Ethernet physical layer

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Ethernet physical layer
EthernetCableYellow3.jpg
A standard 8P8C (often called RJ45) connector used most commonly on category 5 cable, one of the types of cabling used in Ethernet networks
StandardIEEE 802.3 (1983 onwards)
Physical mediaCoaxial cable, twisted pair, optical fiber
Network topologyPoint-to-point, star, bus
Major variants 10BASE5, 10BASE2, 10BASE-T, 100BASE-TX, 1000BASE-T, 10GBASE-T
Maximum distance100 m (328 ft) over twisted pair, up to 100 km over optical fiber
Mode of operationdifferential (balanced), optical, single-ended
Maximum bit rate1 Mbit/s to 400 Gbit/s
Voltage levels± 2.5 V (over twisted pair)
Common connector types8P8C, LC, SC, ST

The physical-layer specifications of the Ethernet family of computer network standards are published by the Institute of Electrical and Electronics Engineers (IEEE), which defines the electrical or optical properties and the transfer speed 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. An implementation of a specific physical layer is commonly referred to as PHY.

Contents

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 with a standardized reach of up to 80 km. 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. If autonegotiation fails, some multiple-speed devices sense the speed used by their partner, [1] 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. Most 10GBASE-T ports also support 1000BASE-T, [2] some even 100BASE-TX or 10BASE-T. While autonegotiation can practically be relied on for Ethernet over twisted pair, few optical-fiber ports support multiple speeds. In any case, even multi-rate fiber interfaces only support a single wavelength (e.g. 850 nm for 1000BASE-SX or 10GBASE-SR).

10 Gigabit Ethernet was already used in both enterprise and carrier networks by 2007, with 40 Gbit/s [3] [4] and 100 Gigabit Ethernet [5] ratified. [6] In 2017, the fastest additions to the Ethernet family were 200 and 400 Gbit/s. [7] Development of 800 Gbit/s and 1.6 Tbit/s Ethernet standards started in 2021. [8]

Naming conventions

Generally, layers are named by their specifications: [9]

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.

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 reasonsoften to support longer distances over fiber optic cabling.

Early implementations and 10 Mbit/s

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

NameStandard (Clause)Common connectorsLink reachRequired cableDescription
Coaxial cable
Xerox experimental EthernetProprietary (1976) Vampire tap 1 km75  Ω coaxialThe original 2.94 Mbit/s Ethernet implementation had eight-bit addresses and other differences in frame format. [10]
10BASE5 802.3-1985 (8) AUI, N, vampire tap 500 mRG-8XOriginal standard uses a single coaxial cable in which a connection is made by tapping into the single cable, drilling in to make contact with the core and the screen. Largely obsolete, though due to its widespread deployment in the early 1980s, some systems may still be in use.[ citation needed ] Was known also as DIX Standard (pre 802.3) and later as Thick-Ethernet (in contrast to 10BASE2, thinnet). 10 Mbit/s over expensive RG-8X 50  Ω coaxial cabling, electrical bus topology with collision detection. Deprecated 2003.
10BASE2 802.3a-1985 (10) BNC, EAD/TAE-E 185 m RG-58 50 Ω coaxial cable connects machines together, each machine using a T-connector to connect to its NIC. Requires terminators at each end. For many years during the mid to late 1980, this was the dominant Ethernet standard. Also called Thin Ethernet, Thinnet or Cheapernet. 10 Mbit/s over RG-58 coaxial cabling, bus topology with collision detection. Deprecated 2011.
10BROAD36 802.3b-1985 (11) F 1800 m @VF0.87 [11] 75 Ω coaxialAn early standard supporting Ethernet over longer distances. It utilized broadband modulation techniques, similar to those employed in cable modem systems, and operated over coaxial cable. 10 Mbit/s, scrambled NRZ signaling modulated (PSK) over high-frequency carrier, broad bandwidth coaxial cabling, bus topology with collision detection. Deprecated 2003.
Twisted-pair cable
1BASE5 802.3e-1987 (12) 8P8C (IEC 60603-7)250 mvoice-gradeAlso called StarLAN. Operated at 1 Mbit/s over twisted pair to an active hub, star topology. Although a commercial failure, 1BASE5 pioneered the use of twisted-pair cabling and defined the architecture for all subsequent Ethernet evolution on that medium. Deprecated 2003.
StarLAN  10Proprietary (1988)8P8C100 mvoice-grade10 Mbit/s over copper twisted pair cabling, star topology evolved into 10BASE-T
LattisNet UTPProprietary (1987)8P8C100 mvoice-grade10 Mbit/s over copper twisted pair cabling, star topology evolved into 10BASE-T
10BASE-T 802.3i-1990 (14)8P8C (IEC 60603-7)100 m Cat-3 Runs over four wires (two twisted pairs). A repeater hub or switch sits in the middle and has a port for each node. This is also the configuration used for 100BASE-T. Copper twisted pair cabling, star topology direct evolution of 1BASE-5. As of 2024, still widely supported.
10BASE-Te 802.3az-2010 (14)100 m Cat-5 Energy-efficient Ethernet variant of 10BASE-T using a reduced amplitude signal over Category 5 cable, completely interoperable with 10BASE-T nodes.
10BASE-T1L 802.3cg-2019 (146)IEC 63171-1, IEC 63171-61000 mEthernet over a single twisted pair - long reach, for industrial applications
10BASE-T1S 802.3cg-2019 (147)25 mEthernet over a single twisted pair - short reach, for automotive applications, including PoDL
Fiber-optical cable
FOIRL 802.3d-1987 (9.9) ST 1000 mFDDI-style MMF Fiber-optic inter-repeater link; the original standard for Ethernet over fiber, superseded by 10BASE-FL, deprecated 2011
10BASE-F802.3j-1993 (15)A generic term for the family of 10 Mbit/s Ethernet standards using fiber optic cable: 10BASE-FL , 10BASE-FB and 10BASE-FP. Of these only 10BASE-FL gained widespread use. 10 Mbit/s over fiber pair
10BASE-FL 802.3j-1993 (15&18)ST2000 mFDDI-style MMFAn updated version of the FOIRL standard for end nodes, 2 km reach over FDDI-style multi-mode fiber, 850 nm wavelength
10BASE-FB 802.3j-1993 (15&17)2000 mIntended for backbones connecting a number of hubs or switches as a direct successor to FOIRL; deprecated 2011. [12]
10BASE‑FP 802.3j-1993 (15&16)1000 mA passive star network that required no repeater, it was never implemented. [12] Deprecated 2003.

100 Mbit/s

All Fast Ethernet variants use a star topology and generally use 4B5B line coding.

NameStandard (Clause)Common connectorsDescription
Twisted-pair cable
100BASE‑T802.3u-1995 (21)A term for any of the three standards for 100 Mbit/s Ethernet over twisted pair cable. Includes 100BASE-TX, 100BASE-T4 and 100BASE-T2. As of 2009, 100BASE-TX has totally dominated the market, and may be considered synonymous with 100BASE-T in informal usage.
100BASE-TX 802.3u-1995 (24, 25)8P8C (FDDI TP-PMD standard, ANSI INCITS 263-1995)4B5B MLT-3 coded signaling, Category 5 cable using two twisted pairs. The specifications are largely borrowed from FDDI's TP-PMD. [13] As of 2018, still very popular.
100BASE-T4 802.3u-1995 (23)8P8C (IEC 60603-7) 8B6T PAM-3 coded signaling, Category 3 cable (as used for 10BASE-T installations) using four twisted pairs. Limited to half-duplex. Deprecated 2003.
100BASE-T2 802.3y-1998 (32)8P8C (IEC 60603-7)PAM-5 coded signaling, CAT3 copper cabling with two twisted pairs, star topology. Supports full-duplex. It is functionally equivalent to 100BASE-TX, but supports old telephone cable. However, special sophisticated digital signal processors are required to handle the encoding schemes it uses, making this option fairly expensive at the time. It arrived well after 100BASE-TX was established in the market. 100BASE-T2 and 100BASE-T4 were not widely adopted but some of the technology developed for them is used in 1000BASE-T. [12] Deprecated 2003.
100BASE-T1 802.3bw-2015 (96)none specifiedUses PAM-3 modulation at 66.7  MBd over a single, bi-directional twisted pair of up to 15 m; three bits are encoded as two ternary symbols. It is intended for automotive applications.
100BaseVG 802.12-19948P8CStandardized by a different IEEE 802 subgroup, 802.12, because it used a different, more centralized form of media access (demand priority). Proposed by Hewlett-Packard. Inherently half-duplex, it needed four pairs in a Cat-3 cable. Now obsolete, the standard has been withdrawn in 2001.
HDMI Ethernet Channel HDMI 1.4 (2009)HDMIHEC uses a hybrid to mix and separate 100BASE-TX's transmit and receive signals through a single twisted pair.
Fiber-optical cable
100BASE‑FX 802.3u-1995 (24, 26)ST, SC 4B5B NRZI coded signaling, two strands of multi-mode optical fiber using 1300 nm wavelength. Maximum length is 400 meters for half-duplex connections (to ensure collisions are detected) or 2 kilometers for full-duplex. The specifications are largely borrowed from FDDI.
100BASE‑SX TIA-785 (2000)ST, SC100 Mbit/s Ethernet over multi-mode fiber. Maximum length is 300 meters. 100BASE-SX used short wavelength (850 nm) optics that was sharable with 10BASE-FL, thus making an autonegotiation scheme possible with 10/100 fiber adapters.
100BASE‑BX10 802.3ah-2004 (58, 66)ST, SC, LC 100 Mbit/s Ethernet bidirectionally over a single strand of single-mode optical fiber. An optical multiplexer is used to split transmit and receive signals into different wavelengths (1530 and 1310 nm) allowing them to share the same fiber. Supports up to 10 km, full-duplex only. [14]
100BASE-LX10 802.3ah-2004 (58)ST, SC, LC100 Mbit/s Ethernet up to 10 km over a pair of single-mode fibers, using 1310 wavelength, full-duplex only. [14]

1 Gbit/s

All Gigabit Ethernet variants use a star topology. 1000BASE-X variants use 8b/10b PCS encoding. Initially, half-duplex mode was included in the standard but has since been abandoned. [15] Very few devices support gigabit speed in half-duplex.

