10BASE5

10BASE5 vampire tap Medium Attachment Unit (transceiver)

10BASE5 transceivers, cables, and tapping tool

10BASE5 (also known as thick Ethernet or thicknet) was the first commercially available variant of Ethernet. The technology was standardized in 1982^[1] as IEEE 802.3. 10BASE5 uses a thick and stiff coaxial cable^[2] up to 500 meters (1,600 ft) in length. Up to 100 stations can be connected to the cable using vampire taps and share a single collision domain with 10 Mbit/s of bandwidth shared among them. The system is difficult to install and maintain.

10BASE5 was superseded by much cheaper and more convenient alternatives: first by 10BASE2 based on a thinner coaxial cable (1985), and then, once Ethernet over twisted pair was developed, by 10BASE-T (1990) and its successors 100BASE-TX and 1000BASE-T. In 2003, the IEEE 802.3 working group deprecated 10BASE5 for new installations.^[3]

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Name origination

The name 10BASE5 is derived from several characteristics of the physical medium. The 10 refers to its transmission speed of 10 Mbit/s. The BASE is short for baseband signaling (as opposed to broadband^[a]), and the 5 stands for the maximum segment length of 500 meters (1,600 ft).^[4]

Network design and installation

For its physical layer 10BASE5 uses cable similar to RG-8/U coaxial cable but with extra braided shielding. This is a stiff, 0.375-inch (9.5 mm) diameter cable with an impedance of 50 ohms, a solid center conductor, a foam insulating filler, a shielding braid, and an outer jacket. The outer jacket is often yellow-to-orange fluorinated ethylene propylene (for fire resistance) so it often is called "yellow cable", "orange hose", or sometimes humorously "frozen yellow garden hose".^[5] 10BASE5 coaxial cables had a maximum length of 500 meters (1,600 ft). Up to 100 nodes could be connected to a 10BASE5 segment.^[6]

Transceiver nodes can be connected to cable segments with N connectors, or via a vampire tap, which allows new nodes to be added while existing connections are live. A vampire tap clamps onto the cable, a hole is drilled through the outer shielding, and a spike is forced to pierce the outer three layers and contact the inner conductor while other spikes bite into the outer braided shield. Care is required to keep the outer shield from touching the spike; installation kits include a "coring tool" to drill through the outer layers and a "braid pick" to clear stray pieces of the outer shield.

Transceivers should be installed only at precise 2.5-meter intervals. This distance was chosen to not correspond to the signal's wavelength; this ensures that the reflections from multiple taps are not in phase.^[7] These suitable points are marked on the cable with black bands. The cable is required to be one continuous run; T-connections are not allowed.

As is the case with most other high-speed buses, segments must be terminated at each end. For coaxial-cable-based Ethernet, each end of the cable has a 50 ohm resistor attached. Typically this resistor is built into a male N connector and attached to the cable's end just past the last device. With termination missing, or if there is a break in the cable, the signal on the bus will be reflected, rather than dissipated when it reaches the end. This reflected signal is indistinguishable from a collision and prevents communication.

Disadvantages

Adding new stations to the network is complicated by the need to pierce the cable accurately. The cable is stiff and difficult to bend around corners. One improper connection can take down the whole network and finding the source of the trouble is difficult.^[8]

Notes

^ The choice for broadband as the opposite is exemplified by Ethernet standards such as 10BROAD36. Later, the term broadband came to be used more commonly for different concepts, and the terms passband or modulated would be used to describe non-baseband signaling.

References

^ von Burg, Urs; Kenney, Martin (December 2003). "Sponsors, Communities, and Standards: Ethernet vs. Token Ring in the Local Area Networking Business" (PDF). Industry & Innovation. 10 (4): 351–375. doi:10.1080/1366271032000163621. Archived from the original (PDF) on December 6, 2011. Retrieved 17 February 2014.
^ Belden. "Product 9880" (PDF). catalog.belden.com. Belden. Retrieved April 8, 2023.
^ IEEE 802.3-2005 8. Medium attachment unit and baseband medium specifications, type 10BASE5
^ Stallings, William (1993). Local and Metropolitan Area Networks. Macmillan Publishing Company. pp. 107. ISBN 0-02-415465-2.
^ Mike Meyers (2004). All-in-One Networking+ Certification Exam Guide (3rd ed.). McGraw-Hill. p. 79.
^ "5-4-3 rule". Archived from the original on June 11, 2010. Retrieved June 30, 2010.
^ Technical Committee on Computer Communications of the IEEE Computer Society (1985), IEEE Standard 802.3-1985, IEEE, p. 121, ISBN 0-471-82749-5
^ Urd Von Burg; Martin Kenny (December 2003). "Sponsors, Communities, and Standards: Ethernet vs. Token Ring in the Local Area Networking Business" (PDF). Archived from the original (PDF) on June 18, 2012. Retrieved March 25, 2012.

v t e Ethernet family of local area network technologies
Speeds	10 Mbit/s 100 Mbit/s 1 Gbit/s 2.5 and 5 Gbit/s 10 Gbit/s 25 and 50 Gbit/s 40 and 100 Gbit/s 200, 400, 800 and 1600 Gbit/s
General	Physical layer Autonegotiation EtherType Flow control Frames Jumbos
Organizations	IEEE 802.3 Ethernet Alliance
Media	Twisted pair Coaxial First mile 10G-EPON
Historic	CSMA/CD StarLAN 10BROAD36 10BASE-FB 10BASE-FL 10BASE5 10BASE2 MAU FOIRL 100BaseVG LattisNet Long Reach
Applications	Audio Automotive Carrier Data center Energy Efficiency Industrial Metro Power Synchronous
Transceivers	GBIC SFP/SFP+/QSFP/QSFP+/OSFP XENPAK/X2 XFP CFP
Interfaces	AUI EAD MDI MII GMII XGMII XAUI
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This page was last edited on 23 April 2024, at 12:31

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