Coherent light generators – Optical fiber laser
Reexamination Certificate
1999-08-06
2002-08-13
Scott, Jr., Leon (Department: 2828)
Coherent light generators
Optical fiber laser
C372S003000, C372S092000, C372S102000, C385S037000
Reexamination Certificate
active
06434172
ABSTRACT:
FIELD OF THE INVENTION
This invention pertains to articles (e.g., an optical fiber communication system, or a light source or amplifier for such a system) that comprise an optical fiber Raman device.
BACKGROUND
Optical fiber Raman lasers and amplifiers (collectively “fiber Raman devices”) are known. See, for instance, U.S. Pat. No. 5,323,404 for exemplary embodiments of fiber Raman devices of a first (topologically linear) type, with fiber gratings acting as wavelength-selective elements.
For a second type of fiber Raman laser (topologically circular), see for instance, S. V. Chernikov et al.,
Electronics Letters
, Vol. 34(7), April 1998, pp. 680-681. This embodiment uses fused fiber couplers as wavelength-selective element to form a ring cavity. All cited references are incorporated herein by reference.
An optical fiber Raman device can be used to provide pump light (exemplarily of wavelength 1480 nm) to an Er-doped fiber amplifier (EDFA), or can be used to amplify signal light (e.g., at 1310 nm).
FIG. 1
schematically depicts a prior art fiber Raman laser
10
of the topologically linear type, suitable for pumping of an EDFA. Cladding pumped fiber laser (CPFL)
11
provides pump light of a predetermined wavelength (e.g., 1117 nm) to the Raman laser. Raman fiber
12
typically is a silica-based fiber with Ge-doped core, and typically is hundreds of meters long. Numerals
13
and
14
refer to the upstream and downstream grating sets, respectively. It will be appreciated that in a schematically depicted grating set herein each cross-line indicates a separate grating. The upstream set
13
typically comprises only high reflectivity (HR) gratings (exemplarily of center wavelengths 1175, 1240, 1315, 1395, and 1480 nm), and the downstream set
14
typically comprises, in addition to the HR gratings, also a grating of relatively low reflectivity, to provide output coupling. By way of example, the downstream gratings have center wavelengths 1117, 1175, 1240, 1315, 1395 and 1480 nm, with the 1117 nm grating serving as pump reflector. The output coupler has center wavelength corresponding to the desired output wavelength, exemplarily 1480 nm.
CPFLs are known, and are commercially available. See for instance, U.S. patent applications Ser. Nos. 08/897,195 and 08/999,429, respectively filed Jul. 21, 1997 and Dec. 29, 1997 by DiGiovanni et al. Briefly, a CPFL comprises several high power light emitting diodes (exemplarily InGaAlAs diodes). The output of each LED is coupled into a multimode fiber, e.g., a silica-based fiber with 0.22 N.A., 105 &mgr;am core and 125 &mgr;m outside diameter. The fibers are arranged into a bundle, fused together and tapered, as described, for instance, in US patent application Ser. No. 09/315,631, filed May 20, 1999 by D. J. DiGiovanni et al.
To date it has not been convenient to form tapered bundles of more than seven multimode fibers. This has limited the number of pump sources to seven, and has correspondingly limited the power that can conveniently be provided to utilization means, e.g., the EDFA.
It clearly would be desirable to be able to conveniently provide to the fiber Raman device pump light from more than seven LEDs. This application discloses an article that comprises a fiber Raman device that is pumped with light from more than seven pump LEDs, exemplarily 14 pump LEDs.
DEFINITIONS AND GLOSSARY OF TERMS
The terms “light” and “radiation” are used herein interchangeably for electromagnetic radiation of interest herein, typically infrared radiation.
Optical fiber gratings and fused fiber couplers are herein collectively referred to as “wavelength-selective elements”. A fused fiber coupler is frequently referred to as a “WDM”.
The “Raman spectrum” of an optical fiber is the scattered intensity as a function of wavelength difference from an incident radiation. A shift to longer wavelength is generally referred to as a Stokes shift. Conventionally, the Stokes shift is expressed in inverse centimeters (cm
−1
), but it can also be expressed in terms of wavelengths.
The Raman spectrum of germano-silicate glass is relatively broad, with a pronounced maximum at a Stokes shift of about 440 cm
−1
, relative to the wavelength of the pump light. See
FIG. 2
herein, which shows the Raman spectrum for pump light of 1427 nm.
A wavelength-selective element in a Raman device that is responsive to a given pump light is herein referred to as being “on resonance” (with respect to the pump light), and an element that is not responsive to the given pump light is herein referred to as being “off resonance” (with respect to the pump light).
A wavelength-selective element is “responsive” to a given pump light if the elementlight interaction is at or near maximum, for instance, if the pump light is within the wavelength range wherein the reflectivity of the grating is 50% or more of the maximum reflectivity of the grating, or wherein the coupling strength of a fiber coupler (WDM) is 50% or more of the maximum coupling strength of the coupler.
SUMMARY OF THE INVENTION
In a broad aspect, the invention is embodied in an optical fiber communication system or other article that comprises an optical fiber Raman device that is adapted for utilizing high pump power.
The Raman device comprises a length of silica-based optical fiber comprising at least a first and a second wavelength-selective element disposed to provide one or more optical cavities for Raman-shifting of light in said optical fiber, and further comprises a first coupler for coupling pump radiation of a first wavelength &lgr;
1
from a first pump radiation source into said optical fiber, and still further comprises means for providing a Raman-shifted Raman device output radiation of wavelength &lgr;
0
greater than &lgr;
1
to output radiation utilization means. Significantly, the fiber Raman device further comprises a second coupler for coupling pump radiation of a second wavelength &lgr;
2
from a second pump radiation source into said optical fiber, where &lgr;
2
is different from &lgr;
1
, with &lgr;
0
>&lgr;
2
, wherein at least one of said wavelength-selective elements is off resonance with regard to at least one of &lgr;
1
, and &lgr;
2.
If the fiber Raman device is a topologically linear Raman laser then the first and second wavelength selective elements typically are fiber gratings, and the means for providing the output radiation to utilization means exemplarily comprise an output coupler of relatively low reflectivity. If the device is a topologically circular Raman laser then the wavelength selective elements typically are fiber couplers (WDMs), and the means for providing the output radiation typically also comprise a WDM.
If the fiber Raman device is a topologically linear Raman amplifier then the wavelength selective elements typically are fiber gratings, and the means for providing the output radiation to utilization means comprise a high-reflectivity optical cavity for radiation that is one Stokes shift from a signal radiation. If the device is a topologically circular Raman amplifier then the wavelength selective elements typically are WDMs, and the means for providing the output radiation typically also comprise a WDM.
If the Raman device is a topologically linear Raman device then |&lgr;
1
−&lgr;
2
| typically is greater than 0.2 nm, and if the Raman device is a topologically circular Raman device then |&lgr;
1
−&lgr;
2
| typically is greater than about 3 nm.
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Chernikov et al,Electronics Letters, v
DiGiovanni David John
Inniss Daryl
Jameson Ralph Stephen
Kosinski Sandra Greenberg
Fitel USA Corp.
Jr. Leon Scott
Pacher E.
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