Open main menu

Wikipedia β

In computer networking, the transport layer is a conceptual division of methods in the layered architecture of protocols in the network stack in the Internet Protocol Suite and the Open Systems Interconnection (OSI). The protocols of the layer provide host-to-host communication services for applications.[1] It provides services such as connection-oriented data stream support, reliability, flow control, and multiplexing.

The details of implementation and semantics of the Transport Layer of the TCP/IP model (RFC 1122),[2] which is the foundation of the Internet, and the Open Systems Interconnection (OSI) model of general networking, are easily compared.[3][4][5][6] In the OSI model the transport layer is most often referred to as Layer 4 or L4, while numbered layers are not used in TCP/IP.

The best-known transport protocol of TCP/IP is the Transmission Control Protocol (TCP), and lent its name to the title of the entire suite. It is used for connection-oriented transmissions, whereas the connectionless User Datagram Protocol (UDP) is used for simpler messaging transmissions. TCP is the more complex protocol, due to its stateful design incorporating reliable transmission and data stream services. Other prominent protocols in this group are the Datagram Congestion Control Protocol (DCCP) and the Stream Control Transmission Protocol (SCTP).



Transport layer services are conveyed to an application via a programming interface to the transport layer protocols. The services may include the following features:

  • Connection-oriented communication: It is normally easier for an application to interpret a connection as a data stream rather than having to deal with the underlying connection-less models, such as the datagram model of the User Datagram Protocol (UDP) and of the Internet Protocol (IP).
  • Same order delivery: The network layer doesn't generally guarantee that packets of data will arrive in the same order that they were sent, but often this is a desirable feature. This is usually done through the use of segment numbering, with the receiver passing them to the application in order. This can cause head-of-line blocking.
  • Reliability: Packets may be lost during transport due to network congestion and errors. By means of an error detection code, such as a checksum, the transport protocol may check that the data is not corrupted, and verify correct receipt by sending an ACK or NACK message to the sender. Automatic repeat request schemes may be used to retransmit lost or corrupted data.
  • Flow control: The rate of data transmission between two nodes must sometimes be managed to prevent a fast sender from transmitting more data than can be supported by the receiving data buffer, causing a buffer overrun. This can also be used to improve efficiency by reducing buffer underrun.
  • Congestion avoidance: Congestion control can control traffic entry into a telecommunications network, so as to avoid congestive collapse by attempting to avoid oversubscription of any of the processing or link capabilities of the intermediate nodes and networks and taking resource reducing steps, such as reducing the rate of sending packets. For example, automatic repeat requests may keep the network in a congested state; this situation can be avoided by adding congestion avoidance to the flow control, including slow-start. This keeps the bandwidth consumption at a low level in the beginning of the transmission, or after packet retransmission.
  • Multiplexing: Ports can provide multiple endpoints on a single node. For example, the name on a postal address is a kind of multiplexing, and distinguishes between different recipients of the same location. Computer applications will each listen for information on their own ports, which enables the use of more than one network service at the same time. It is part of the transport layer in the TCP/IP model, but of the session layer in the OSI model.


The transport layer is responsible for delivering data to the appropriate application process on the host computers. This involves statistical multiplexing of data from different application processes, i.e. forming data segments, and adding source and destination port numbers in the header of each transport layer data segment. Together with the source and destination IP address, the port numbers constitutes a network socket, i.e. an identification address of the process-to-process communication. In the OSI model, this function is supported by the session layer.

Some transport layer protocols, for example TCP, but not UDP, support virtual circuits, i.e. provide connection oriented communication over an underlying packet oriented datagram network. A byte-stream is delivered while hiding the packet mode communication for the application processes. This involves connection establishment, dividing of the data stream into packets called segments, segment numbering and reordering of out-of order data.

Finally, some transport layer protocols, for example TCP, but not UDP, provide end-to-end reliable communication, i.e. error recovery by means of error detecting code and automatic repeat request (ARQ) protocol. The ARQ protocol also provides flow control, which may be combined with congestion avoidance.

UDP is a very simple protocol, and does not provide virtual circuits, nor reliable communication, delegating these functions to the application program. UDP packets are called datagrams, rather than segments.

