Ethernet physical layer

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The five layer TCP/IP model
5. Application layer

DHCPDNSFTPHTTPIMAP4IRCNNTPXMPPMIMEPOP3SIPSMTPSNMPSSHTELNETBGPRPCRTPRTCPTLS/SSLSDPSOAPL2TPPPTP

4. Transport layer

TCPUDPDCCPSCTPGTP

3. Network layer

IP (IPv4IPv6) • ICMPIGMPRSVPIPsec

2. Data link layer

ATMDTMEthernetFDDIFrame RelayGPRSPPPARPRARP

1. Physical layer

Ethernet physical layerISDNModemsPLCSONET/SDHG.709Wi-Fi

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 IEEE photograph of a diagram with the original terms for describing Ethernet drawn by Robert M. Metcalfe around 1976.
IEEE photograph of a diagram with the original terms for describing Ethernet drawn by Robert M. Metcalfe around 1976.

The Ethernet physical layer evolved over a considerable time span and encompasses quite a few physical media interfaces and several magnitudes of speed. The speed ranges from 3 Mbit/s to 10 Gbit/s in speed while the physical medium ranges from bulky coaxial cable to twisted pair to optical fiber. In general, network protocol stack software will work identically on most of the following types.

The following sections provide a brief summary of all the official Ethernet media types (section numbers from the IEEE 802.3-2002 standard are parenthesized). 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.

Many Ethernet adapters and switch ports support multiple speeds, using auto-negotiation to set the speed and duplex for the best values supported by both connected devices. If auto-negotiation fails, a multiple speed device will sense the speed used by its partner, but will assume half-duplex. A 10/100 Ethernet port supports 10BASE-T and 100BASE-TX. A 10/100/1000 Ethernet port supports 10BASE-T, 100BASE-TX, and 1000BASE-T.

Contents

[edit] Physical layers

[edit] Xerox experimental Ethernet

Name Description
Xerox Ethernet The original, 3Mb/s Ethernet implementation, which had a frame format different from the production forms of Ethernet.

[edit] Early implementations (10 Mb/s and 1 Mb/s)

Name Standard Description
10BASE5 802.3 (8) 10Mb/sec, Manchester coded signaling, copper RG-8X (expensive) coaxial cabling, bus topology with collision detection (aka Thick Ethernet)
10BASE2 802.3 (10) 10Mb/sec, Manchester coded signaling, copper RG-58 (cheap) coaxial cabling, bus topology with collision detection (aka Thin Ethernet)
10BROAD36 802.3 (11) 10Mb/sec, scrambled NRZ signaling modulated (PSK) over high frequency carrier, broad bandwidth coaxial cabling, bus topology with collision detection
1BASE5 802.3 (12) 1Mb/sec, Manchester coded signaling, copper twisted pair cabling, star topology
StarLAN 10 10Mb/sec, Manchester coded signaling, copper twisted pair cabling, star topology - evolved into 10BASE-T
10BASE-T 802.3 (14) 10Mb/sec, Manchester coded signaling, copper twisted pair cabling, star topology - direct evolution of 1BASE-5
FOIRL Fiber-optic inter-repeater link; the original standard for Ethernet over fiber
10BASE-F 802.3 (15) (also called 10BASE-FX) -- 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 is in widespread use. 10Mb/sec, Manchester coded signaling, fiber pair
10BASE-FL 802.3 (15) an updated version of the FOIRL standard
10BASE-FB 802.3 (15) intended for backbones connecting a number of hubs or switches; it is now obsolete
10BASE-FP 802.3 (15) a passive star network that required no repeater, it was never implemented

[edit] Fast Ethernet (100 Mb/s)

