Fiber Optic Tech

Sharing various fiber optic news, inforamtion, topics, etc.

Guide to Twisted Pair Cabling

2016-08-29 17:47:03 | Copper Transceivers

Nowadays, fiber optic cable is a popular medium for both new cabling installations and upgrades, including backbone, horizontal, and even desktop applications. Although fiber offers various advantages over copper, copper still has a space in telecommunication networks, for example, direct attach copper cables, like HP JD096C 10G SFP+ direct attach copper cable or Cisco QSFP+ breakout cable (Cisco QSFP-4SFP10G-CU5M). The twisted pair cable has been widely deployed for telephone line networks ever since it was first developed in 1881. Today, it has already been extended worldwide mainly for outdoor land lines offering telephone voice services.

What Is Twisted Pair Cable

As a kind of copper wiring, twisted pair cable is made by putting two separate insulated wires together in a twisted pattern and running them parallel to each other. It is widely used in different kinds of data and voice infrastructures. To reduce crosstalk or electromagnetic induction between pairs of wires, two insulated copper wires are twisted around each other. Each connection on twisted pair requires both wires. Twisted pair can offset electromagnetic interference (EMI) from external sources to stop degrading the performance of circuit.

There are two twisted pair types: shielded and unshielded. A shielded twisted pair (STP) has a fine wire mesh surrounding the wires to protect the transmission; an unshielded twisted pair (UTP) does not. Shielded cable is used in older telephone networks, as well as network and data communications to reduce outside interference.

UTP vs STP

Different Categories of Twisted Pair Cabling

According to the standards, twisted pair cables can also be divided into various categories as Cat 1, Cat 2, Cat 3, Cat 4, Cat 5/5e, Cat 6/6a, Cat 7/7a, Cat 8/8.1/8.2 which will be introduced below.

  • Cat 5/5e Cat 5 twisted pair cable is often used for structured cabling of computer networks. It is available to 10/100 Mbps speeds at up to 100 MHz bandwidth. However, it is now considered to be obsolete and replaced by Cat 5e (enhanced). Cat 5e is one the most commonly used twisted pair cables now. The biggest distinction between Cat 5 and Cat 5e is that Cat 5e has a lower crosstalk and its transmitting speed can reach up to 1000 Mbps.
  • Cat 6/6a As a substitute of Cat 5/5e, Cat 6 twisted pair cable is applied to Gigabit Ethernet and other network physical layers. Cat 6 supports up to 10 Gbps speed at 250 MHz. When used for 10GBASE-T applications, Cat 6 has a reduced maximum length from 37 to 55 meters. Cat 6a (augmented) twisted pair cable has been evolved to perform at up to 500 MHz, thus the maximum cable distance is longer than Cat 6 of up to 100 meters.
  • Cat 7/7a Cat 7 is the standard for twisted pair cabling used for 1000BASE-T and 10GBASE-T networks. It provides performance of up to 600 MHz with a maximum length of 100 meters. Cat 7a (augmented) twisted pair cable has a higher frequency of 1000 MHz. Results show that Cat 7a may be possible to support 40 GbE or even 100 GbE at a very short length.
  • Cat 8/8.1/8.2 Cat 8 is the USA standard specified by ANSI/TIA while Cat 8.1 and Cat 8.2 are specified by ISO/IEC for global application. All these three kinds of Cat 8 twisted pair cables are used for 25GBASE-T and 40GBSE-T at the maximum frequency of up to 2 GHz. Except Cat 8 adopts Cat 8 links, Cat 8.1 uses class I links and Cat 8.2 uses class II links. The key difference between class I and class II is that class II allows three different styles of connectors that are not compatible with one another, or with the RJ45 connector.
Conclusion

When balancing the costs of the twisted pair cables with different grades or categories, you must keep in mind that higher categories are more expensive than lower ones, but most of the cost is actually spent on labor force for installing the cables. And twisted pair cables under Cat 5 are not recommended now. Higher categories are the trends for future network cabling.


コメントを投稿