral B/W
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Length
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LAN Applications
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Notes
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Cat3
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UTP
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16 MHz
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100m
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10Base-T, 4Mbps
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Now mainly for telephone cables
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Cat4
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UTP
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20 MHz
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100m
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16Mbps
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Rarely seen
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Cat5
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UTP
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100MHz
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100m
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100Base-Tx,ATM, CDDI
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Common for current LANs
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Cat5e
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UTP
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100MHz
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100m
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1000Base-T
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Common for current LANs
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Cat6
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UTP
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250MHz
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100m
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Emerging
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Cat7
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ScTP
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600MHz
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100m
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It might seem that CAT5 and CAT5e are the same. Pretty much they are, the CAT5e
specification simply included some additional limits over the CAT5 specification. The reality is that most CAT5 cable is in fact CAT5e cable just not certified as such. Here is a comparison
of those extra specifications.
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CAT5, CAT5e, and CAT6 UTP Solid Cable Specifications Comparison
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Category 5
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Category 5e
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Category 6
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Frequency
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100 MHz
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100 MHz
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250 MHz
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Attenuation (Min. at 100 MHz)
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22 dB
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22 dB
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19.8 dB
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Characteristic Impedance
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100 ohms ± 15%
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100 ohms ± 15%
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100 ohms ± 15%
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NEXT (Min. at 100 MHz)
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32.3 dB
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35.3 dB
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44.3 dB
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PS-NEXT (Min. at 100 MHz)
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no specification
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32.3 dB
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42.3 dB
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ELFEXT (Min. at 100 MHz)
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no specification
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23.8 dB
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27.8 dB
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PS-ELFEXT (Min. at 100 MHz)
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no specification
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20.8 dB
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24.8 dB
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Return Loss (Min. at 100 MHz)
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16.0 dB
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20.1 dB
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20.1 dB
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Delay Skew (Max. per 100 m)
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no specification
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45 ns
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45 ns
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If you're cabling a mission critical system or you want your network to be future proof, go for
the CAT6 cables (and patch panels and connectors), but for the average home or small office network CAT5 or CAT5e will be just fine.
Crossover Cables vs Straight Through Cables
Ethernet patch cables can be wired in three different ways, the two main ways are called
straight through and crossover. The third type is called rolled and has only specialized applications.
Generally speaking, straight through cables are used to patch between different types of
equipment; for example, PCs to a hub.
Conversely, crossover cables are generally used to patch between similar types of equipment; a PC to another PC for example.
Some modern hubs don't care if you use crossover cables or straight through cables, they work out what you're using and configure themselves accordingly.
As stated at the outset, the actual difference is in the wiring. Inside the UTP patch cable there
are 8 physical wires although the network only uses 4 of them (the other 4 are simply wasted). The 8 wires are arranged in what's known as pairs and one pair is used to send information
whilst the other pair is used to receive information.
On a PC, the pair on pins 1 and 2 of the connector send information, whilst the pair on pins 3
and 6 receive the information. To make PCs talk to each we therefore need to connect the send pair of one PC to the receive pair of the other PC (and vice-a-versa). That means we
need a crossover cable. If we used a straight through cable the both be listening on the one pair - and hearing nothing, and sending on the one pair - achieving nothing.
Electrically, the straight through and crossover cables look like the diagram below: The most
common cable is the straight through cable. In a home or small office network you might only have one crossover cable used - perhaps from the cable or DSL modem to the distribution hub
. How do you tell what sort of cable you have in your hand? You can tell by looking at the connectors, identifying the wiring from its colors, and comparing the ends. See the next
question on color codes.
Color Codes
The standards say that Ethernet connectors should be cabled with specific colors on specific
pins. There are two standard layouts - if a cable has the same layout on both ends it's a straight through cable. If a cable has one layout on one end and the other layout on the other
end then it's a crossover cable. Whilst not universal, the color codes shown below are generally used on professional cables.
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If a cable has 568A color wiring on both ends then it's a straight through cable.
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If a cable has 568B color wiring on both ends then it's also a straight through cable.
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If a cable has 568A
color wiring on one end and 568B color coded wiring on the other end, then it's a crossover cable.
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In fact, while the colors are standardized and usually followed, that's not the important part.
What's more important is that one "pair" (wires that are twisted together inside the cable
sheath) is used for the transmit side and another pair for the receive side. If pairs aren't used
then it's likely your cable will not work. Pairs are identified by the colors. The orange wire and
the orange with white stripe (or sometimes white with orange stripe) wire are a pair. The brown wire and the brown with white stripe wire are a pair. Etc.
Network Cables vs Patch Cables
A short lead with connectors on either end which is flexible and is used to plug one piece of
equipment directly into another is generally referred to as a patch cable. To make them flexible, patch leads are generally made with stranded wire.
Cables with solid core wires are more often used in permanent wiring and terminate on wall
sockets and may be sometimes referred to as network cables . These cables aren't so flexible (and will break if repeatedly flexed).
Solid Core Cables vs Stranded Cables
Solid conductor uses 1 solid wire per conductor, so in a 4 pair (8 conductor) roll, there would
be a total of 8 solid wires. Stranded conductor uses multiple wires wrapped around each other
in each conductor, so in a 4 pair (8 conductor) 7 strand roll, there would be a total of 56 wires.
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