Asynchronous Transfer Mode
(ATM) is a dedicated-connection switching technology that organizes
digital data into 53-byte cell units and transmits them over a physical medium using digital
signal technology. Individually, a cell is processed asynchronously relative to
other related cells and is queued before being multiplexed over the
transmission path. It is also a
standard switching technique designed to unify telecommunication and computer networks. It uses
asynchronous time-division multiplexing, and it encodes data into
small, fixed-sized cells. This differs from approaches such as the Internet Protocol or Ethernet that use variable sized packets or frames. ATM provides data link layer services that run over a
wide range of OSI physical Layer links. ATM has functional similarity with both circuit switched networking and small packet
switched networking. It was designed for a network that must handle both
traditional high-throughput data traffic (e.g., file transfers), and real-time, low-latency content such as voice and
video. ATM uses a connection-oriented model in which a virtual circuit must be established between
two endpoints before the actual data exchange begins. ATM is a core protocol used
over the SONET/SDH backbone of the public switched telephone
network (PSTN) and Integrated Services Digital
Network (ISDN), but its use is
declining in favour of All IP.
Table 1: Comparing Network Features
Feature
|
Data Communications
|
Telecommunications
|
ATM
|
|---|---|---|---|
Traffic support
|
Data
|
Voice
|
Data, voice, video
|
Transmission unit
|
Packet
|
Frame
|
Cell
|
Transmission length
|
Variable
|
Fixed
|
Fixed
|
Switching type
|
Packet
|
Circuit
|
Cell
|
Connection type
|
Connectionless or Connection-oriented
|
Connection-oriented
|
Connection-oriented
|
Time sensitivity
|
None to some
|
All
|
Adaptive
|
Delivery
|
Best effort
|
Guaranteed
|
Defined class or guaranteed
|
Media and operating rate
|
Defined by protocol
|
Defined by class
|
Scalable
|
Media access
|
Shared or dedicated
|
Dedicated
|
Dedicated
|
ATM can be considered to represent a
unifying technology because it was designed to transport voice, data, and video
(including graphics images) on both local and wide area networks. Until the
development of ATM, networks were normally developed based on the type of data
to be transported. Thus, circuit-switched networks, which included the public
switched telephone network and high-speed digital transmission facilities, were
primarily used to transport delay-sensitive information, such as voice and
video. In comparison, on packet-based networks, such as X.25 and Frame Relay,
information can tolerate a degree of delay. Network users can select a
networking technology to satisfy a specific communications application, but
most organizations support a mixture of applications. Thus, most organizations
are forced to operate multiple networks, resulting in a degree of inefficiency
and escalating communications costs. By combining the features from both
technologies, ATM enables a single network to support voice, data, and video
Architecture
ATM is based on the switching of 53-byte cells, in which each cell
consists of a 5-byte header and a payload of 48 bytes of information. Figure
14.1 illustrates the format of the ATM cell, including the explosion of its
5-byte header to indicate the fields carried in the header.
.gif)
Advantages of ATM
- High
evolution potential, works with existing, legacy technologies
- ATM
supports voice, video and data allowing multimedia and mixed services over
a
- Single
network.
- Provides
the best multiple service support
- Supports
delay close to that of dedicated services
- Supports
the broadest range of burstiness, delay tolerance and loss performance
through the implementation of multiple QoS classes
- Provides
the capability to support both connection-oriented and connectionless
traffic using AALs
- Able
to use all common physical transmission paths like SONET.
- Cable
can be twisted-pair, coaxial or fiber-optic
- Ability
to connect LAN to WAN
- Legacy
LAN emulation
- Efficient
bandwidth use by statistical multiplexing
- Scalability
- Higher
aggregate bandwidth
- High
speed Mbps and possibly Gbps
.gif)
ATM disadvantages
- Flexible
to efficiency’s expense, at present, for any one application it is usually
possible to find a more optimized technology
- Cost,
although it will decrease with time
- New
customer premises hardware and software are required
Competition from other technologies -100 Mbps FDDI, 100 Mbps Ethernet and fast Ethernet - Presently
the applications that can benefit from ATM such as multimedia are rare
The wait, with all the promise of ATM’s capabilities many details are still in the standards process
.
References:
