Glass manufacturing – Processes of manufacturing fibers – filaments – or preforms – Process of manufacturing optical fibers – waveguides – or...
Reexamination Certificate
2001-12-20
2004-05-18
Griffin, Steven P. (Department: 1731)
Glass manufacturing
Processes of manufacturing fibers, filaments, or preforms
Process of manufacturing optical fibers, waveguides, or...
C065S475000, C065S477000
Reexamination Certificate
active
06735985
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to multimode optical fibers having increased bandwidth.
BACKGROUND OF THE INVENTION
Manufacture of state of the art multimode optical fiber requires demanding control over a variety of power loss and signal impairment mechanisms. For multimode fiber, controlling mode dispersion is an important goal.
As is well known, within the optical fiber, bits of data are represented by pulses of light. Each pulse of light will spread, or disperse, over time as it travels the length of the fiber. If these data pulses overlap, they can no longer be unambiguously read at the receiving end. Lower tendency toward data pulse overlap results in higher data transmission capacity, i.e. higher bandwidth. Therefore, the bandwidth of optical fibers is ultimately limited by dispersion.
Predominant forms of dispersion are chromatic dispersion and mode dispersion. Chromatic dispersion is well known and occurs is all optical fiber systems. Mode dispersion, or intermodal dispersion, occurs mainly in multimode optical fibers where the large core diameter allows a wide number of optical paths for light to travel. Different optical paths usually have different lengths. Because the modes travel along paths of varying length, they arrive at the fiber end at different intervals of time. If the time difference is great enough, the pulse traveling the faster path will overlap the pulse ahead of it.
Multimode optical fiber bandwidth is optimized by minimizing intermodal dispersion. This is commonly achieved by using graded index profiles wherein the refractive index gradually increases from the outer region of the cladding to the center of the core. Signals travel faster-in the low-index region near the cladding, and slower in the high-index region near the center of the core.
In multimode optical fiber, mode dispersion may be referred to as
D
ifferential
M
ode
D
elay (DMD). Manufacturing specifications for optical fiber for use in state of the art systems have rigid requirements for DMD. The DMD specification within a given optical fiber core radius is called mask width. For example, fibers with DMD of less than 0.23 ps/m within a core radius of 18 microns are referred to as having a mask width within the 18 micron radius of <0.23 ps/m. This may also be expressed as MW 18<0.23 ps/m. These mask width specifications correspond to an optical fiber having an
E
ffective
M
odal
B
andwidth (EMB) of 2000 MHz-km at 850-nm, and optical fibers meeting these mask width specifications typically have overfilled bandwidths >500 MHz-km at 1300-nm. 850-nm and 1300-nm are typical wavelengths of choice for multimode optical systems. Manufacturing multimode optical fiber to meet these specifications has proven difficult.
It is known that short range refractive index variations, or perturbations, cause mode mixing, which has the effect of averaging the transmission distance for all modes traversing the optical fiber. Techniques for enhancing mode mixing have been sought by workers in the art to address adverse DMD. One of these is described in U.S. patent application Ser. No. 847,034 filed May 1, 2001 by DiGiovanni et al., which is incorporated by reference herein in its entirety. In that approach the fiber core is made non-circular, and the optical fiber is twisted during draw. Significant increases in bandwidth result. However, there is always a quest for further improvements in multimode optical fiber bandwidth.
STATEMENT OF THE INVENTION
We have developed multimode optical fiber that satisfies current bandwidth needs and has promise for meeting future high-speed Ethernet protocols. It is known from prior work, e.g. the patent referenced above, that short range refractive index variations, or perturbations, in a multimode optical fiber can result in enhanced mode mixing. These perturbations exist as inherent “defects” even in high quality optical fiber. We have recognized the ubiquitous nature of these perturbations, as well as the fact that to be optimally effective they should be randomized along the path lengths of the various modes traversing the fiber. Following this recognition we have demonstrated that DMD in multimode optical fibers with cores regarded as essentially circular can be reduced by adding twist to the optical fiber as it is drawn.
The invention will be described in greater detail with the aid of the drawing.
REFERENCES:
patent: 5298047 (1994-03-01), Hart et al.
patent: 5581647 (1996-12-01), Onishi et al.
patent: 5704960 (1998-01-01), Evans et al.
patent: 5868815 (1999-02-01), DiGiovanni et al.
patent: 5897680 (1999-04-01), Geertman
patent: 6076376 (2000-06-01), Onishi et al.
patent: 6240748 (2001-06-01), Henderson et al.
patent: 6422043 (2002-07-01), DiGiovanni et al.
patent: 6550283 (2003-04-01), Blaszyk et al.
patent: 6597853 (2003-07-01), Cabot et al.
patent: 2001-220168 (2001-08-01), None
DiGiovanni David John
DiMarcello Frank Vincent
Jiang XinLi
Oulundsen George E.
Pandit Sandeep Prabhakar
Furukawa Electric North America Inc
Griffin Steven P.
Lopez Carlos
Wilde Peter V. D.
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