Gigabit Ethernet Explained

In computer networking, Gigabit Ethernet (GbE or 1 GigE) 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.[1]

History

Ethernet was the result of research conducted at Xerox PARC in the early 1970s, and later evolved into a widely implemented physical and link layer protocol. Fast Ethernet increased the speed from 10 to 100 megabits per second (Mbit/s). Gigabit Ethernet was the next iteration, increasing the speed to 1000 Mbit/s.

Initially, Gigabit Ethernet was deployed in high-capacity backbone network links (for instance, on a high-capacity campus network). In 2000 and 2001, Apple's Power Mac G4 and PowerBook G4 respectively were the first mass-produced personal computers to feature the 1000BASE-T connection.[2] It quickly became a built-in feature in many other computers.

Half-duplex GbE links connected through repeater hubs were part of the IEEE specification,[3] but the specification is not updated anymore and full-duplex operation with switches is used exclusively.

Varieties

There are five physical layer standards for Gigabit Ethernet using optical fiber (1000BASE-X), twisted pair cable (1000BASE-T), or shielded balanced copper cable (1000BASE-CX).

The IEEE 802.3z standard includes 1000BASE-SX for transmission over multi-mode fiber, 1000BASE-LX for transmission over single-mode fiber, and the nearly obsolete 1000BASE-CX for transmission over shielded balanced copper cabling. These standards use 8b/10b encoding, which inflates the line rate by 25%, from 1000 Mbit/s to 1250 Mbit/s, to ensure a DC balanced signal, and allow for clock recovery. The symbols are then sent using NRZ.

Optical fiber transceivers are most often implemented as user-swappable modules in SFP form or GBIC on older devices.

IEEE 802.3ab, which defines the widely used 1000BASE-T interface type, uses a different encoding scheme in order to keep the symbol rate as low as possible, allowing transmission over twisted pair.

IEEE 802.3ap defines Ethernet Operation over Electrical Backplanes at different speeds.

Ethernet in the First Mile later added 1000BASE-LX10 and -BX10.

Copper

Comparison of twisted-pair-based Ethernet physical transport layers (TP-PHYs)[4] ! Name! Standard! Status! Speed ! Pairs required! Lanes per direction! Bits per hertz! Line code! Symbol rate per lane (MBd) ! Bandwidth (MHz)! Max distance (m)! Cable (minimum required)! Cable rating (MHz)! Usage
(CL40)1000444TCM 4D-PAM-512562.5100Cat 5100LAN
1000112.6PAM-3 80B/81B RS-FEC75037540Cat 6A500Automotive, IoT, M2M
(2001)1000424PAM-5250125100Cat 6250

1000BASE-T

1000BASE-T (also known as IEEE 802.3ab) is a standard for Gigabit Ethernet over twisted-pair wiring.

Each 1000BASE-T network segment is recommended to be a maximum length of 100abbr=offNaNabbr=off,[5] and must use Category 5 cable or better (including Cat 5e and Cat 6).

Autonegotiation is a requirement for using 1000BASE-T[6] according to Section 28D.5 Extensions required for Clause40 (1000BASE-T).[7] At least the clock source has to be negotiated, as one endpoint must be master and the other endpoint must be slave.

In a departure from both 10BASE-T and 100BASE-TX, 1000BASE-T uses four lanes over all four cable pairs for simultaneous transmission in both directions through the use of echo cancellation with adaptive equalization called hybrid circuits[8] (this is like telephone hybrid) and five-level pulse-amplitude modulation (PAM-5). The symbol rate is identical to that of 100BASE-TX (125 megabaud (MBd)) and the noise immunity of the five-level signaling is also identical to that of the three-level signaling in 100BASE-TX, since 1000BASE-T uses four-dimensional trellis coded modulation (TCM) to achieve a 6 dB coding gain across the four pairs.

