Fddi Connection Equipment; Fddi Media - Cisco 7000 Hardware Installation And Maintenance

All information in a Token Ring network is seen by active MSAUs or MAUs. Some of these devices
can be programmed to check for problems and automatically remove problem stations from the ring,
and some contain bypass relays so that you can selectively remove stations from the ring without
affecting traffic on the network.
All TRIP ports support both 4 and 16-Mbps operation and early token release. The default for all
ports is for 4 Mbps operation and early token release disabled. Both states are enabled with
configuration commands in the configuration mode. To enable 16 Mbps, specify the slot/port
address and use the configuration command ring-speed 16; to return to 4-Mbps operation, use the
command ring-speed 4. To enable and disable early token release, specify the slot/port address and
use the configuration command [no] early token release. For examples of these commands, refer to
the section "Token Ring Connection Equipment" in the chapter "Preparing for Installation." For
complete descriptions and examples of software commands, refer to the related software
configuration and command reference documentation.

FDDI Connection Equipment

Fiber-optic transceivers on the FIP provide a direct interface between the router and the Fiber
Distributed Data Interface (FDDI) ring. The FIP supports both single-mode and multimode
transceivers and is available with any combination of the two types. Both transceiver types provide
a Class A dual attachment interface that can be connected to a Class A or a Class B station. Class A
is a dual attachment station (DAS) with primary and secondary rings; Class B is a single attachment
station (SAS) with only a primary ring. A detailed description of Class A and B and of DASs and
SASs follows the descriptions of FDDI connection equipment.

FDDI Media

FDDI networks use two types of fiber-optic cable: single-mode (also called monomode) and
multimode. Mode refers to the angle at which light rays (signals) are reflected and propagated
through the optical fiber core, which acts as a waveguide for the light signals. Multimode fiber has
a relatively thick core (62.5/125-micron) that reflects light rays at many angles. Single-mode fiber
has a narrow core (8.7 to 10/125-micron) that allows the light to enter only at a single angle.
Although multimode fiber allows more light signals to enter at a greater variety of angles (modes),
the different angles create multiple propagation paths that cause the signals to spread out in time and
limits the rate at which data can be accurately received. This distortion does not occur on the single
path of the single-mode signal; therefore, single-mode fiber is capable of higher bandwidth and
greater cable run distances than multimode fiber. In addition, multimode transmitters usually use
LEDs as a light source, and single-mode transmitters use a laser diode, which is capable of
sustaining faster data rates. Both types use a photodiode detector at the receiver to translate the light
signal into electrical signals.
Preparing Network Connections
Preparing for Installation 2-97