TCP is used for many protocols, including HTTP web browsing and email transfer. UDP may be used for multicasting and broadcasting, since retransmissions are not possible to a large amount of hosts. UDP typically gives higher throughput and shorter latency, and is therefore often used for real-time multimedia communication where packet loss occasionally can be accepted, for example IP-TV and IP-telephony, and for online computer games.

Many non-IP-based networks, such as X.25, Frame Relay and ATM, implement the connection-oriented communication at the network or data link layer rather than the transport layer. In X.25, in telephone network modems and in wireless communication systems, reliable node-to-node communication is implemented at lower protocol layers.

The OSI connection-mode transport layer protocol specification defines five classes of transport protocols: TP0, providing the least error recovery, to TP4, which is designed for less reliable networks.


Comparison of transport layer protocolsEdit

Feature Name UDP UDP-Lite TCP Multipath TCP SCTP DCCP RUDP
Packet header size 8 bytes 8 bytes 20–60 bytes 50–90 bytes 12 bytes 12 or 16 bytes 6+ bytes
Transport layer packet entity Datagram Datagram Segment Segment Datagram Datagram Datagram
Connection oriented No No Yes Yes Yes Yes Yes
Reliable transport No No Yes Yes Yes No Yes
Unreliable transport Yes Yes No No Yes Yes Yes
Preserve message boundary Yes Yes No No Yes Yes Yes
Ordered delivery No No Yes Yes Yes No Yes
Unordered delivery Yes Yes No No Yes Yes Yes
Data checksum Optional Yes Yes Yes Yes Yes Optional
Checksum size (bits) 16 16 16 16 32 16 16
Partial checksum No Yes No No No Yes No
Path MTU No No Yes Yes Yes Yes Unsure
Flow control No No Yes Yes Yes No Yes
Congestion control No No Yes Yes Yes Yes Unsure
Explicit Congestion Notification No No Yes Yes Yes Yes
Multiple streams No No No Yes Yes No No
Multi-homing No No No Yes Yes No No
Bundling / Nagle No No Yes Yes Yes No Unsure

Comparison of OSI transport protocolsEdit

ISO/IEC 8073/ITU-T Recommendation X.224, "Information Technology - Open Systems Interconnection - Protocol for providing the connection-mode transport service", defines five classes of connection-mode transport protocols designated class 0 (TP0) to class 4 (TP4). Class 0 contains no error recovery, and was designed for use on network layers that provide error-free connections. Class 4 is closest to TCP, although TCP contains functions, such as the graceful close, which OSI assigns to the session layer. All OSI connection-mode protocol classes provide expedited data and preservation of record boundaries. Detailed characteristics of the classes are shown in the following table:[7]

Service TP0 TP1 TP2 TP3 TP4
Connection oriented network Yes Yes Yes Yes Yes
Connectionless network No No No No Yes
Concatenation and separation No Yes Yes Yes Yes
Segmentation and reassembly Yes Yes Yes Yes Yes
Error Recovery No Yes No Yes Yes
Reinitiate connection (if an excessive number of PDUs are unacknowledged) No Yes No Yes No
multiplexing and demultiplexing over a single virtual circuit No No Yes Yes Yes
Explicit flow control No No Yes Yes Yes
Retransmission on timeout No No No No Yes
Reliable Transport Service No Yes No Yes Yes

There is also a connectionless transport protocol, specified by ISO/IEC 8602/ITU-T Recommendation X.234.[8]


  1. ^ RFC 1122, §1.1.3.
  2. ^ RFC 1122, Requirements for Internet Hosts – Communication Layers, IETF, R. Braden (Editor), October 1989
  3. ^ Lou Frenzel (2013-10-02). "What's The Difference Between The OSI Seven-Layer Network Model And TCP/IP?". Electronic Design. Retrieved 2017-01-17. 
  4. ^ "Difference between OSI Reference Model and TCP/IP Reference Model | Computer Network Tutorial". Retrieved 2017-01-17. 
  5. ^ "Four Layers of TCP/IP model, Comparison and Difference between TCP/IP and OSI models". Retrieved 2017-01-17. 
  6. ^ Tetz, Edward. "Network Basics: TCP/IP and OSI Network Model Comparisons". Retrieved 2017-01-17. 
  7. ^ "ITU-T Recommendation X.224 (11/1995) ISO/IEC 8073". Retrieved 2017-01-17. 
  8. ^ "ITU-T Recommendation X.234 (07/1994) ISO/IEC 8602". Retrieved 2017-01-17.