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This chapter
introduces the various protocols and technologies used in wide- area
network (WAN) environments. Topics summarized here include
point-to-point links, circuit switching, packet switching, virtual
circuits, dialup services, and WAN devices.
A WAN is a data communications network
that covers a relatively broad geographic area and often uses
transmission facilities provided by common carriers, such as telephone
companies. WAN technologies function at the lower three layers of the
OSI reference model: the physical layer, the data link layer, and the
network layer. Figure 3-1 illustrates the
relationship between the common WAN technologies and the OSI model.
Figure 3-1: WAN
technologies operate at the lowest levels of the OSI model.
A point-to-point link
provides a single, preestablished WAN communications path from the
customer premises through a carrier network, such as a telephone
company, to a remote network. A point-to-point link is also known as a
leased line because its established path is permanent and fixed for each
remote network reached through the carrier facilities. The carrier
company reserves point-to-point links for the private use of the
customer. These links accommodate two types of transmissions: datagram
transmissions, which are composed of individually addressed frames, and
data-stream transmissions, which are composed of a stream of data for
which address checking occurs only once. Figure 3-2
illustrates a typical point-to-point
link through a WAN.
Figure 3-2: A
typical point-to-point link operates through a WAN to a remote network.
Circuit switching is
a WAN switching method in which a dedicated physical circuit is
established, maintained, and terminated through a carrier network for
each communication session. Circuit switching accommodates two types of transmissions:
datagram transmissions and data-stream transmissions. Used extensively
in telephone company networks, circuit switching operates much like a
normal telephone call. Integrated Services Digital Network (ISDN) is an
example of a circuit-switched WAN technology, and is illustrated in Figure
3-3.
Figure 3-3: A
circuit- switched WAN undergoes a process similar to that used for a
telephone call.
Packet switching
is a WAN switching method in which network devices
share a single point-to-point link to transport packets from a source to
a destination across a carrier network. Statistical multiplexing is used
to enable devices to share these circuits. Asynchronous
Transfer Mode (ATM), Frame Relay, Switched
Multimegabit Data Service (SMDS), and X.25 are
examples of packet-switched WAN technologies (see Figure
3-4).
Figure 3-4: Packet
switching transfers packets across a carrier network.
A virtual circuit is a logical circuit
created to ensure reliable communication between two network devices.
Two types of virtual
circuits exist: switched virtual circuits (SVCs) and permanent
virtual circuits (PVCs).
SVCs are virtual circuits that
are dynamically established on demand and terminated when transmission
is complete. Communication over an SVC consists of three phases: circuit
establishment, data transfer, and circuit termination. The establishment
phase involves creating the virtual circuit between the source and
destination devices. Data transfer involves transmitting data between
the devices over the virtual circuit, and the circuit-termination phase
involves tearing down the virtual circuit between the source and
destination devices. SVCs are used in situations in which data
transmission between devices is sporadic, largely because SVCs increase
bandwidth used due to the circuit establishment and termination phases,
but decrease the cost associated with constant virtual circuit
availability.
A PVC is a permanently
established virtual circuit that consists of one mode: data transfer.
PVCs are used in situations in which data transfer between devices is
constant. PVCs decrease the bandwidth use associated with the
establishment and termination of
virtual circuits, but increase costs due to constant virtual circuit
availability.
Dialup services offer cost-effective
methods for connectivity across WANs. Two popular dialup implementations
are dial-on-demand routing (DDR) and dial backup.
DDR is a technique whereby a router can dynamically
initiate and close a circuit-switched session as transmitting end
station demand. A router is configured to consider certain traffic
interesting (such as traffic from a particular protocol) and other
traffic uninteresting. When the router receives interesting traffic
destined for a remote network, a circuit is established and the traffic
is transmitted normally. If the router receives uninteresting traffic
and a circuit is already established, that traffic also is transmitted
normally. The router maintains an idle timer that is reset only when
interesting traffic is received. If the router receives no interesting
traffic before the idle timer expires, however, the circuit is
terminated. Likewise, if uninteresting traffic is received and no
circuit exists, the router drops the traffic. Upon receiving interesting
traffic, the router initiates a new circuit. DDR can be used to replace
point-to-point links and switched multiaccess WAN services.
Dial backup is a service that activates a
backup serial line under certain conditions. The secondary serial line
can act as a backup link that is used when the primary link fails or as
a source of additional bandwidth when the load on the primary link
reaches a certain threshold. Dial backup provides protection against WAN
performance degradation and downtime.
WANs use
numerous types of devices that are specific to WAN environments. WAN
switches, access servers, modems, CSU/DSUs, and ISDN terminal adapters
are discussed in the following sections. Other devices found in WAN
environments that are exclusive to WAN implementations include routers,
ATM switches, and multiplexers.
A WAN switch
is a multiport internetworking device used in carrier networks. These
devices typically switch such traffic as Frame Relay, X.25, and SMDS and
operate at the data link layer of the OSI reference model. Figure
3-5 illustrates two routers at remote ends of a WAN that are
connected by WAN switches.
Figure 3-5: Two routers at
remote ends of a WAN can be connected by WAN switches.
An
access server acts as a concentration point for dial-in and dial-out
connections. Figure 3-6 illustrates an access
server concentrating dial-out connections into a WAN.
Figure 3-6: An
access server concentrates dial-out connections into a WAN.
A modem is
a device that interprets digital and analog signals, enabling data to be
transmitted over voice-grade telephone lines. At the source, digital
signals are converted to a form suitable for transmission over analog
communication facilities. At the destination, these analog signals are
returned to their digital form. Figure 3-7
illustrates a simple modem-to-modem connection through a WAN.
Figure 3-7: A
modem connection through a WAN handles analog and
digital signals.
A channel service
unit/digital service unit (CSU/DSU) is a digital-interface device (or
sometimes two separate digital devices) that adapts the physical
interface on a data terminal equipment (DTE) device (such as a terminal)
to the interface of a data circuit-terminating (DCE) device (such as a
switch) in a switched-carrier network. The CSU/DSU also provides signal
timing for communication between these devices. Figure
3-8 illustrates the placement of the CSU/DSU in a WAN
implementation.
Figure 3-8: The
CSU/DSU stands between the switch and the terminal.
An ISDN terminal adapter is
a device used to connect ISDN Basic
Rate Interface (BRI) connections to other interfaces, such as EIA/TIA-232.
A terminal adapter is essentially an ISDN modem. Figure
3-9 illustrates the placement of the terminal adapter in an ISDN
environment.
Figure 3-9: The
terminal adapter connects the ISDN terminal adapter to other interfaces.
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