Since negotiation takes place on only two pairs, if two GbE interfaces are connected through a cable with only two pairs, the interfaces will successfully choose 'gigabit' as the highest common denominator (HCD), but the link will never come up. Most GbE physical devices have a specific register to diagnose this behavior. Some drivers offer an "Ethernet@Wirespeed" option where this situation leads to a slower yet functional connection.[9]

The data is transmitted over four copper pairs, eight bits at a time. First, eight bits of data are expanded into four three-bit symbols through a non-trivial scrambling procedure based on a linear-feedback shift register; this is similar to what is done in 100BASE-T2, but uses different parameters. The three-bit symbols are then mapped to voltage levels which vary continuously during transmission. An example mapping is as follows:

Symbol 000 001 010 011 100 101 110 111
Line signal level0 +1 +2 −1 0 +1 −2 −1

Automatic MDI/MDI-X Configuration is specified as an optional feature in the 1000BASE-T standard,[10] meaning that straight-through cables will often work between two GbE-capable network node interfaces (both MDI) and between two switch or hub interfaces (both MDI-X). This feature eliminates the need for crossover cables, making obsolete the uplink vs normal port choices and manual selector switches found on many older hubs and switches and greatly reduces installation errors.

In order to extend and maximize the use of existing Cat-5e and Cat-6 cabling, the newer standards 2.5GBASE-T and 5GBASE-T operate at 2.5 and 5.0 Gbit/s, respectively, on existing copper infrastructure designed for use with 1000BASE-T. They are based on 10GBASE-T but use lower signaling frequencies.

1000BASE-T1

IEEE 802.3 standardized 1000BASE-T1 in IEEE Std 802.3bp-2016.[11] It defines Gigabit Ethernet over a single twisted pair for automotive and industrial applications. It includes cable specifications for 15 meters (type A) or 40 meters (type B) reach. The transmission is done using PAM-3 at 750 MBd.

1000BASE-TX

The Telecommunications Industry Association (TIA) created and promoted a standard similar to 1000BASE-T that was simpler to implement, calling it 1000BASE-TX (TIA/EIA-854).[12] The simplified design would have, in theory, reduced the cost of the required electronics by only using four unidirectional pairs (two pairs TX and two pairs RX) instead of four bidirectional pairs. However, this solution has been a commercial failure, likely due to the required Category 6 cabling and the rapidly falling cost of 1000BASE-T products.

1000BASE-CX

802.3z-1998 CL39 standardized 1000BASE-CX is an initial standard for Gigabit Ethernet connections with maximum distances of 25 meters using balanced shielded twisted pair and either DE-9 or 8P8C connector (with a pinout different from 1000BASE-T). The short segment length is due to a very high signal transmission rate. Although it is still used for specific applications where cabling is done by IT professionals, for instance, the IBM BladeCenter uses 1000BASE-CX for the Ethernet connections between the blade servers and the switch modules, 1000BASE-T has succeeded it for general copper wiring use.[13]

1000BASE-KX

802.3ap-2007 CL70 standardized 1000BASE-KX is part of the IEEE 802.3ap standard for Ethernet Operation over Electrical Backplanes. This standard defines one to four lanes of backplane links, one RX and one TX differential pair per lane, at link bandwidth ranging from 100 Mbit to 10 Gbit per second (from 100BASE-KX to 10GBASE-KX4). The 1000BASE-KX variant uses 1.25 GBd electrical (not optical) signalling speed.

Fiber optics

1000BASE-X is used in industry to refer to Gigabit Ethernet transmission over fiber, where options include 1000BASE-SX, 1000BASE-LX, 1000BASE-LX10, 1000BASE-BX10 or the non-standard -EX and -ZX implementations. Included are copper variants using the same 8b/10b line code. 1000BASE-X is based on the physical-layer standards developed for Fibre Channel.[14]

NameStandardStatusMediaConnectorTransceiver
Module
Reach
in m


  1. (⇆)


  1. (→)


  1. (→)
Notes
colspan="11"

(CL39)

(150 Ω)
254N/A4Data centres

predates 1000BASE-T; rarely used.

(CL70)
11N/A4PCBs

(CL38)
SFP
GBIC
direct-plug
211
SFP211vendor-specific;
FP laser transmitter

(CL38)
SFP

direct-plug
211

(CL59)
SFP211identical with -LX but with increased power/sensitivity;
commonly simply referred to as -LX or -LH prior to 802.3ah
1often simply referred to as -BX
SFP
211vendor-specific
SFP
211vendor-specific

(CL115)
111Automotive, Industry, Home; [15] [16]
Line code: 64b65b × PAM16
Line rate: 325 MBd
Variants: -RHA (50 m), -RHB (40 m), -RHC (15 m).

