Definition of Optical Fiber
An
optical fiber is a flexible filament of very clear glass capable of
carrying information in the form of light. Optical fibers are hair-thin
structures created by forming pre-forms, which are glass rods drawn into
fine threads of glass protected by a plastic coating. Fiber
manufacturers use various vapor deposition processes to make the
pre-forms. The fibers drawn from these pre-forms are then typically
packaged into cable configurations, which are then placed into an
operating environment for decades of reliable performance.
Anatomy of Optical Fiber
Core
and cladding are the two main elements of an optical fiber. The core,
made of silica glass, is the light transmission area of the fiber.
Sometimes it may be treated with a “doping” element to change its
refractive index and therefore the velocity of light down the fiber. The
cladding is the layer completely surrounding the core. The difference
in refractive index between the core and cladding is less than 0.5
percent. The refractive index of the core is higher than that of the
cladding, so that light in the core strikes the interface with the
cladding at a bouncing angle, gets trapped in the core by total internal
reflection, and keeps traveling in the proper direction down the length
of the fiber to its destination.
Surrounding
the cladding is usually another layer, called coating, which typically
consists of protective polymer layers applied during the fiber drawing
process, before the fiber contacts any surface.
Fiber Types and Associated Optical Transceivers
Fiber
designs that are used today include single-mode and multimode fiber.
Multimode fiber simply refers to the fact that numerous modes of light
rays are carried simultaneously through the waveguide. Multimode fibers
used in telecom or datacom applications have a core size of 50 or 62.5
microns. Single-mode fiber shrinks the core down so small that the light
can only travel in one ray. The typical core size of a single-mode
fiber is 9 microns.
Multimode Transceiver and Fiber Type Compatibility Matrix
The
table below summarizes various optical interfaces and their performance
over the different fiber types. The table is directly derived from the
IEEE 802.3-2005 standard and specifies the maximum reach achievable over
each fiber type and the requirement for a mode conditioning patch cord
(MCP).
Interface Type
|
Wavelength (nm)
|
Fibers Supported
|
Reach (m)
|
MCP Requirement
|
1000BASE-SX
|
850
|
FDDI-grade
|
220
|
No
|
OM1
|
275
|
No
| ||
OM2
|
550
|
No
| ||
OM3
|
Not specified
| |||
1000BASE-LX
|
1300
|
FDDI-grade
|
550
|
Yes
|
OM1
|
550
|
Yes
| ||
OM2
|
550
|
Yes
| ||
OM3
|
Not specified
| |||
10GBASE-SR
|
850
|
FDDI-grade
|
26
|
No
|
OM1
|
33
|
No
| ||
OM2
|
82
|
No
| ||
OM3
|
300
|
No
| ||
10GBASE-LX4
|
1300
|
FDDI-grade
|
300
|
Yes
|
OM1
|
300
|
Yes
| ||
OM2
|
300
|
Yes
| ||
OM3
|
Not specified
| |||
10GBASE-LRM
|
1300
|
FDDI-grade
|
220
|
Yes
|
OM1
|
220
|
Yes
| ||
OM2
|
220
|
Yes
| ||
OM3
|
220
|
No
| ||
These
performance levels are guaranteed. If we go beyond the standard, longer
reaches may be achievable depending on the quality of each link. Fiber
quality can vary for a specific type due to the aging factor or to the
random imperfections it was built with. In order to really know if a
link can work, the rule is to try and see if the performance is
satisfactory. The link should be either error-free for critical
applications, or the bit error should remain below 10-12 as per minimum
standard requirement.
For example, it may be possible to reach much longer distances than 550 m with an OM3 laser-optimized fiber and 1000BASE-SX
interfaces. Also, it may be possible to reach 2 km between two
1000BASE-LX devices over any fiber type with mode conditioning path
cords properly installed at both ends.
Single-mode Transceiver and Fiber Type Compatibility Matrix
The
reaches in the table below illustrate typical performance observed in
the field. They may vary with the rate and fiber type and should not be
considered as guaranteed. NDSF refers to non-dispersion shifted fiber.
DSF means dispersion shifted fiber with a zero dispersion centered at
1550 nm, while NZDSF means non-zero dispersion shifted fiber with a zero
dispersion usually centered at 1510 nm.
Interface Type
|
Wavelength (nm)
|
Typical Reach* (km)
|
NDSF
|
DSF
|
NZDSF
|
1000BASE-LX
1000BASE-BX
10GBASE-LR
10GBASE-LW
10GBASE-LX4
|
1310
|
10
|
Yes
|
No
|
No
|
10GBASE-ER
|
1550
|
30-40
|
Yes
|
Yes
|
Yes
|
1000BASE-ZX
10GBASE-ZR
|
1550
|
80-100
|
Yes
|
Yes
|
Yes
|
CWDM
|
1470 to 1610
|
80-120**
|
Yes
|
No
|
Yes
|
DWDM
|
1530 to 1565
|
80-100**
|
Yes
|
No
|
Yes
|
Conclusion
Fiber
optic cables are the medium of choice in telecommunications
infrastructure, enabling the transmission of high-speed voice, video and
data traffic in enterprise and service provider networks. This article
has briefly explained optical fiber basis and its structure as well as
the associated transceivers by the fiber types. As a professional
supplier in optical industry, Fiberstore has all kinds of transceivers,
such as SFP-10G-ER, GLC-LH-SMD, etc. And Fiberstore also provides customized service according to your special requirements.
Article source: www.fiberopticshare.com/1777.html
没有评论:
发表评论