NameStandard (Clause)Common connectorsDescription
Twisted-pair cable
1000BASE-T 802.3ab-1999 (40)8P8C (IEC 60603-7) PAM-5 coded signaling, at least Category 5 cable, with Category 5e strongly recommended copper cabling with four twisted pairs. Each pair is used in both directions simultaneously. Extremely wide adoption.
1000BASE-T1 802.3bp-2016 (97)none specifiedUses a single, bi-directional twisted pair in full duplex mode only; cables specified for a reach of 15 m (automotive link segment) or 40 m (optional link segment), intended for automotive and industrial applications; it uses 80B/81B encoding in the PCS, PAM-3 signalling at 750 MBd (three bits transmitted as two ternary symbols) and includes Reed–Solomon error correction.
1000BASE-TX TIA-854 (2001)8P8C (IEC 60603-7) Category 6 cable required. Unimplemented, withdrawn.
Fiber-optic cable
1000BASE-SX 802.3z-1998 (38)ST, SC, LC 8b/10b NRZ coded signaling on 850 nm carrier, short-range multi-mode fiber (up to 550 m).
1000BASE-LX 802.3z-1998 (38)SC, LC8b/10b NRZ coded signaling on 1310 nm carrier, multi-mode fiber (up to 550 m) or single-mode fiber of up to 5 km; most current implementations are actually 1000BASE-LX10 with 10 km reach
1000BASE-BX10 802.3ah-2004 (59)SC, LCup to 10 km on 1490 and 1310 nm carriers; bidirectional over single strand of single-mode fiber; often called just 1000BASE-BX
1000BASE-LX10 802.3ah-2004 (59)SC, LCidentical to 1000BASE-LX but increased power and sensitivity for up to 10 km over a pair of single-mode fiber; commonly called just 1000BASE-LX or, prior to 802.3ah, 1000BASE-LH; vendor-specific extensions exist for up to 40 km reach
1000BASE‑PX10‑D802.3ah-2004 (60)SC, LCdownstream (from head-end to tail-ends) over single-mode fiber using point-to-multipoint topology (supports at least 10 km).
1000BASE‑PX10‑U802.3ah-2004 (60)upstream (from a tail-end to the head-end) over single-mode fiber using point-to-multipoint topology (supports at least 10 km).
1000BASE‑PX20‑D802.3ah-2004 (60)downstream (from head-end to tail-ends) over single-mode fiber using point-to-multipoint topology (supports at least 20 km).
1000BASE‑PX20‑U802.3ah-2004 (60)upstream (from a tail-end to the head-end) over single-mode fiber using point-to-multipoint topology (supports at least 20 km).
1000BASE-EX
1000BASE-ZX
multi-vendorSC, LCup to 40 or 100 km over single-mode fiber on 1550 nm carrier [16]
Other
SFP INF-8074i (2001)SFPnot a complete PHY in its own right but highly popular for adding modular transceivers; single lane, usually 1.25 Gbit/s
1000BASE-CX 802.3z-1998 (39) DE-9, FC style-2/IEC 61076-3-103, CX4/SFF-84708b/10b NRZ coded signaling over up to 25 m shielded, balanced copper cable (150 Ω). Predates 1000BASE-T and is rarely used.
1000BASE‑KX802.3ap-2007 (70)1 m over backplane
1000BASE-RHA
1000BASE-RHB
1000BASE-RHC
802.3bv-2017 (115)RHA: clamping fixture
RHB/RHC: none specified
1000BASE-RHA, -RHB, -RHC run over up to 50, 40, and 15 m of duplex plastic optical fiber (POF) using ~650 nm wavelength, 64b/65b encoding, and PAM16 symbols at 325 MBd; intended for home, industrial and automotive use, respectively

2.5 and 5 Gbit/s

2.5GBASE-T and 5GBASE-T are scaled-down variants of 10GBASE-T and provide longer reach over pre-Cat 6A cabling. These physical layers support twisted-pair copper cabling and backplanes only.

NameStandard (Clause)Common connectorsDescription
Twisted-pair cable
2.5GBASE-T 802.3bz-2016 (126)8P8C IEC 60603-7-4 (unscreened) or IEC 60603-7-5 (screened)100 m of Cat 5e
5GBASE-T 100 m of Cat 6
2.5GBASE-T1802.3ch-2020 (149)use a single, bi-directional twisted pair in full duplex mode only, intended for automotive and industrial applications
5GBASE-T1
Fiber-optical cable
2.5GBASE-AU802.3cz-2023 (166)undefinedup to 40 m of OM3 for automotive
5GBASE-AUup to 40 m of OM3 for automotive
Other
2.5GBASE-KX802.3cb-2018 (128)2.5 Gbit/s over 1 m of backplane, upscaled 1000BASE-KX
5GBASE-KR802.3cb-2018 (130)5 Gbit/s over 1 m of backplane, downscaled 10GBASE-KR

10 Gbit/s

10 Gigabit Ethernet is a version of Ethernet with a nominal data rate of 10 Gbit/s, ten times as fast as Gigabit Ethernet. The first 10 Gigabit Ethernet standard, IEEE Std 802.3ae-2002, was published in 2002. Subsequent standards encompass media types for single-mode fiber (long haul), multi-mode fiber (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. Most 10-gigabit variants use 64b/66b PCS code (-R). 10 Gigabit Ethernet, specifically 10GBASE-LR and 10GBASE-ER, enjoys significant market shares in carrier networks.

NameStandard (Clause)Common connectorsDescription
Twisted-pair cable
10GBASE-T 802.3an-2006 (55)8P8C (IEC 60603-7-4 (unscreened) or IEC 60603-7-5 (screened))Uses Cat 6A twisted-pair wiring, four lanes at 800 MBd each, PAM-16 with DSQ128 line code
10GBASE-T1802.3ch-2020 (149)Uses a single, bi-directional twisted pair in full duplex mode only, intended for automotive and industrial applications
Fiber-optical cable
10GBASE-SR 802.3ae-2002 (52)SC, LCDesigned to support short distances over deployed multi-mode fiber cabling using 850 nm wavelength; it has a range of between 26 m and 400 m depending on cable type (modal bandwidth:reach: 160 MHz·km(FDDI):26 m, 200 MHz·km(OM1):33 m, 400 MHz·km:66 m, 500 MHz·km(OM2):82 m, 2000 MHz·km(>OM3):300 m, 4700 MHz·km(>OM4):400 m) [17]
10GBASE-LX4 802.3ae-2002 (53)SC, LCUses four 8b/10b lanes with wavelength division multiplexing (1275, 1300, 1325, and 1350 nm) over deployed/legacy multi-mode cabling to support ranges of between 240 m and 300 m (400/500 MHz·km modal bandwidth). Also supports 10 km over single-mode fiber.
10GBASE-LR 802.3ae-2002 (52)SC, LCSupports 10 km over single-mode fiber using 1,310 nm wavelength
10GBASE-ER 802.3ae-2002 (52)SC, LCSupports 30 km over single-mode fiber using 1,550 nm wavelength (40 km over engineered links)
10GBASE-ZR Multi-vendorSC, LCOffered by various vendors; supports 80 km or more over single-mode fiber using 1,550 nm wavelength
10GBASE-SW 802.3ae-2002 (52)A variation of 10GBASE-SR with 9.58464 Gbit/s, designed to be mapped directly as OC-192/STM-64 SONET/SDH streams (850 nm wavelength)
10GBASE-LW 802.3ae-2002 (52)A variation of 10GBASE-LR with 9.58464 Gbit/s, designed to be mapped directly as OC-192/STM-64 SONET/SDH streams (1,310 nm wavelength)
10GBASE-EW 802.3ae-2002 (52)A variation of 10GBASE-ER with 9.58464 Gbit/s, designed to be mapped directly as OC-192/STM-64 SONET/SDH streams (1,550 nm wavelength)
10GBASE-LRM 802.3aq-2006 (68)SC, LCUp to 220 m over deployed 500  MHz·km multi-mode fiber (1,310 nm wavelength)
10GBASE-PR 802.3av-2009 (75)Providing P2MP 10 Gbit/s Ethernet links over PONs, at the distance of 10 or 20 km.
10GBASE-BR10
10GBASE-BR20
10GBASE-BR40
802.3cp-2021 (158)SC, LCbidirectional over a single strand of single-mode fiber for up to 10, 20 or 40 km using 1330 (-D; OLT→ONU) and 1270 nm (-U; ONU→OLT) wavelengths; pre-standard variants offered by various vendors, often called 10GBASE-BX or BiDi
10GBASE-AU802.3cz-2023 (166)undefinedup to 40 m of OM3 for automotive
Other
10GBASE-CX4 802.3ak-2004 (54)CX4/SFF-8470/IEC 61076-3-113Designed to support short distances over copper cabling, it uses InfiniBand 4x connectors and CX4 twinaxial cabling and allows a cable length of up to 15 m. Was specified in IEEE 802.3ak-2004 which has been incorporated into IEEE 802.3-2008. Shipping has all but stopped in favor of 10GBASE-T and SFP+ direct attach.
10GBASE-KX4 802.3ap-2007 (71)1 m over 4 lanes of backplane
10GBASE-KR 802.3ap-2007 (72)1 m over a single lane of backplane
10GPASS-XR802.3bn-2016 (100–102) EPON Protocol over Coax (EPoC) – up to 10 Gbit/s downstream and 1.6 Gbit/s upstream for a passive optical, point-to-multipoint network using passband OFDM with up to 16384-QAM
SFP+ direct attach SFF-8431 (2009) SFP+ Up to 7 m using passive twinaxial cables, up to 15 m using active cables, or up to 100 m using active optical cables (AOC); single lane, usually 10.3125 Gbit/s

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 the P802.3by task force. [18] 25GBASE-T over twisted pair was approved alongside 40GBASE-T within IEEE 802.3bq. [19] [20]

NameStandard (Clause)Common connectorsDescription
Twisted-pair cable
25GBASE-T802.3bq-2016 (113)8P8C (IEC 60603-7-51 and IEC 60603-7-81, 2000 MHz)Scaled-down version of 40GBASE-T – up to 30 m Category 8 or ISO/IEC TR 11801-9905 [B1] cabling
Fiber-optical cable
25GBASE-SR802.3by-2016 (112)LC, SC850 nm over multi-mode cabling with 100 m (OM4) or 70 m (OM3) reach
25GBASE-EPON
Nx25-EPON
802.3ca-2020 (141)Providing P2MP 25 Gbit/s Ethernet links over PONs, at a distance of at least 20 km.
25GBASE-LR802.3cc-2017 (114)LC, SC1310 nm over single-mode cabling with 10 km reach
25GBASE-ER802.3cc-2017 (114)LC, SC1300 nm over single-mode cabling with 30 km reach (40 km over engineered links)
25GBASE-BR10
25GBASE-BR20
25GBASE-BR40
802.3cp-2021 (159)SC, LCbidirectional over a single strand of single-mode fiber for up to 10, 20 or 40 km using 1330 (-D; OLT→ONU) and 1270 nm (-U; ONU→OLT) wavelengths for -BR10, or 1314/1290 nm wavelengths for -BR20 and -BR40
25GBASE-AU802.3cz-2023 (166)undefinedup to 40 m of OM3 for automotive
Other
25GBASE-CR
25GBASE-CR-S
802.3by-2016 (110)SFP28 (SFF-8402/SFF-8432)Direct-attach cable (DAC) over twinaxial cabling with 3 m (-CR-S) and 5 m (-CR-L) reach
25GBASE-KR
25GBASE-KR-S
802.3by-2016 (111)For printed-circuit backplane, derived from 100GBASE-KR4
SFP28 SFF-8402 (2014)SFP28Popular for adding modular transceivers

40 Gbit/s

This class of Ethernet was standardized in June 2010 as IEEE 802.3ba. The work also included the first 100 Gbit/s generation, published in March 2011 as IEEE 802.3bg. [21] [22] A 40 Gbit/s twisted-pair standard was published in 2016 as IEEE 802.3bq-2016.

Name [23] Standard (Clause)Common connectorsDescription
Twisted-pair cable
40GBASE-T 802.3bq-2016 (113)8P8C (IEC 60603-7-51 and IEC 60603-7-81, 2000 MHz)Requires Category 8 cabling, up to 30 m
Fiber-optical cable
40GBASE-SR4 802.3ba-2010 (86) MPO At least 100 m over 2000  MHz·km multi-mode fiber (OM3) at least 150 m over 4700  MHz·km multi-mode fiber (OM4)
40GBASE-LR4 802.3ba-2010 (87)SC, LCAt least 10 km over single-mode fiber, CWDM with 4 lanes using 1270, 1290, 1310 and 1330 nm wavelength
40GBASE-ER4 802.3ba-2010 (87)SC, LCAt least 30 km over single-mode fiber, CWDM with 4 lanes using 1270, 1290, 1310 and 1330 nm wavelength (40 km over engineered links)
40GBASE-FR 802.3bg-2011 (89)SC, LCSingle lane, single-mode fiber over 2 km, 1550 nm wavelength
Other
40GBASE-KR4 802.3ba-2010 (84)At least 1 m over a backplane
40GBASE-CR4 802.3ba-2010 (85)QSFP+ (SFF-8436)Up to 7 m over twinaxial copper cable assembly (4 lanes, 10 Gbit/s each)

50 Gbit/s

The IEEE 802.3cd task force developed 50 Gbit/s along with next-generation 100 and 200 Gbit/s standards using 50 Gbit/s lanes. [24]

NameStandard (Clause)Common connectorsDescription
Fiber-optical cable
50GBASE-SR802.3cd-2018 (138)LC, SC100 m over OM4 multi-mode fiber using PAM-4 at 26.5625 GBd, 70 m over OM3
50GBASE-FR802.3cd-2018 (139)LC, SC2 km over single-mode fiber using PAM-4
50GBASE-LR802.3cd-2018 (139)LC, SC10 km over single-mode fiber using PAM-4
50GBASE-ER802.3cd-2018 (139)LC, SC30 km over single-mode fiber using PAM-4, 40 km over engineered links
50GBASE-BR10
50GBASE-BR20
50GBASE-BR40
802.3cp-2021 (160)SC, LCbidirectional over a single strand of single-mode fiber for up to 10, 20 or 40 km using 1330 (-D; OLT→ONU) and 1270 nm (-U; ONU→OLT) wavelengths for -BR10, or 1314/1290&nm wavelengths for -BR20 and -BR40
50GBASE-AU802.3cz-2023 (166)undefinedup to 40 m of OM3 for automotive
Other
50GBASE-CR802.3cd-2018 (136)SFP28, QSFP28, microQSFP, QSFP-DD, OSFP3 m over twinaxial cable
50GBASE-KR802.3cd-2018 (137)Printed-circuit backplane, consistent with 802.3bs Clause 124

100 Gbit/s

The first generation of 100 Gigabit Ethernet using 10 and 25 Gbit/s lanes was standardized in June 2010 as IEEE 802.3ba alongside 40 Gigabit Ethernet. [21] The second generation using 50 Gbit/s lanes was developed by the IEEE 802.3cd task force along with 50 and 200 Gbit/s standards. [24] The third generation using a single 100 Gbit/s lane was standardized in September 2022 as IEEE 802.3ck along with 200 and 400 Gbit/s Ethernet. [25] [26]

NameStandard (Clause)Common connectorsDescription
Fiber-optical cable
100GBASE-SR10 802.3ba-2010 (86)MPOAt least 100 m over 2000  MHz·km multi-mode fiber (OM3), at least 150 m over 4700  MHz·km multi-mode fiber (OM4)
100GBASE-SR4 802.3bm-2015 (95)MPO4 lanes, at least 70 m over 2000  MHz·km multi-mode fiber (OM3), at least 100 m over 4700  MHz·km multi-mode fiber (OM4)
100GBASE-SR2802.3cd-2018 (138)MPOTwo 50 Gbit/s lanes using PAM-4 at 26.5625 GBd over OM4 multi-mode fiber with 100 m reach, 70 m over OM3, using RS-FEC(544,514) (Clause 91)
100GBASE-LR4 802.3ba-2010 (88)SC, LCAt least 10 km over single-mode fiber, DWDM with 4 lanes using 1296, 1300, 1305 and 1310 nm wavelength
100GBASE-ER4 802.3ba-2010 (88)SC, LCAt least 30 km over single-mode fiber, DWDM with 4 lanes using 1296, 1300, 1305 and 1310 nm wavelength (40 km over engineered links)
100GBASE-DR 802.3cu-2021 (140)LC, SCAt least 500 m over single-mode fiber using a single lane, using RS-FEC and PAM4, 1310 nm wavelength
100GBASE-FR1 At least 2 km over single-mode fiber using a single lane, using RS-FEC and PAM4, 1310 nm wavelength
100GBASE-LR1 At least 10 km over single-mode fiber using a single lane, using RS-FEC and PAM4, 1310 nm wavelength
100GBASE-ZR 802.3ct-2021 (153 & 154)At least 80 km over single-mode fiber using a single wavelength over a DWDM system, also forming the base for 200GBASE-ZR and 400GBASE-ZR
Other
100GBASE-CR10 802.3ba-2010 (85)CXP10 (SFF-8642)Up to 7 m over twinaxial copper cable assembly (10 lanes, 10 Gbit/s each)
100GBASE-CR4 802.3bj-2014 (92)QSFP28 4X (SFF-8665)Up to 5 m over twinaxial copper cable assembly (4 lanes, 25 Gbit/s each)
100GBASE-CR2802.3cd-2018 (136)QSFP28, microQSFP, QSFP-DD, OSFPOver twinaxial cable with 3 m reach (two 50 Gbit/s lanes), using RS-FEC
100GBASE-CR1802.3ck-2022 (162)Single-lane over twin-axial copper with at least 2 m reach
100GBASE-KR4 802.3bj-2014 (93)Four lanes 25 Gbit/s each over a backplane
100GBASE-KR2802.3cd-2018 (137)Two 50 Gbit/s lanes over printed-circuit backplane, consistent with 802.3bs Clause 124, using RS-FEC
100GBASE-KR1802.3ck-2022 (163)Single-lane over electrical backplanes supporting an insertion loss of up to 28 dB at 26.5625 GBd
100GBASE-KP4 802.3bj-2014 (94)Using PAM4 modulation on four lanes 12.5 GBd each over a backplane, using RS-FEC

200 Gbit/s

First generation 200 Gbit/s have been defined by the IEEE 802.3bs task force and standardized in 802.3bs-2017. [27] The IEEE 802.3cd task force has developed 50 and next-generation 100 and 200 Gbit/s standards using one, two, or four 50 Gbit/s lanes respectively. [24] The next generation using 100 Gbit/s lanes was standardized in September 2022 as IEEE 802.3ck along with 100 and 400 Gbit/s PHYs and attachment unit interfaces (AUI) using 100 Gbit/s lanes. [25] [26]

NameStandard (Clause)Common connectorsDescription
Fiber-optical cable
200GBASE-DR4802.3bs-2017 (121)MPOFour PAM-4 lanes (26.5625 GBd) using individual strands of single-mode fiber with 500 m reach (1310 nm)
200GBASE-FR4802.3bs-2017 (122)SC, LCFour PAM-4 lanes (26.5625 GBd) using four wavelengths (CWDM) over single-mode fiber with 2 km reach (1270/1290/1310/1330 nm)
200GBASE-LR4802.3bs-2017 (122)SC, LCFour PAM-4 lanes (26.5625 GBd) using four wavelengths (DWDM, 1296/1300/1305/1309 nm) over single-mode fiber with 10 km reach
200GBASE-SR4802.3cd-2018 (138)MPOFour PAM-4 lanes at 26.5625 GBd each over OM4 multi-mode fiber with 100 m reach, 70 m over OM3
200GBASE-ER4802.3cn-2019 (122)Four-lane using four wavelengths (DWDM, 1296/1300/1305/1309 nm) over single-mode fiber with 30 km reach, 40 km over engineered links
TBD802.3dfsingle-pair single-mode fiber with 500 m reach
TBDsingle-pair single-mode fiber with 2 km reach
Other
200GBASE-CR4802.3cd-2018 (136)QSFP28, microQSFP, QSFP-DD, OSFPFour PAM-4 lanes (26.5625 GBd) over twinaxial cable with 3 m reach
200GBASE-KR4802.3cd-2018 (137)Four PAM-4 lanes (26.5625 GBd) over printed-circuit backplane, consistent with 802.3bs Clause 124
200GBASE-CR2802.3ck-2022 (162)Two-lane over twin-axial copper with at least 2 m reach
200GBASE-KR2802.3ck-2022 (163)Two-lane over electrical backplanes supporting an insertion loss of up to 28 dB at 26.56 GBd
TBD802.3dfsingle-pair twinaxial cable with 1 m reach

400 Gbit/s

An Ethernet standard capable of 200 and 400 Gbit/s is defined in IEEE 802.3bs-2017. [27] 1 Tbit/s may be a further goal. [28]

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. [25] The new standards were approved in September 2022. [26]

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. [29] It was predicted this would be followed rapidly by a scaling to 100 Terabit, possibly as early as 2020. These were theoretical predictions of technological ability, rather than estimates of when such speeds would actually become available at a practical price point. [30]

NameStandard (Clause)Common connectorsDescription
Fiber-optical cable
400GBASE-SR16802.3bs-2017 (123)MPO-32Sixteen lanes (26.5625 Gbit/s) using individual strands of OM4/OM5 multi-mode fiber with 100 m reach or 70 m over OM3
400GBASE-DR4802.3bs-2017 (124)MPOFour PAM-4 lanes (53.125 GBd) using individual strands of single-mode fiber with 500 m reach (1310 nm)
400GBASE-FR8802.3bs-2017 (122)SC, LCEight PAM-4 lanes (26.5625 GBd) using eight wavelengths (CWDM) over single-mode fiber with 2 km reach
400GBASE-LR8802.3bs-2017 (122)SC, LCEight PAM-4 lanes (26.5625 GBd) using eight wavelengths (DWDM) over single-mode fiber with 10 km reach
400GBASE-FR4802.3cu-2021 (151)SC, LCFour lanes/wavelengths (CWDM, 1271/1291/1311/1331 nm) over single-mode fiber with 2 km reach, using PAM4
400GBASE-LR4-6Four lanes/wavelengths (CWDM, 1271/1291/1311/1331 nm) over single-mode fiber with 6 km reach, using PAM4
400GBASE-SR8802.3cm-2020 (138)MPO-24, MPO-16Eight-lane using individual strands of multi-mode fiber with 100 m reach
400GBASE-SR4.2802.3cm-2020 (150)MPO-12Eight-lane using four multi-mode fiber pairs and two wavelengths (850 and 910 nm) with 70/100/150 m reach over OM3/OM4/OM5 respectively
400GBASE-ER8802.3cn-2019 (122)SC, LCEight-lane using eight wavelengths over single-mode fiber with 40 km reach
400GBASE-ZR 802.3cw (155 & 156)SC, LCAt least 80 km over single-mode fiber using a single wavelength with 16QAM over a DWDM system
TBD802.3dftwo pairs of single-mode fiber with 500 m reach
Other
400GBASE-CR4802.3ck-2022 (162)Four-lane over twin-axial copper with at least 2 m reach
400GBASE-KR4802.3ck-2022 (163)Four-lane over electrical backplanes supporting an insertion loss of up to 28 dB at 26.56 GBd
TBD802.3dftwo pairs of twin-axial copper with 1 m reach

800 Gbit/s

The Ethernet Technology Consortium proposed an 800 Gbit/s Ethernet PCS variant based on tightly bundled 400GBASE-R in April 2020. [31]

In December 2021, IEEE started the P802.3df Task Force to define variants for 800 and 1600 Gbit/s over twinaxial copper, electrical backplanes, single-mode and multi-mode optical fiber along with new 200 and 400 Gbit/s variants using 100 and 200 Gbit/s lanes. [32]

NameStandard (Clause)Common connectorsDescription
Fiber-optical cable
TBD802.3dfeight pairs of multi-mode fiber for 50 m reach
TBDeight pairs of multi-mode fiber for 100 m reach
TBDeight pairs of single-mode fiber for 500 m reach
TBDeight pairs of single-mode fiber for 2 km reach
TBDfour pairs of single-mode fiber for 500 m reach
TBDfour pairs of single-mode fiber for 2 km reach
TBDusing four wavelengths (WDM) over a single strand of SMF for 2 km reach
TBDusing a single strand of SMF for 10 km reach
TBDusing a single strand of SMF for 40 km reach
Other
TBD802.3dffour twinax pairs for 1 m reach
TBDeight lanes over twinax for 2 m reach
TBDeight lanes over electrical backplane
800GBASE-RAs of April 2020, the PCS and PMA sublayers seem to be defined, using eight lanes of 100 Gbit/s each, and connecting with the transceiver module through a C2M or C2C interface defined in 802.3ck. [33]

1.6 Tbit/s

In December 2022, IEEE started the P802.3dj Task Force to define variants for 200, 400, 800 and 1600 Gbit/s over twinaxial copper, electrical backplanes, single-mode and multi-mode optical fiber along with new variants using 100 and 200 Gbit/s lanes. [32]

NameStandard (Clause)Common connectorsDescription
Fiber-optical cable
TBD802.3djeight pairs of single-mode fiber for 500 m reach
TBDeight pairs of single-mode fiber for 2 km reach
Other
TBD802.3djeight twinaxial copper pairs for 1 meter reach

First mile

Ethernet in the first mile provides Internet access service directly from providers to homes and small businesses.

