JP4484021B2 - Multi-wavelength light source - Google Patents

Description

  The present invention relates to a multi-wavelength light source, and more particularly to a multi-wavelength light source that can continuously supply light having a plurality of wavelengths with a constant frequency interval.

Along with the demand for an increase in communication capacity, wavelength division multiplexing optical communication has been developed in which a large number of signals are assigned to light of a number of different wavelengths and transmitted through a single optical fiber.
In a wavelength division multiplexing optical transmission system, a light source that supplies a large number of wavelengths with a certain frequency interval is required, and in the measurement and inspection of various optical components used in the wavelength division multiplexing optical transmission system, a similar light source is necessary. Become.
As such a light source that supplies a large number of wavelength lights (hereinafter referred to as a multi-wavelength light source), a technique that collects and uses a plurality of laser light sources that oscillate different wavelength lights, or Patent Document 1, on the same chip A multi-wavelength semiconductor laser light source has been invented in which a large number of semiconductor lasers having slightly different oscillation wavelengths are integrated.
JP-A-5-102613

However, when a large number of laser light sources are arranged as described above, a light source that supplies light of several tens of different wavelengths requires a large multi-wavelength light source device, and each laser light source must be individually adjusted. Therefore, there is a problem that handling becomes complicated.
In addition, the multiwavelength semiconductor laser light source has a problem that it is difficult to precisely control the frequency interval between individual lasers.
Furthermore, in the measurement and inspection of optical components, it is necessary to investigate the characteristics at each wavelength used in wavelength division multiplexing communication. For example, a variable wavelength laser light source is prepared and measured while adjusting to a desired wavelength. There was a drawback that inspection took time.

  The present invention has been made to solve the above-described problems. In particular, a single or a small number of light sources are used to simultaneously supply continuous light of a large number of wavelengths having a precisely controlled constant frequency interval. It is to provide a possible multi-wavelength light source.

The invention according to claim 1 optically couples a light source unit including a laser light source, an optical circulation unit including an SSB optical modulator, an output unit including a demultiplexing element, and the light source unit and the optical circulation unit. to the optical coupler, a multi-wavelength light source Do that from the optical coupler for coupling the light circulating unit and the output unit optically, light coupled to the light source unit and the light circulating unit optically The coupler is composed of an optical circulator and an optical fiber grating arranged in the optical circulator. The optical circulator is optically coupled to the light source, and the fiber grating is connected to the optical circulator. The multi-wavelength light source is arranged on the upstream side .

  The invention according to claim 2 is the multi-wavelength light source according to claim 1, wherein the light source unit combines single wavelength light from a single mode laser light source or laser light sources having a plurality of different wavelengths. It is characterized in that it is configured to supply any one of the multi-wavelength lights.

  The invention according to claim 3 is the multi-wavelength light source according to claim 1 or 2, characterized in that an optical amplifier is provided in the optical circulation section.

  According to a fourth aspect of the present invention, in the multi-wavelength light source according to any one of the first to third aspects, light that transmits light in a wavelength range that can be demultiplexed by the demultiplexing element is transmitted to the optical circulation unit. A filter is provided.

  According to a fifth aspect of the present invention, in the multiwavelength light source according to any one of the first to fourth aspects, the branching element is formed of an arrayed waveguide grating.

The invention according to claim 6 is the multi-wavelength light source according to any one of claims 1 to 5, an optical coupler for optically coupling with said light circulator portion and the light output unit, an optical fiber coupler It is characterized by being configured.

The invention according to claim 7 is the multi-wavelength light source according to any one of claims 1 to 6 , wherein the connection between the light source unit and the optical circulation unit, the connection of optical components in the optical circulation unit, and the A single mode optical fiber is used for connection between the optical circulation unit and the output unit, and a polarization controller is provided in the light source unit and the optical circulation unit.

The invention according to claim 8 is the multi-wavelength light source according to any one of claims 1 to 7 , wherein the connection between the light source unit and the optical circulation unit, the connection of optical components in the optical circulation unit, and the A polarization maintaining optical fiber is used for connection between the optical circulation unit and the output unit, and an optical coupler having a polarization maintaining function is used for the optical coupler.