For more details on this topic, see Fast Ethernet.
Name Standard Description
100BASE-T A term for any of the three standards for 100 Mbit/s Ethernet over twisted pair cable up to 100 meters long. Includes 100BASE-TX, 100BASE-T4 and 100BASE-T2. All of them use a star topology.
100BASE-TX 802.3 (24) 4B5B MLT-3 coded signaling, CAT5 copper cabling with two twisted pairs.
100BASE-T4 802.3 (23) 8B6T PAM-3 coded signaling, CAT3 copper cabling (as used for 10BASE-T installations) with four twisted pairs (uses all four pairs in the cable). Now obsolete, as Cat-5 cabling is the norm. Limited to half-duplex.
100BASE-T2 802.3 (32) No products exist. 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 encoding schemes required, making this option fairly expensive.
100BASE-FX 802.3 (24) 4B5B NRZI coded signaling, two strands of multi-mode optical fiber. Maximum length is 400 meters for half-duplex connections (to ensure collisions are detected) or 2 kilometers for full-duplex.
100BASE-SX TIA 100 Mbit/s Ethernet over multi-mode fiber. Maximum length is 300 meters. Unlike 100BASE-FX using lasers as light sources, 100BASE-SX uses LEDs, so it is cheaper.
100BASE-BX10 802.3 100 Mbit/s Ethernet bidirectionally over a single strand of single-mode optical fiber. A multiplexer is used to split transmit and receive signals into different wavelengths allowing them to share the same fiber. Supports up to 10km.
100BASE-LX10 802.3 100 Mbit/s Ethernet up to 10km over a pair of single mode fibers.
100Base-VG 802.12 Standardized by a different IEEE 802 subgroup, 802.12, because it used a different, more centralized form of media access ("Demand Priority"). Championed by only HP, 100VG-AnyLAN (as was the marketing name) was the earliest in the market. It needed four pairs of Cat-3 cables. Now obsolete (802.12 has been "inactive" since 1997).

[edit] Gigabit Ethernet

For more details on this topic, see Gigabit Ethernet.

All of these use a star topology.

Name Standard Description
1000BASE-T 802.3 (40) PAM-5 coded signaling, CAT5/CAT5e/CAT6 copper cabling with four twisted pairs (used in both directions)
1000BASE-TX TIA 854 over only Cat-6 copper cabling. Unimplemented.
1000BASE-SX 802.3 8B10B NRZ coded signaling, multi-mode fiber (up to 550 m).
1000BASE-LX 802.3 8B10B NRZ coded signaling, multi-mode fiber (up to 550 m) or single-mode fiber (up to 2 km; can be optimized for longer distances, up to 10 km).
1000BASE-LH multi-vendor over single-mode fiber (up to 100 km). A long-haul solution.
1000BASE-CX 802.3 8B10B NRZ coded signaling, balanced shielded twisted pair (up to 25 m) over special copper cable. Predates 1000BASE-T and rarely used.
1000BASE-BX10 802.3 Up to 10km over single strand of single-mode fibre.
1000BASE-LX10 802.3 Up to 10km over a pair of single-mode fibres.
1000BASE-PX10-D 802.3 downstream (from head-end to tail-ends) over single-mode fiber using point-to-multipoint topology (supports at least 10 km).
1000BASE-PX10-U 802.3 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-D 802.3 downstream (from head-end to tail-ends) over single-mode fiber using point-to-multipoint topology (supports at least 20 km).
1000BASE-PX20-U 802.3 upstream (from a tail-end to the head-end) over single-mode fiber using point-to-multipoint topology (supports at least 20 km).

[edit] 10 gigabit Ethernet

For more details on this topic, see 10 gigabit Ethernet.
Name Standard Description
10GBASE-SR 802.3ae designed to support short distances over deployed multi-mode fiber cabling, it has a range of between 26 m and 82 m depending on cable type. It also supports 300 m operation over a new 2000 MHz.km multi-mode fiber.
10GBASE-LX4 802.3ae uses wavelength division multiplexing to support ranges of between 240 m and 300 m over deployed multi-mode cabling. Also supports 10 km over single-mode fiber.
10GBASE-LR 802.3ae supports 10 km over single-mode fiber
10GBASE-ER 802.3ae supports 40 km over single-mode fiber
10GBASE-SW 802.3ae A variation of 10GBASE-SR using the WAN PHY, designed to interoperate with OC-192 / STM-64 SONET/SDH equipment
10GBASE-LW 802.3ae A variation of 10GBASE-LR using the WAN PHY, designed to interoperate with OC-192 / STM-64 SONET/SDH equipment
10GBASE-EW 802.3ae A variation of 10GBASE-ER using the WAN PHY, designed to interoperate with OC-192 / STM-64 SONET/SDH equipment
10GBASE-CX4 802.3ak designed to support short distances over copper cabling, it uses InfiniBand 4x connectors and CX4 cabling and allows a cable length of up to 15 m.
10GBASE-T 802.3an Uses unshielded twisted-pair wiring.
10GBASE-LRM draft 802.3aq Extend to 220 m over deployed 500 MHz.km multimode fiber
  • 10 gigabit Ethernet is still fairly new and it remains to be seen which of the standards will gain commercial acceptance.
  • Note that both IEEE 802.2ae and IEEE 802.3ak have been incorporated into IEEE 802.3-2005.

