Ethernet frame

A data packet on an Ethernet link is called an Ethernet frame. A frame begins with Preamble and Start Frame Delimiter. Following which, each Ethernet frame continues with an Ethernet header featuring destination and source MAC addresses. The middle section of the frame is payload data including any headers for other protocols (e.g. Internet Protocol) carried in the frame. The frame ends with a 32-bit cyclic redundancy check which is used to detect any corruption of data in transit.

A data packet on the wire is called a frame and consists of binary data. A frame viewed on the physical wire would show Preamble and Start Frame Delimiter, in addition to the other data. These are required by all physical hardware.^{[note 1]}

The table below shows the complete Ethernet frame, as transmitted, for the MTU of 1500 octets (some implementations of gigabit Ethernet and higher speeds support larger jumbo frames).^{[note 2]} One octet is eight bits of data (i.e., a byte on most modern computers).

10/100M transceiver chips (MII PHY) work with 4-bits (one nibble) at a time. Therefore the preamble will consist of 7 instances of 0101 + 0101, and the Start Frame Delimiter 0101 + 1101. 8-bit values are sent low 4-bit first and then high 4-bit. 1000M transceiver chips (GMII) work with 8-bits at a time, and 10 Gbit/s (XGMII) PHY works with 32-bits at a time. Note that when using octets, first 7 octets of 01010101 are sent, and then one octet of 11010101. But because the low 4-bit nibble 0101 is sent first, and later the high 4-bit nibble 1101, the Start-of-frame sequence 1101 will be sent after the preamble not before the last 4-bits of the preamble as one might otherwise be lead to believe.

The header features source and destination MAC address, the Ethertype protocol identifier field and optional IEEE 802.1Q VLAN tag indicating VLAN membership and traffic priority.

The frame check sequence is a 32-bit cyclic redundancy check which enables detection of corrupted data within the entire frame.

After a frame has been sent, transmitters are required to transmit a minimum of 12 octets of idle line state before transmitting the next frame.

There are several types of Ethernet frames. The different frame types have different formats and MTU values, but can coexist on the same physical medium.

• The Ethernet Version 2^{[note 3]} or Ethernet II frame or DIX frame is the most common type in use today, as it is often used directly by the Internet Protocol.
• Novell's non-standard variation of raw IEEE 802.3 frame
• IEEE 802.2 Logical Link Control (LLC) frame
• Subnetwork Access Protocol (SNAP) frame

In addition, all four Ethernet frames types may optionally contain a IEEE 802.1Q tag to identify what VLAN it belongs to and its IEEE 802.1p priority (quality of service). This encapsulation is defined in the IEEE 802.3ac specification and increases the maximum frame by 4 bytes.

The IEEE 802.1Q tag, if present, is placed between the Source Address and the EtherType or Length fields. The first two bytes of the tag are the Tag Protocol Identifier (TPID) value of 0x8100. This is located in the same place as the EtherType/Length field in untagged frames, so an EtherType value of 0x8100 means the frame is tagged, and the true EtherType/Length is located after the Q-tag. The TPID is followed by two bytes containing the Tag Control Information (TCI) (the IEEE 802.1p priority (quality of service) and VLAN id). The Q-tag is followed by the rest of the frame, using one of the types described above.

Ethernet II framing (also known as DIX Ethernet, named after DEC, Intel and Xerox, the major participants in its design^[1]), defines the two-octet EtherType field in an Ethernet frame, preceded by destination and source MAC addresses, that identifies an upper layer protocol encapsulating the frame data.

For example, an EtherType value of 0x0800 signals that the frame contains an IPv4 datagram. Likewise, an EtherType of 0x0806 indicates an ARP frame, 0x8100 indicates an IEEE 802.1Q frame and 0x86DD indicates an IPv6 frame.

As this industry-developed standard went through a formal IEEE standardization process, the EtherType field was changed to a (data) length field in the new 802.3 standard. (Original Ethernet packets define their length with the framing that surrounds it, rather than with an explicit length count.) Since the packet recipient still needs to know how to interpret the packet, the standard required an IEEE 802.2 header to follow the length and specify the packet type. Many years later, the 802.3x-1997 standard, and later versions of the 802.3 standard, formally approved of both types of framing. In practice, both formats are in wide use, with original Ethernet framing the most common in Ethernet local area networks, due to its simplicity and lower overhead.

