Published on Nov 14, 2015
AppleTalk is a network operating system designed to connect Apple computers. Its components are built on Macintosh operating systems. There are two main versions of AppleTalk depending on how many years in the past the network was implemented, Phase 1 and Phase 2. Phase 2 is the current installation as of about 2002.
If anyone knows of something more current they should let me know. AppleTalk/Local Talk networks make use of CSMA/CA a media access control method. STP cabling is usually used. But it is possible to use UTP or Fiber Optic cabling depending on cost and/or performance issues. The network topology is a bus or tree. A Local Talk network is limited to 32 nodes. Local Talk is the data link layer protocol originally used for Macintoshes. Macintosh computers using Local Talk are linked together using their printer ports. AppleShare is used as the file and print sharing protocol on AppleTalk networks.
AppleTalk networks make use of an addressing scheme in which each computer when it comes online:
• looks for a stored address that it used in a previous session • if one isn't available then it chooses an address at random from those that are available • then it broadcasts the address to make sure no other computer is using it • if it is being used then it tries another • if it isn't being used then it stores the address to potentially be used again when it returns online the next time.
AppleTalk was designed for small networks. Fortunately, these small networks can be connected together. Each subnetwork is called a zone and has a name for identification. Resources in other zones can be configured so that they can be accessed by a click on the zone name.
AppleTalk networks can be fairly directly connected to networks of other architectures such as Ethernet or Token Ring.
Apple has developed EtherTalk or TokenTalk, which are cards that enable Macintosh computers to connect to networks operating under 802.3 and 802.5 specifications, respectively
AppleTalk Network Components
An AppleTalk socket is a unique, addressable location in an AppleTalk node. It is the logical point at which upper-layer AppleTalk software processes and the network layer Datagram Delivery Protocol (DDP) interact. These upper-layer processes are known as socket clients. Socket clients own one or more sockets, which they use to send and receive datagrams. Sockets can be assigned statically or dynamically. Statically assigned sockets are reserved for use by certain protocols or other processes. Dynamically assigned sockets are assigned by DDP to socket clients upon request. An AppleTalk node can contain up to 254 different socket numbers
Implications of the end of AppleTalk routing
Legacy operating systems and devices that only support AppleTalk should be replaced if at all possible. If they cannot be replaced, they need to be placed on the RIT network with forethought. As long as any two legacy AppleTalk devices are within the same network segment, AppleTalk communications between them will still work. However, after July 24, 2006, the addresses change because AppleTalk zones will no longer be present .
There will no longer be a way to use two AppleTalk-only devices between campus buildings, and in many cases, between hallways within buildings.If you are browsing for AppleTalk resources, you will no longer see zones, such as the "GEM Bldg Zone" or "JE Booth Bldg Zone." You will not be able to connect with AppleTalk resources that were previously in a different zone, unless you can switch to an IP-based protocol.
Devices that were within your own AppleTalk zone may also be inaccessible, because multiple network segments were often combined into one zone. Since 2003, AppleTalk has only been activated by request for subnets where there was a demonstrated need (with no reasonable IP-based alternatives) for this network service. AppleTalk was never routed on the RIT residential network, dial-in services, Virtual Private Network (VPN), or the wireless network.
AppleTalk, like many network protocols, makes no provisions for network security. The design of the AppleTalk protocol architecture requires that security measures be implemented at higher application levels. Cisco supports AppleTalk distribution lists, allowing control of routing updates on a per-interface basis. This security feature is similar to those that Cisco provides for other protocols. Note that the Cisco implementation of AppleTalk does not forward packets with local source and destination network addresses. This behavior does not conform to the definition of AppleTalk in the Apple Computer inside AppleTalk publication. However, this behavior is designed to prevent any possible corruption of the AARP table in any AppleTalk node that is performing address gleaning Through MAC.
Apple automatically includes AppleTalk in the Macintosh operating system.
Easy to implement and configure
Setting up a small workgroup is simple and inexpensive
It is not suitable for very large networks
It is very slow compared to other LAN links at 230.4 Kbps
It is unsuitable for bandwidth intensive applications
AppleTalk includes an address-resolution method much like TCP/IP's ARP. The AppleTalk version is called AARP. AARP uses broadcasts to discover the hardware address of a node. The primary network layer routing protocol in AppleTalk is the Datagram Delivery Protocol (DDP). DDP provides a best-effort connectionless datagram service. There are five key implementations of the transport layer in AppleTalk: RTMP, NBP, AURP, ATP, and AEP
W. de Leeuw and R. van Liere. Case Study: Comparing Two Methods for Filtering External Motion in 4D Confocal Microscopy Data. Joint Eurographics .
W.E. Lorensen and H.E. Cline. Marching cubes: a high resolution 3D surface construction algorithm. Computer Graphics (Siggraph’87 Proceedings), 21(4), pp163-169.
M. Levoy. Display of surfaces from volume data. Computer Graphics & Application
More Seminar Topics:
Virtual Retinal Display,
Virtual Private Network,
Virtual LAN Technology,
Unlicensed Mobile Access,
Unified Modeling Language (UML),
Unicode And Multilingual Computing,
Tsunami Warning System,
Transient Stability Assessment using Neural Networks,
Tracking and Positioning of Mobiles in Telecommunication