NameStandard (Clause)Description
10BaseS Proprietary [34] Ethernet over VDSL, used in Long Reach Ethernet products; [35] uses passband instead of the indicated baseband
2BASE-TL 802.3ah-2004 (61&63)Over telephone wires
10PASS-TS 802.3ah-2004 (61&62)
100BASE-LX10 802.3ah-2004 (58)Single-mode fiber-optics
100BASE-BX10
1000BASE-LX10 802.3ah-2004 (59)
1000BASE-BX10
1000BASE-PX10802.3ah-2004 (60) Passive optical network
1000BASE-PX20
10GBASE-PR
10/1GBASE-PRX
802.3av-2009 (75)10 Gbit/s passive optical network with 1 or 10 Gbit/s uplink for 10 or 20 km range
25GBASE-PR
50GBASE-PR
802.3ca-2020 (141)25 and 50 Gbit/s passive optical network

Sublayers

Starting with Fast Ethernet, the physical layer specifications are divided into three sublayers in order to simplify design and interoperability: [36]

Twisted-pair cable

Several varieties of Ethernet were specifically designed to run over 4-pair copper structured cabling already installed in many locations. 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 deliver electrical power along with the data. This is called power over Ethernet and there are several variations defined in IEEE 802.3 standards. Combining 10BASE-T (or 100BASE-TX) with 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. [37] [ failed verification ] The pins used in Mode B supply power over the spare pairs not used by 10BASE-T and 100BASE-TX. 4PPoE defined in IEEE 802.3bt can use all four pairs to supply up to 100 W.

8P8C wiring (MDI)
PinPairColorTelephone10BASE-T, [38] 100BASE-TX [39] 1000BASE-T [40] onwardsPoE mode APoE mode B
13 Wire white green stripe.svg white/greenTX+BI_DA+48 V out
23 Wire green.svg greenTX−BI_DA–48 V out
32 Wire white orange stripe.svg white/orangeRX+BI_DB+48 V return
41 Wire blue.svg blueringunusedBI_DC+48 V out
51 Wire white blue stripe.svg white/bluetipunusedBI_DC–48 V out
62 Wire orange.svg orangeRX−BI_DB–48 V return
74 Wire white brown stripe.svg white/brownunusedBI_DD+48 V return
84 Wire brown.svg brownunusedBI_DD–48 V return

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.

Twisted pair based ethernet.svg

Minimum cable lengths

Some fiber connections have minimum cable lengths due to maximum level constraints on received signals. [41] Fiber ports designed for long-haul wavelengths may 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 to minimize reflections. [42]

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. [43] [44]

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.

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

Other special-purpose physical layers include Avionics Full-Duplex Switched Ethernet and TTEthernet.

Related Research Articles

<span class="mw-page-title-main">Ethernet</span> Computer networking technology

Ethernet is a family of wired computer networking technologies commonly used in local area networks (LAN), metropolitan area networks (MAN) and wide area networks (WAN). It was commercially introduced in 1980 and first standardized in 1983 as IEEE 802.3. Ethernet has since been refined to support higher bit rates, a greater number of nodes, and longer link distances, but retains much backward compatibility. Over time, Ethernet has largely replaced competing wired LAN technologies such as Token Ring, FDDI and ARCNET.

IEEE 802.3 is a working group and a collection of standards defining the physical layer and data link layer's media access control (MAC) of wired Ethernet. The standards are produced by the working group of Institute of Electrical and Electronics Engineers (IEEE). This is generally a local area network (LAN) technology with some wide area network (WAN) applications. Physical connections are made between nodes and/or infrastructure devices by various types of copper or fiber cable.

<span class="mw-page-title-main">Ethernet over twisted pair</span> Ethernet physical layers using twisted-pair cables

Ethernet over twisted-pair technologies use twisted-pair cables for the physical layer of an Ethernet computer network. They are a subset of all Ethernet physical layers.

<span class="mw-page-title-main">Fast Ethernet</span> Ethernet standards that carry data at the nominal rate of 100 Mbit/s

In computer networking, Fast Ethernet physical layers carry traffic at the nominal rate of 100 Mbit/s. The prior Ethernet speed was 10 Mbit/s. Of the Fast Ethernet physical layers, 100BASE-TX is by far the most common.

<span class="mw-page-title-main">Gigabit Ethernet</span> Standard for Ethernet networking at a data rate of 1 gigabit per second

In computer networking, Gigabit Ethernet is the term applied to transmitting Ethernet frames at a rate of a gigabit per second. The most popular variant, 1000BASE-T, is defined by the IEEE 802.3ab standard. It came into use in 1999, and has replaced Fast Ethernet in wired local networks due to its considerable speed improvement over Fast Ethernet, as well as its use of cables and equipment that are widely available, economical, and similar to previous standards. The first standard for faster 10 Gigabit Ethernet was approved in 2002.

<span class="mw-page-title-main">Small Form-factor Pluggable</span> Modular communications interface

Small Form-factor Pluggable (SFP) is a compact, hot-pluggable network interface module format used for both telecommunication and data communications applications. An SFP interface on networking hardware is a modular slot for a media-specific transceiver, such as for a fiber-optic cable or a copper cable. The advantage of using SFPs compared to fixed interfaces is that individual ports can be equipped with different types of transceivers as required, with the majority including optical line terminals, network cards, switches and routers.

