Ethernet physical layer

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The Ethernet physical layer is the physical layer functionality of the Ethernet family of computer network standards. The physical layer defines the electrical or optical properties of the physical connection between a device and the network or between network devices. It is complemented by the MAC layer and the logical link layer.

The Ethernet physical layer has evolved over its existence starting in 1980 and encompasses multiple physical media interfaces and several orders of magnitude of speed from 1 Mbit/s to 400 Gbit/s. The physical medium ranges from bulky coaxial cable to twisted pair and optical fiber. In general, network protocol stack software will work similarly on all physical layers.

Many Ethernet adapters and switch ports support multiple speeds by using autonegotiation to set the speed and duplex for the best values supported by both connected devices. While this can practically be relied on for Ethernet over twisted pair, few optical-fiber ports support multiple speeds. If autonegotiation fails, some multiple-speed devices sense the speed used by their partner, but this may result in a duplex mismatch. With rare exceptions, a 100BASE-TX port (10/100) also supports 10BASE-T while a 1000BASE-T port (10/100/1000) also supports 10BASE-T and 100BASE-TX. A 10GBASE-T port often also supports 1000BASE-T.

10 Gigabit Ethernet was already used in both enterprise and carrier networks by 2007, with 40 Gbit/s and 100 Gigabit Ethernet ratified. In 2017, the fastest additions to the Ethernet family were 200 and 400 Gbit/s.

Video Ethernet physical layer

Naming conventions

Generally, layers are named by their specifications:

• 10, 100, 1000, 10G, ... - the nominal, usable speed at the top of the physical layer (no suffix = megabit/s, G = gigabit/s), excluding line codes but including other physical layer overhead (preamble, SFD, IPG); some WAN PHYs (W) run at slightly reduced bitrates for compatibility reasons; encoded PHY sublayers usually run at higher bitrates
• BASE, BROAD, PASS - indicates baseband, broadband, or passband signaling respectively
• -T, -S, -L, -E, -Z, -C, -K, -H ... - medium: T = twisted pair, S = 850 nm short wavelength (multi-mode fiber), L = 1300 nm long wavelength (mostly single-mode fiber), E or Z = 1500 nm extra long wavelength (single-mode), B = bidirectional fiber (mostly single-mode) using WDM, P = passive optical (PON), C = copper/twinax, K = backplane, 2 or 5 or 36 = coax with 185/500/3600 m reach (obsolete), F = fiber, various wavelengths, H = plastic optical fiber
• X, R - PCS encoding method (varying with the generation): X for 8b/10b block encoding (4B5B for Fast Ethernet), R for large block encoding (64b/66b)
• 1, 2, 4, 10 - for LAN PHYs indicates number of lanes used per link; for WAN PHYs indicates reach in kilometers

For 10 Mbit/s, no encoding is indicated as all variants use Manchester code. Most twisted pair layers use unique encoding, so most often just -T is used.

The reach, especially for optical connections, is defined as the maximum achievable link length that is guaranteed to work when all channel parameters are met (modal bandwidth, attenuation, insertion losses etc). With better channel parameters, often a longer, stable link length can be achieved. Vice versa, a link with worse channel parameters can also work but only over a shorter distance. Reach and maximum distance have the same meaning.

Maps Ethernet physical layer

Physical layers

The following sections provide a brief summary of official Ethernet media types. In addition to these official standards, many vendors have implemented proprietary media types for various reasons--often to support longer distances over fiber optic cabling.

Early implementations

Early Ethernet standards used Manchester coding so that the signal was self-clocking and not adversely affected by high-pass filters.

Fast Ethernet

All Fast Ethernet variants use a star topology.

1 Gbit/s

All Gigabit Ethernet variants use a star topology. Initially, half-duplex mode was included in the standard but has been abandoned since. Very few devices support gigabit speed in half-duplex.

2.5 and 5 Gbit/s

2.5GBASE-T and 5GBASE-T are scaled-down variants of 10GBASE-T. These physical layers support twisted pair copper cabling only.

10 Gbit/s

10 Gigabit Ethernet defines a version of Ethernet with a nominal data rate of 10 Gbit/s, ten times as fast as Gigabit Ethernet. In 2002, the first 10 Gigabit Ethernet standard was published as IEEE Std 802.3ae-2002. Subsequent standards encompass media types for single-mode fibre (long haul), multi-mode fibre (up to 400 m), copper backplane (up to 1 m) and copper twisted pair (up to 100 m). All 10-gigabit standards were consolidated into IEEE Std 802.3-2008. As of 2009, 10 Gigabit Ethernet is predominantly deployed in carrier networks, where 10GBASE-LR and 10GBASE-ER enjoy significant market shares.

25 Gbit/s

Single-lane 25-gigabit Ethernet is based on one 25.78125 GBd lane of the four from the 100 Gigabit Ethernet standard developed by task force P802.3by. 25GBASE-T over twisted pair was approved alongside 40GBASE-T within IEEE 802.3bq.

40 Gbit/s

This class of Ethernet was standardized in June 2010 as IEEE 802.3ba along with the first 100 Gbit/s generation, with an addition in March 2011 as IEEE 802.3bg, and the fastest yet twisted-pair standard in IEEE 802.3bq-2016. The nomenclature is as follows:

50 Gbit/s

The IEEE 802.3cd Task Force is currently developing 50 Gbit/s along with next-generation 100 and 200 Gbit/s standards using 50 Gbit/s lanes-

100 Gbit/s

The first generation of 100G Ethernet using 10 and 25 Gbit/s lanes was standardized in June 2010 as IEEE 802.3ba alongside 40 Gbit/s. The second generation using 50 Gbit/s lanes is currently being developed by the IEEE 802.3cd Task Force along with 50 and 200 Gbit/s standards. The third generation using a single 100 Gbit/s lane is currently being developed by the IEEE 802.3ck Task Force along with 200 and 400 Gbit/s PHYs and attachment unit interfaces (AUI) using 100 Gbit/s lanes.

