Difference between revisions of "TCP/IP"

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=== ARP ===
=== ARP ===
Address resolution protocol; it translates from an IP address to physical netowrk (e.g. [[Ethernet]]) addresses.
Address resolution protocol; it translates from an IP address to physical network (e.g. [[Ethernet]]) addresses.
=== SLIP ===
=== SLIP ===

Revision as of 16:29, 14 June 2018

TCP/IP is the network protocol suite that is used in the Internet, the internet (the short form of the term internetwork) which is the world's dominant information network.

Because of the rise in popularity of the Internet, TCP/IP is the most popular networking protocol suite of all time. There simply are an amazing amount of OSs and platforms that support TCP/IP.

TCP/IP was heavily influenced by the ground-breaking CYCLADES network (as were all internetworks), and also took influences from the PARC Universal Packet (PUP) protocol suite.

Vint Cerf is largely credited with initially creating the protocol suite; over the last several decades, a varying cast of characters, under the aegis of the Internet Engineering Task Force, has done the engineering work to let TCP/IP handle the much larger Internet of today (many times larger than TCP/IP was originally designed to support).

TCP/IP is a family of several protocols, the most important of which are listed below:


The most important protocol of all, the internetworking layer Internet Protocol (IP), offers direct un-reliable datagram carriage across the entire internetwork.

Underneath IP, each individual physical network has a protocol which specifies how packets are carried from one interface to that network to another; there are also a number of different protocols, providing different services, running on top of IP.

IP is thus spoken of as being the 'waist' in the 'hour-glass' of TCP/IP; it is the one indispensable protocol that every node in the internet must understand and use.

The lack of delivery guarantees means that it is the job of the protocols above IP to ensure reliable data carriage on an end to end basis; these do so using checksums, sequence numbers, acknowledgements, timeouts, and re-transmissions.

Higher level protocols


The Transmission Control Protocol is the most widely used protocol to do that; it provides a reliable byte stream service/abstraction.


The User Datagram Protocol is used to provide access to an un-reliable datagram service, for applications which don't need the complexity and overhead of TCP.

Lower level protocols


Address resolution protocol; it translates from an IP address to physical network (e.g. Ethernet) addresses.


Serial line protocol. SLIP was a popular way to connect machines with TCP/IP over leased lines and modems (or anything that could talk in a serial manner, like the most popular RS232 ports). The big drawback to SLIP was that each end had to be pre-configured; this made things like dialup banks exceptionally difficult to maintain, as each user would be assigned a static address - however it did work out fine for 'infrastructure' as they tended not to move.

SLIP has been largely supplanted by the PPP protocol.


Point to point protocol.

PPP supplanted SLIP in two major ways. The first and most significant change was that PPP can auto-configure nodes, so that clients don't have to know anything about the network they are connecting to. The PPP server will supply an IP address from a pool - and configure the client's gateway - and will also add DNS information. PPP also included VJ header compression support, while ignoring the payload did help speed up some things on slow dialup links.

Historical Systems Including TCP/IP

This list is far, far from exhaustive, and primarily meant for systems from the 1980s, before TCP/IP became universal on all but embedded systems.

The most popular implementation of TCP/IP came from the 4.3 BSD release: because of the BSD copyright, people were free to adapt the software to their own needs.

  • BSD Unix from 4.2 onward.