(CL60)
SFP
XFP
111EPON
FTTH;
using point-to-multipoint topology.

[17] [18]
SFP211CWDM makes it possible to have multiple parallel channels over 2 fibers;
spectral bandwidth 11 nm;
capable of 18 parallel channels

[19]
SFP211DWDM makes it possible to have multiple parallel channels over 2 fibers;
spectral bandwidth 0.2 nm;
capable of 45 to 160 parallel channels

1000BASE-SX

1000BASE-SX is an optical fiber Gigabit Ethernet standard for operation over multi-mode fiber using a 770 to 860 nanometer, near infrared (NIR) light wavelength.

The standard specifies a maximum length of 220 meters for 62.5 μm/160 MHz×km multi-mode fiber, 275 m for 62.5 μm/200 MHz×km, 500 m for 50 μm/400 MHz×km, and 550 m for 50 μm/500 MHz×km multi-mode fiber.[20] [21] Fiber optic cable manufacturers have extended the reach of 1000BASE-SX to at least 1km when used with more modern fiber optic grades such as OM3 and OM4.

This standard is highly popular for intra-building links in large office buildings, co-location facilities and carrier-neutral Internet exchanges.

Optical power specifications of SX interface: Minimum output power = −9.5 dBm. Minimum receive sensitivity = −17 dBm.

1000BASE-LSX

1000BASE-LSX is a non-standard but industry accepted[22] term to refer to Gigabit Ethernet transmission. It is very similar to 1000BASE-SX but achieves longer distances up to 2 km over a pair of multi-mode fibers due to higher quality optics than a SX, running on 1310 nm wavelength lasers. It is easily confused with 1000BASE-SX or 1000BASE-LX because the use of -LX, -LX10 and -SX is ambiguous between vendors. The range is achieved with use of Fabry Perot laser transmitter.

1000BASE-LX

1000BASE-LX is an optical fiber Gigabit Ethernet standard specified in IEEE 802.3 Clause 38 which uses a long wavelength laser (1,270–1,355 nm), and a maximum RMS spectral width of 4 nm.

1000BASE-LX is specified to work over a distance of up to 5 km over 10 μm single-mode fiber.

1000BASE-LX can also run over all common types of multi-mode fiber with a maximum segment length of 550 m. For link distances greater than 300 m, the use of a special launch conditioning patch cord may be required.[23] This launches the laser at a precise offset from the center of the fiber which causes it to spread across the diameter of the fiber core, reducing the effect known as differential mode delay which occurs when the laser couples onto only a small number of available modes in multi-mode fiber.

1000BASE-LX10

1000BASE-LX10 was standardized six years after the initial gigabit fiber versions as part of the Ethernet in the First Mile task group. It is practically identical to 1000BASE-LX, but achieves longer distances up to 10 km over a pair of single-mode fiber due to higher quality optics. Before it was standardized, 1000BASE-LX10 was essentially already in widespread use by many vendors as a proprietary extension called either 1000BASE-LX/LH or 1000BASE-LH.[24]

1000BASE-EX

1000BASE-EX is a non-standard but industry accepted term[25] to refer to Gigabit Ethernet transmission. It is very similar to 1000BASE-LX10 but achieves longer distances up to 40 km over a pair of single-mode fibers due to higher quality optics than a LX10, running on 1310 nm wavelength lasers. It is sometimes referred to as LH (Long Haul), and is easily confused with 1000BASE-LX10 or 1000BASE-ZX because the use of -LX(10), -LH, -EX, and -ZX is ambiguous between vendors. 1000BASE-ZX is a very similar non-standard longer-reach variant that uses 1550 nm wavelength optics.

1000BASE-BX10

1000BASE-BX10 is capable of up to 10 km over a single strand of single-mode fiber, with a different wavelength going in each direction. The terminals on each side of the fiber are not equal, as the one transmitting downstream (from the center of the network to the outside) uses the 1490 nm wavelength, and the one transmitting upstream uses the 1310 nm wavelength. This is accomplished using a passive splitter prism inside each transceiver.

Other, non-standard higher-powered single-strand optics commonly known as "BiDi" (bi-directional) utilize wavelength pairs in the 1490/1550 nm range, and are capable of reaching distances of 20, 40 and 80 km, or greater depending on module cost, fiber path loss, splices, connectors and patch panels. Very long reach BiDi optics may use 1510/1590 nm wavelength pairs.