In order to allow some packets using Ethernet v2 framing and some packets using the original version of 802.3 framing to be used on the same Ethernet segment, EtherType values must be greater than or equal to 1536 (0x0600). That value was chosen because the maximum length of the data field of an Ethernet 802.3 frame is 1500 bytes (0x05DC). Thus if the field's value is greater than or equal to 1536, the frame must be an Ethernet v2 frame, with that field being a type field. If it's less than or equal to 1500, it must be an IEEE 802.3 frame, with that field being a length field. Values between 1500 and 1536, exclusive, are undefined.^[2] Versions 1.0 and 2.0 of the Digital/Intel/Xerox (DIX) Ethernet specification have a 16-bit sub-protocol label field called the EtherType. The new IEEE 802.3 Ethernet specification replaced that with a 16-bit length field, with the MAC header followed by an IEEE 802.2 logical link control (LLC) header. The maximum length of a frame was 1518 bytes for untagged (1522 for 802.1p or 802.1q tagged) classical Ethernet v2 and IEEE 802.3 frames. The two formats were eventually unified by the convention that values of that field between 0 (or 8 when using LLC/SNAP) and 1500 indicated the use of the new 802.3 Ethernet format with a length field, while values of 1536 decimal (0600 hexadecimal) and greater indicated the use of the original DIX or Ethernet II frame format with an EtherType sub-protocol identifier.^[3] This convention allows software to determine whether a frame is an Ethernet II frame or an IEEE 802.3 frame, allowing the coexistence of both standards on the same physical medium. See also jumbo frames.

Some protocols, particularly those designed for the OSI stack, operate directly on top of 802.2 LLC, which provides both datagram and connection-oriented network services.

The 802.2 variants of Ethernet are not in widespread use on common networks currently, with the exception of large corporate Netware installations that have not yet migrated to Netware over IP. In the past, many corporate networks supported 802.2 Ethernet to support transparent translating bridges between Ethernet and IEEE 802.5 Token Ring or FDDI networks. The most common framing type used today is Ethernet Version 2, as it is used by most Internet Protocol-based networks, with its EtherType set to 0x0800 for IPv4 and 0x86DD for IPv6.

There exists an Internet standard for encapsulating IP version 4 traffic in IEEE 802.2 frames with LLC/SNAP headers.^[4] It is almost never implemented on Ethernet (although it is used on FDDI and on token ring, IEEE 802.11, and other IEEE 802 networks). IP traffic cannot be encapsulated in IEEE 802.2 LLC frames without SNAP because, although there is an LLC protocol type for IP, there is no LLC protocol type for ARP. IP Version 6 can also be transmitted over Ethernet using IEEE 802.2 with LLC/SNAP, but, again, that's almost never used (although LLC/SNAP encapsulation of IPv6 is used on IEEE 802 networks).

By examining the 802.2 LLC header, it is possible to determine whether it is followed by a SNAP header. The LLC header includes two additional eight-bit address fields, called service access points (SAPs) in OSI terminology; when both source and destination SAP are set to the value 0xAA, the SNAP service is requested. The SNAP header allows EtherType values to be used with all IEEE 802 protocols, as well as supporting private protocol ID spaces. In IEEE 802.3x-1997, the IEEE Ethernet standard was changed to explicitly allow the use of the 16-bit field after the MAC addresses to be used as a length field or a type field.

Mac OS uses 802.2/SNAP framing for the AppleTalk V2 protocol suite on Ethernet ("EtherTalk")

Novell's "raw" 802.3 frame format was based on early IEEE 802.3 work. Novell used this as a starting point to create the first implementation of its own IPX Network Protocol over Ethernet. They did not use any LLC header but started the IPX packet directly after the length field. This does not conform to the IEEE 802.3 standard, but since IPX has always FF at the first two bytes (while in IEEE 802.2 LLC that pattern is theoretically possible but extremely unlikely), in practice this mostly coexists on the wire with other Ethernet implementations, with the notable exception of some early forms of DECnet which got confused by this.

Novell NetWare used this frame type by default until the mid nineties, and since Netware was very widespread back then, while IP was not, at some point in time most of the world's Ethernet traffic ran over "raw" 802.3 carrying IPX. Since Netware 4.10, Netware now defaults to IEEE 802.2 with LLC (Netware Frame Type Ethernet_802.2) when using IPX. (See "Ethernet Framing" in References for details.)

We may calculate the efficiency and net bit rate for Ethernet: ${\displaystyle {\text{Efficiency}}={\frac {\text{Payload size}}{\text{Frame size}}}}$ Maximum efficiency is achieved with largest allowed payload size and is ${\displaystyle {\frac {1500}{1538}}=97.53\%}$ for untagged Ethernet packets and ${\displaystyle {\frac {1500}{1542}}=97.28\%}$ when 802.1Q VLAN tagging is used.

Net bit rate may be calculated from efficiency: ${\displaystyle {\text{Net bit rate}}={\text{Efficiency}}\times {\text{Wire bit rate}}\,\!}$ Maximum net bit rate for 100BASE-TX Ethernet without 802.1Q is 97.53 Mbit/s.

A runt frame is an Ethernet frame that is less than the IEEE 802.3 minimum length of 64 bytes. Possible causes are collision, underruns, bad network card or software.^[5]