[edit] 100 gigabit Ethernet

For more details on this topic, see 100 gigabit Ethernet.
Name Standard Description
100GBASE-? 802.3 HSSG Higher Speed Study Group. 100 Gb/s up to 100 m or 10 km using MMF or SMF optical fiber respectively

[edit] Ethernet over 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[citation needed].

RJ-45 Wiring (TIA/EIA-568-B T568A)
Pin Pair Color telephone 10BASE-T 100BASE-TX 1000BASE-T PoE mode A PoE mode B
1 3 Pair 3 Wire 1 white/green - TX+ z bidi 48V out -
2 3 Pair 3 Wire 2 green - TX- z bidi 48V out -
3 2 Pair 2 Wire 1 white/orange - RX+ z bidi 48V return -
4 1 Pair 1 Wire 2 blue ring - - bidi - 48V out
5 1 Pair 1 Wire 1 white/blue tip - - bidi - 48V out
6 2 Pair 2 Wire 2 orange - RX- z bidi 48V return -
7 4 Pair 4 Wire 1 white/brown - - - bidi - 48V return
8 4 Pair 4 Wire 2 brown - - - bidi - 48V return

Combining 10Base-T (or 100BASE-TX) with "IEEE 802.3af mode A" allows a hub to transmit both power and data over only two pairs. This was designed to leave the other two pairs free for analog telephone signals[citation needed][1].

The pins used in "IEEE 802.3af Mode B" supplies power over the "spare" pairs not used by 10BASE-T and 100BASE-TX.

In a departure from both 10BASE-T and 100BASE-TX, 1000BASE-T uses all four cable pairs for simultaneous transmission in both directions through the use of echo cancellation. (Telephones also use echo cancellation to simultaneously transmit in both direction over a single cable pair).

[edit] Ethernet Minimum Cable Lengths

All copper Ethernet segments that run the Collision Detect (CD) portion of CSMA/CD have a minimum cable length to function properly because of reflections. This is normally 10-100 Mb stuff; Gigabit is covered at the end of this section.

for example: http://support.microsoft.com/kb/97550 http://www.comptechdoc.org/independent/networking/guide/nethwethernet.html

Fiber connections have minimum cable lengths too, due to received signal level requirements:

http://www.cisco.com/en/US/products/hw/modules/ps5455/products_data_sheet0900aecd801ba88e.html

Fiber ports designed for long distances (kilometers) need a signal attenuator if used within a data center, for example:

for example: from http://apps.extremenetworks.com/services/documentation/ConsolidatedHWRev2-Chapter1.asp "The transmitter output power level for the 1000BASE-SX is -5 dBm. The maximum allowable receiver input power level is -17 dBm. Therefore, there is a minimum of 12 dB loss required for the link to operate without errors. This minimum required loss can be achieved using a fiber length of 52 km (0.25 dB/km provides 8 dB loss), or by adding 10 dB of fixed optical attenuator at the receiver end."

Industrial Ethernet uses a star topology with no collisions, therefore no minimum cable length is required. Please see http://www.ccontrols.com/pdf/NWSL61.pdf

Aircraft use a special type of Ethernet also; not included in this article yet.

So here's where it gets interesting. 1000BaseT, (Gigabit over copper, 4-pair) actually supports half-duplex mode, so collisions are possible. This would definitely require a minimum cable length for CD to work, so to avoid this in Gigabit, they pad small frames in half duplex mode:

http://www.intel.com/network/connectivity/resources/doc_library/white_papers/solutions/copper_guide/gig_over_copper.htm

"When running in half-duplex mode, Gigabit Ethernet uses the CSMA/CD protocol. Half-duplex collision domains should be the same as for 100BASE-TX, although each domain can support only one half-duplex repeater. In order to make CSMA/CD work for Gigabit Ethernet, it was necessary to alter the normal timing within a collision domain. At Gigabit speeds, smaller sized data packets could literally reach their destinations before the sending station could detect a collision signal. To overcome this problem, minimum-sized packets are padded with an extension field."

[edit] See also

[edit] External links