1000BASE-ZX

1000BASE-ZX is a non-standard but multi-vendor[26] term to refer to Gigabit Ethernet transmission using 1,550 nm wavelength to achieve distances of at least 70km (40miles) over single-mode fiber. Some vendors specify distances up to 120km (80miles) over single-mode fiber, sometimes called 1000BASE-EZX. Ranges beyond 80 km are highly dependent upon the path loss of the fiber in use, specifically the attenuation figure in dB per km, the number and quality of connectors/patch panels and splices located between transceivers.[27]

1000BASE‑CWDM

1000BASE-CWDM is a non-standard but industry accepted term to refer to Gigabit Ethernet transmission. It is very similar to 1000BASE-LX10 but achieves longer distances up 40–120 km, and up to 18 parallel channels over a pair of single-mode fibers due to higher quality optics than LX10 and use of CWDM, running on 1270-1610 nm wavelength lasers.

Use of CWDM requires a Mux/Demux unit at both ends of the fiber link, a CWDM MUX/DEMUX with corresponding wavelengths, and SFP with corresponding wavelengths. is it also possible to DWDM in serie to increase number of channels.

Most uses Wavelengths: 1270 nm, 1290 nm, 1310 nm, 1330 nm, 1350 nm, 1370 nm, 1390 nm, 1410 nm, 1430 nm, 1450 nm, 1470 nm, 1490 nm, 1510 nm, 1530 nm, 1550 nm, 1570 nm, 1590 nm and 1610 nm

CWDM is cheaper to use than DWDM, about 1/5-1/3 of the cost.[28] [29] CWDM is about 5-10 times more expensive the if you have the fiber available, then traditional -LX/-LZ transceivers.

1000BASE‑DWDM

1000BASE-DWDM is a non-standard but industry accepted term to refer to Gigabit Ethernet transmission. It is very similar to 1000BASE-LX10 but achieves longer distances up 40–120 km, and up to 64 to 160 parallel channels over a pair of single-mode fibers due to higher quality optics than LX10 and use of DWDM, running on 1528-1565 nm wavelength lasers.

The most used channels are CH17-61 on Wavelength 1528.77-1563-86 nm.

To use DWDM it is necessary to use a Mux/Demux unit on both ends of the fiber link, a DWDM MUX/DEMUX with corresponding wavelengths, and SFP with corresponding wavelengths. is it also possible to use CWDM in series to increase the number of channels.

1000BASE-RHx

IEEE 802.3bv-2017 defines standardizes Gigabit Ethernet over step-index plastic optical fiber (POF) using -R 64b/65b large block encoding with red light (600–700 nm). 1000BASE-RHA is intended for home and consumer use (just clamping the bare POF), 1000BASE-RHB for industrial, and 1000BASE-RHC for automotive applications.

Optical interoperability

There may be optical interoperability with respective 1000BASE-X Ethernet interfaces on the same link.[30] It is also possible with certain types of optics to have a mismatch in wavelength.[31]

To achieve interoperability some criteria have to be met:[32]

1000BASE-X Ethernet is not backward compatible with 100BASE-X and is not forward compatible with 10GBASE-X.