<span class="mw-page-title-main">Power over Ethernet</span> System for delivering power along with data over an Ethernet cable

Power over Ethernet (PoE) describes any of several standards or ad hoc systems that pass electric power along with data on twisted-pair Ethernet cabling. This allows a single cable to provide both a data connection and enough electricity to power networked devices such as wireless access points (WAPs), IP cameras and VoIP phones.

Autonegotiation is a signaling mechanism and procedure used by Ethernet over twisted pair by which two connected devices choose common transmission parameters, such as speed, duplex mode, and flow control. In this process, the connected devices first share their capabilities regarding these parameters and then choose the highest-performance transmission mode they both support.

<span class="mw-page-title-main">Medium-dependent interface</span> Interface between a network device and the data link it communicates over

A medium-dependent interface (MDI) describes the interface in a computer network from a physical-layer implementation to the physical medium used to carry the transmission. Ethernet over twisted pair also defines a medium-dependent interface – crossover (MDI-X) interface. Auto–MDI-X ports on newer network interfaces detect if the connection would require a crossover and automatically choose the MDI or MDI-X configuration to complement the other end of the link.

<span class="mw-page-title-main">Multi-mode optical fiber</span> Type of optical fiber mostly used for communication over short distances

Multi-mode optical fiber is a type of optical fiber mostly used for communication over short distances, such as within a building or on a campus. Multi-mode links can be used for data rates up to 800 Gbit/s. Multi-mode fiber has a fairly large core diameter that enables multiple light modes to be propagated and limits the maximum length of a transmission link because of modal dispersion. The standard G.651.1 defines the most widely used forms of multi-mode optical fiber.

Physical medium dependent sublayers or PMDs further help to define the physical layer of computer network protocols. They define the details of transmission and reception of individual bits on a physical medium. These responsibilities encompass bit timing, signal encoding, interacting with the physical medium, and the properties of the cable, optical fiber, or wire itself. Common examples are specifications for Fast Ethernet, Gigabit Ethernet and 10 Gigabit Ethernet defined by the Institute of Electrical and Electronics Engineers (IEEE).

The physical coding sublayer (PCS) is a networking protocol sublayer in the Fast Ethernet, Gigabit Ethernet, and 10 Gigabit Ethernet standards. It resides at the top of the physical layer (PHY), and provides an interface between the physical medium attachment (PMA) sublayer and the media-independent interface (MII). It is responsible for data encoding and decoding, scrambling and descrambling, alignment marker insertion and removal, block and symbol redistribution, and lane block synchronization and deskew.

Ethernet in the first mile (EFM) refers to using one of the Ethernet family of computer network technologies between a telecommunications company and a customer's premises. From the customer's point of view, it is their first mile, although from the access network's point of view it is known as the last mile.

40 Gigabit Ethernet (40GbE) and 100 Gigabit Ethernet (100GbE) are groups of computer networking technologies for transmitting Ethernet frames at rates of 40 and 100 gigabits per second (Gbit/s), respectively. These technologies offer significantly higher speeds than 10 Gigabit Ethernet. The technology was first defined by the IEEE 802.3ba-2010 standard and later by the 802.3bg-2011, 802.3bj-2014, 802.3bm-2015, and 802.3cd-2018 standards. The first succeeding Terabit Ethernet specifications were approved in 2017.

The 10 Gbit/s Ethernet Passive Optical Network standard, better known as 10G-EPON allows computer network connections over telecommunication provider infrastructure. The standard supports two configurations: symmetric, operating at 10 Gbit/s data rate in both directions, and asymmetric, operating at 10 Gbit/s in the downstream direction and 1 Gbit/s in the upstream direction. It was ratified as IEEE 802.3av standard in 2009. EPON is a type of passive optical network, which is a point-to-multipoint network using passive fiber-optic splitters rather than powered devices for fan-out from hub to customers.

<span class="mw-page-title-main">10 Gigabit Ethernet</span> Standards for Ethernet at ten times the speed of Gigabit Ethernet

10 Gigabit Ethernet is a group of computer networking technologies for transmitting Ethernet frames at a rate of 10 gigabits per second. It was first defined by the IEEE 802.3ae-2002 standard. Unlike previous Ethernet standards, 10GbE defines only full-duplex point-to-point links which are generally connected by network switches; shared-medium CSMA/CD operation has not been carried over from the previous generations of Ethernet standards so half-duplex operation and repeater hubs do not exist in 10GbE. The first standard for faster 100 Gigabit Ethernet links was approved in 2010.

Terabit Ethernet (TbE) is Ethernet with speeds above 100 Gigabit Ethernet. The 400 Gigabit Ethernet and 200 Gigabit Ethernet standard developed by the IEEE P802.3bs Task Force using broadly similar technology to 100 Gigabit Ethernet was approved on December 6, 2017. On February 16, 2024 the 800 Gigabit Ethernet standard developed by the IEEE P802.3df Task Force was approved.

<span class="mw-page-title-main">OPEN Alliance SIG</span>

The OPEN Alliance is a non-profit, special interest group (SIG) of mainly automotive industry and technology providers collaborating to encourage wide scale adoption of Ethernet-based communication as the standard in automotive networking applications.

25 Gigabit Ethernet and 50 Gigabit Ethernet are standards for Ethernet connectivity in a datacenter environment, developed by IEEE 802.3 task forces 802.3by and 802.3cd and are available from multiple vendors.

IEEE 802.3bz, NBASE-T and MGBASE-T are standards released in 2016 for Ethernet over twisted pair at speeds of 2.5 and 5 Gbit/s. These use the same cabling as the ubiquitous Gigabit Ethernet, yet offer higher speeds. The resulting standards are named 2.5GBASE-T and 5GBASE-T.

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