Optical waveguides – With optical coupler – Input/output coupler
Reexamination Certificate
1999-06-30
2001-09-18
Schuberg, Darren (Department: 2872)
Optical waveguides
With optical coupler
Input/output coupler
C359S570000, C065S017100, C065S029180
Reexamination Certificate
active
06292607
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to aging of a grating built in an optical waveguide, and more particularly to aging of a grating used as a filter, multi/demultiplexer, dispersion-compensator, and the like in an optical fiber network. The present invention also relates to a temperature sensor including an optical waveguide grating as a sensing section.
2. Related Background Art
An optical waveguide type grating, which is typified by an optical fiber grating, is a region in an optical waveguide such as an optical fiber (mostly in its core portion) in which a periodic change of refractive index along the longitudinal direction of the waveguide occurs. The region where the refractive index changes can transmit or reflect propagated light depending on its wavelength. In particular, a Bragg grating generates reflected light with a narrow wavelength band centered on its Bragg wavelength. The optical waveguide grating is applied to various optical elements such as filters, multi/demultiplexers, dispersion-compensators, and the like.
FIG. 1
is a view showing a typical method for producing an optical waveguide grating. As shown in
FIG. 1
, a grating
20
is often formed by a method comprising preparing a silica-based optical fiber
10
in which GeO
2
(germanium dioxide) is added to at least its core region; irradiating this optical fiber
10
with an interference fringe formed by light rays
30
having a predetermined wavelength; and generating a change in refractive index independent on the optical energy intensity distribution of this interference fringe. Since the optical fiber
10
is usually coated with a plastic layer (not shown), a part of the coating is removed, and thus exposed part of the optical fiber
10
is irradiated with the light rays
30
. It has been considered that the irradiation with a certain wavelength of light generates Ge-defects in the GeO
x
-doped portion in the silica-based optical waveguide, thereby causing the change in refractive index. In
FIG. 1
, numeral
22
indicates parts where a larger amount of increase in refractive index is induced upon the irradiation, whereas numeral
24
indicates parts where a smaller amount of increase in refractive index is induced. The grating
20
may be considered to be a region where the parts
22
and
24
are alternatively and periodically disposed along the longitudinal direction of the optical fiber
10
.
An optical waveguide grating may be used as a temperature sensor also. The temperature sensor comprises an optical waveguide grating as a sensing section, and measures temperature utilizing the temperature dependence of the Bragg wavelength. More particularly, in the measurement of temperature, the sensor measures the Bragg wavelength and compares the measured value with the temperature dependence of the Bragg wavelength previously measured to determine the temperature.
As is previously known, the characteristics of an optical waveguide grating change over time because the number of Ge-defects generated by the irradiation of light changes over time. This has been known as aged deterioration of an optical waveguide grating. With respect to a Bragg grating, the Bragg wavelength at any temperature changes (usually decreases) over time. It means that the operating characteristics of a temperature sensor comprising an optical waveguide Bragg grating as its sensing section change over time. For example, if such a temporal change is relatively rapid, different Bragg wavelengths are measured for the same temperature one month and three months after beginning to use the temperature sensor, and thus different temperatures will be determined at different points in time. In view of the foregoing, there have been proposed techniques which perform accelerated aging for an optical waveguide grating immediately after its manufacture to sufficiently suppress its aged deterioration upon operation in the market. Examples of such techniques are disclosed in U.S. Pat. Nos. 5,287,427 and 5,620,496 which are incorporated herein by reference.
In the technique disclosed in U.S. Pat. No. 5,620,496, normalized refractive index difference &eegr; is supposed to be represented by the following relational expression:
η
=
1
1
+
C
·
t
α
(
1
)
where t represents time, and C and &agr; are functions of temperature. The normalized refractive index difference &eegr; is a value of the refractive index difference of a grating when time t has elapsed from a predetermined point of time (i.e., reference time) after formation of the grating, and this value is normalized with respect to the refractive index difference of the grating at this point of time. Namely, &eegr;=(refractive index difference at t after the reference time)/(refractive index difference at the reference time). In the technique disclosed in the above patent, the time immediately after formation of a grating is adopted as the reference time. The refractive index difference refers to the difference between the maximum and minimum values of the refractive index in a grating.
In the conventional techniques, from the fact that &eegr; changes more rapidly as temperature is higher, the optical fiber grating is heat-treated in an environment with temperature higher than its operating temperature to perform the accelerated aging, in order to suppress the deterioration upon its operation.
SUMMARY OF THE INVENTION
Having studied the conventional techniques mentioned above, the inventors have found the following problems. Namely, in the above-mentioned conventional techniques, since expression (1) which represents the temporal change in normalized refractive index difference &eegr; has the relatively complicated form and the two parameters of C and &agr; depend on temperature, it is difficult to determine the temperature and time of the heat treatment for the aging. In effect, the above-mentioned patents do not fully disclose such conditions of the aging.
It is an object of the present invention to provide a method by which a condition of aging may be determined more easily.
More specifically, the method in accordance with the present invention comprises setting the aged deterioration curve of an optical waveguide grating as a form of C·t
−&agr;
, where t represents time, and C and &agr; represent parameters; and a step of determining a condition of aging according to said aged deterioration curve. The aging condition can be determined more easily because the form of the aged deterioration curve that is proportional to t
−&agr;
is simpler than that in the prior art. Parameter a may be represented as follows:
&agr;=&agr;0·exp(−E
&agr;
/T)
where &agr;0 and E
&agr;
are constants, and T is absolute temperature. Since these expressions can represent aged deterioration of an optical waveguide grating with sufficient accuracy, these expressions may be used to determine an aging condition adequately.
Parameter C may be represented as follows:
C=&tgr;
&agr;
=[&tgr;0·exp(−E
&tgr;
/T)]
&agr;
where &tgr;0 and E
&tgr;
are constants, and T is absolute temperature. This expression provides a good representation of aged deterioration of an optical waveguide grating at high temperature. Therefore, the expression may be used to determine an aging condition for an optical waveguide grating adequately even if the grating is used in relatively high temperature environment.
In one embodiment, parameter C may be regarded as a constant. In this case, the expression of the aged deterioration curve may include only one parameter dependent on temperature, i.e., &agr;, and thus the aging condition can be determined still more easily.
Further, in one embodiment, the value &eegr;1 of the normalized refractive index difference at the completion of the aging may be determined as the aging condition. The temperature T1 and time t1 of the heat treatment for the aging can be determined from the value &eegr;1.
Another aspect of the present invention includes a method for making an optical waveguid
Inoue Akira
Ishikawa Shinji
Iwashima Toru
Shigehara Masakazu
Takushima (nee Harumoto) Michiko
Pillsbury & Winthrop LLP
Schuberg Darren
Sumitomo Electric Industries
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