See also

Further reading

External links

Notes and References

  1. Web site: IEEE P802.3ae 10Gb/s Ethernet Task Force . 2013-03-19.
  2. Web site: Power Macintosh G4 (Gigabit Ethernet) . apple-history.com . November 5, 2007.
  3. A single repeater per collision domain is defined in IEEE 802.3 2008 Section 3: 41. Repeater for 1000 Mb/s baseband networks
  4. Book: Ethernet: The Definitive Guide . 2nd . Charles E. Spurgeon . O'Reilly Media . 2014 . 978-1-4493-6184-6.
  5. Barrera . Dan . Interview: Dan Barrera With Ideal Networks About TIA 42 Cabling Standards & Testing Processes . https://ghostarchive.org/varchive/youtube/20211117/kNa_IdfivKs. November 17, 2021 . live. Youtube . April 8, 2020 . 11:49.
  6. Web site: Auto-Negotiation; 802.3-2002 . https://web.archive.org/web/20060130134410/http://standards.ieee.org/reading/ieee/interp/IEEE802.3af-2003interp-6.pdf . dead . January 30, 2006 . IEEE Standards Interpretations . IEEE . November 5, 2007.
  7. Web site: IEEE . Part 3: Carrier Sense Multiple Access with Collision Detection (CSMA/CD) access method and Physical Layer specifications . SECTION TWO: This section includes Clause21 through Clause 33 and Annex 22A through Annex 33E.. February 18, 2010.
  8. Web site: IEEE . 1.4 Definitions 1.4.187 hybrid . August 9, 2017 . https://web.archive.org/web/20101206030247/http://standards.ieee.org/getieee802/download/802.3-2008_section1.pdf . December 6, 2010 . dead .
  9. Web site: Broadcom Ethernet NIC FAQs . April 25, 2016.
  10. Clause 40.4.4 in IEEE 802.3-2008
  11. Web site: IEEE P802.3bp 1000BASE-T1 PHY Task Force . IEEE 802.3 . July 29, 2016 . October 6, 2016.
  12. Web site: TIA Publishes New Standard TIA/EIA-854 . https://web.archive.org/web/20110927060633/http://www.tiaonline.org/news_events/press_room/press_releases/legacy.cfm?parelease=01-87 . September 27, 2011 . July 25, 2001 . TAI.
  13. Web site: 1000BaseCX . The Network Encyclopedia . August 17, 2019 . Ciberforma Lda.
  14. IEEE 802.3 Clause 36.1.1
  15. Web site: 1000BASE-RH PHY system simulations . IEEE 802.3bv Task Force . September 8, 2015 . August 25, 2018.
  16. Web site: Optical Ethernet in Automotive . Knowledge Development for POF S.L. (KDPOF) . July 3, 2017 . August 25, 2018 . September 10, 2018 . https://web.archive.org/web/20180910014611/http://www.respice-sme.eu/fileadmin/cms/downloads/KDPOF-07_Presentation_Optical_Ethernet_Automotive.pdf . dead .
  17. Web site: CWDM SFP Datasheet . Cisco . March 22, 2020 . December 29, 2005 . en.
  18. Web site: DWDM Technology And DWDM Network Overview . FS.com . March 22, 2020 . en . November 28, 2016.
  19. Web site: DWDM-SFP Data Sheet . Cisco . March 22, 2020 . en.
  20. Web site: Ethernet Media Standards and Distances. kb.wisc.edu. February 1, 2017.
  21. IEEE 802.3 Table 38–2—Operating range for 1000BASE-SX over each optical fiber type
  22. Web site: Datasheet for SFP-1G Series . MOXA . March 21, 2020.
  23. Web site: Mode-Conditioning Patch Cord Installation Note . February 14, 2009 .
  24. Web site: Cisco SFP Optics For Gigabit Ethernet Applications . June 1, 2010 . Cisco Systems.
  25. Web site: fs SFP1G-EX-55 . FS Germany . March 30, 2020 . en.
  26. Web site: FS SFP1G-ZX-55 . FS Germany . March 30, 2020 . en.
  27. Web site: 1.25Gbps SFP Transceiver 120km. Menaranet. June 21, 2014. December 10, 2014. https://web.archive.org/web/20141210040945/http://menaranet.com/download/datasheets/SFP/187-0A031-00%20SFP%201550nm%20EZX%201GbE%20-%20Product%20Datasheet-%202%20page.pdf. dead.
  28. Web site: CWDM vs. DWDM: What Are the Differences? . Medium.com . March 22, 2020 . en . November 30, 2017.
  29. Web site: CWDM - Cost-Effective Alternative to Expand Network Capacity . fs.com. March 22, 2020 . en . June 17, 2014.
  30. Web site: Cisco 100BASE-X SFP for Fast Ethernet SFP Ports . cisco . March 29, 2020 . March 29, 2020 . https://web.archive.org/web/20200329115059/https://www02.cp-static.com/objects/pdf/2/227/1347766271_1_network-media-converters-cisco-100base-zx-for-fast-ethernet-sfp-ports-glc-fe-100zx253d.pdf . dead .
  31. Web site: Everything You Always Wanted to Know About Optical Networking – But Were Afraid to Ask . archive.nanog.org . Richard A Steenbergen . March 30, 2020.
  32. Web site: Fiber incompatabilities? - Ars Technica OpenForum . arstechnica.com . March 29, 2020 . June 6, 2006.