200 Gbit/s

First generation 200 Gbit/s have been defined by the IEEE 802.3bs Task Force and standardized in 802.3bs-2017. The IEEE 802.3cd Task Force is currently developing 50 and next-generation 100 and 200 Gbit/s standards using one, two, or four 50 Gbit/s lanes respectively. The next generation using 100 Gbit/s lanes is currently being developed by the IEEE 802.3ck Task Force along with 100 and 400 Gbit/s PHYs and attachment unit interfaces (AUI) using 100 Gbit/s lanes.

400 Gbit/s and beyond

The Institute of Electrical and Electronic Engineers (IEEE) has defined a new Ethernet standard capable of 200 and 400 Gbit/s in IEEE 802.3bs-2017. 1 Tbit/s may be a further goal.

In May 2018, IEEE 802.3 started the 802.3ck Task Force to develop standards for 100, 200, and 400 Gbit/s PHYs and attachment unit interfaces (AUI) using 100 Gbit/s lanes.

In 2008, Robert Metcalfe, one of the co-inventors of Ethernet, said he believed commercial applications using Terabit Ethernet may occur by 2015, though it might require new Ethernet standards. It was predicted this would be followed rapidly by a scaling to 100 Terabit, possibly as early as 2020. It is worth noting that these were theoretical predictions of technological ability, rather than estimates of when such speeds would actually become available at a practical price point.

First mile

For providing Internet access service directly from providers to homes and small businesses:

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Sublayers

Starting with Fast Ethernet, the physical layer specifications are divided into three sublayers in order to simplify design and interoperability:

• PCS (Physical Coding Sublayer) - This sublayer performs auto-negotiation and basic encoding such as 8b/10b
• PMA (Physical Medium Attachment sublayer) - This sublayer performs PMA framing, octet synchronization/detection, and ${\displaystyle x^{7}+x^{6}+1}$ scrambling/descrambling
• PMD (Physical Medium Dependent sublayer) - This sublayer consists of a transceiver for the physical medium

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Twisted-pair cable

Several varieties of Ethernet were specifically designed to run over 4-pair copper structured cabling already installed in many locations. ANSI recommends using Category 6 cable for new installations.

In a departure from both 10BASE-T and 100BASE-TX, 1000BASE-T and above use all four cable pairs for simultaneous transmission in both directions through the use of echo cancellation.

Using point-to-point copper cabling provides the opportunity to transmit low electrical power along with the data. This is called Power over Ethernet and there are several, incremental IEEE 802.3 standards. Combining 10Base-T (or 100BASE-TX) with "IEEE 802.3af mode A" allows a hub or a switch to transmit both power and data over only two pairs. This was designed to leave the other two pairs free for analog telephone signals. The pins used in "IEEE 802.3af Mode B" supply power over the "spare" pairs not used by 10BASE-T and 100BASE-TX.

The cable requirements depend on the transmission speed and the employed encoding method. Generally, faster speeds require both higher-grade cables and more sophisticated encoding.

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Minimum cable lengths

Fiber connections have minimum cable lengths due to level requirements on received signals. Fiber ports designed for long-haul wavelengths require a signal attenuator if used within a building.

10BASE2 installations, running on RG-58 coaxial cable, require a minimum of 0.5 m between stations tapped into the network cable, this is to minimize reflections.

10BASE-T, 100BASE-T, and 1000BASE-T installations running on twisted pair cable use a star topology. No minimum cable length is required for these networks.

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Related standards

Some networking standards are not part of the IEEE 802.3 Ethernet standard, but support the Ethernet frame format, and are capable of interoperating with it.

• LattisNet--A SynOptics pre-standard twisted-pair 10 Mbit/s variant.
• 100BaseVG--An early contender for 100 Mbit/s Ethernet. It runs over Category 3 cabling. Uses four pairs. Commercial failure.
• TIA 100BASE-SX--Promoted by the Telecommunications Industry Association. 100BASE-SX is an alternative implementation of 100 Mbit/s Ethernet over fiber; it is incompatible with the official 100BASE-FX standard. Its main feature is interoperability with 10BASE-FL, supporting autonegotiation between 10 Mbit/s and 100 Mbit/s operation - a feature lacking in the official standards due to the use of differing LED wavelengths. It is targeted at the installed base of 10 Mbit/s fiber network installations.
• TIA 1000BASE-TX--Promoted by the Telecommunications Industry Association, it was a commercial failure, and no products exist. 1000BASE-TX uses a simpler protocol than the official 1000BASE-T standard so the electronics can be cheaper, but requires Category 6 cabling.
• G.hn--A standard developed by ITU-T and promoted by HomeGrid Forum for high-speed (up to 1 Gbit/s) local area networks over existing home wiring (coaxial cables, power lines and phone lines). G.hn defines an Application Protocol Convergence (APC) layer that accepts Ethernet frames and encapsulates them into G.hn MSDUs.

Other networking standards do not use the Ethernet frame format but can still be connected to Ethernet using MAC-based bridging.

• 802.11--Standards for wireless local area networks (LANs), sold with brand name Wi-Fi
• 802.16--Standards for wireless metropolitan area networks (MANs), sold with brand name WiMAX

Other special-purpose physical layers include Avionics Full-Duplex Switched Ethernet and TTEthernet -- Time-Triggered Ethernet for embedded systems.

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References

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External links

• Get IEEE 802.3
• IEEE 802.3
• How to make an Ethernet cable

Source of article : Wikipedia