The invention according to claim 9 is the multi-wavelength light source according to any one of claims 1 to 8 , wherein the frequency interval Δf of the light demultiplexed by the demultiplexing element is applied to the SSB optical modulator. It is characterized by being set to an integral multiple of the frequency f.

The invention according to claim 10 is the multiwavelength light source according to any one of claims 1 to 9 , wherein the light can be emitted from the branching element by changing a frequency applied to the SSB optical modulator. Each light wave is selectively switched to an emission state or a non-emission state.

According to the first aspect of the present invention, the specific wavelength light supplied from the laser light source is repeatedly passed through the SSB optical modulator in the optical circulation unit including the SSB optical modulator, so that a precisely controlled constant frequency interval is obtained. It becomes possible to generate continuous light having multiple wavelengths.
In addition, it is possible to separate the light waves having the required wavelengths from the light waves in which a plurality of wavelengths are mixed, and to output them individually by the demultiplexing element of the output unit. Moreover, even if the SSB optical modulator cannot be modulated at a high speed at a frequency corresponding to the required wavelength interval, a large number of lights having a wavelength interval less than the required wavelength are generated, and only the necessary wavelength is selected from the many wavelengths. Can be selected and output externally.
Furthermore, since the optical coupler that optically couples the light source unit and the optical circulation unit is configured by an optical component including an optical circulator and an optical fiber grating, the coupling unit between the light source unit and the optical circulation unit includes an optical circulator. The input light wave is introduced into the optical fiber grating, only the necessary wavelength light is selected, returned to the optical circulator, and the return light can be introduced into the optical circulation unit. Thereby, only a required wavelength can be efficiently introduced from the light source unit to the optical circulation unit.
An optical circulator has a characteristic of always deriving light incident from a specific port to a predetermined port, and an optical fiber grating has the same characteristics as an ordinary optical fiber for light waves other than a specific wavelength. Even if optical fiber gratings are arranged in the optical path of the optical circulation section, the propagation of light waves having a large number of wavelengths generated by the SSB optical modulator is not disturbed, and the optical loss is suppressed in the optical circulation section by suppressing optical loss. It becomes possible to confine light.

  According to the second aspect of the present invention, the light circulation unit including the SSB optical modulator can generate continuous light having a plurality of wavelengths having a constant frequency interval from a single wavelength. Multiple wavelengths can be generated simply by providing a single-mode laser light source. In addition, by utilizing a laser light source having a plurality of different wavelengths, by superimposing light having a number of wavelengths generated at a specific wavelength with light having a number of wavelengths generated at another specific wavelength, It is possible to increase the number of generated wavelengths, expand the wavelength band, or subdivide the frequency interval. In addition, when the specific wavelength and the wavelength generated at another specific wavelength overlap, the light intensity can be increased.

  According to the third aspect of the invention, since the optical circulation unit has an optical amplifier, it is possible to compensate for the attenuation of the light intensity of the sideband spectrum generated by the SSB optical modulator. For this reason, even if light having many wavelengths is generated from a specific wavelength by the SSB optical modulator, the light intensity of the generated light can be maintained at a predetermined level or more.

  According to the invention of claim 4, the optical filter provided in the optical circulation unit limits the light wave passing through the optical circulation unit including the SSB optical modulator to light in a wavelength range that can be demultiplexed by the demultiplexing element. Therefore, it is possible to suppress noise contained in light waves emitted from the multi-wavelength light source without generating light waves outside the necessary wavelength range.

  According to the invention of claim 5, since the demultiplexing element is composed of an arrayed waveguide grating, it is possible to efficiently select only the necessary wavelengths from the light waves in which a large number of wavelengths are mixed and output them to the outside. Become.

According to the sixth aspect of the present invention, since the optical coupler that couples the optical circulation unit and the output unit is constituted by an optical fiber coupler, the entire apparatus can be made more compact.

According to the seventh aspect of the present invention, a single mode optical fiber is used in the connection between the light source unit and the optical circuit unit, the connection of the optical components in the optical circuit unit, and the connection between the optical circuit unit and the output unit. Since the polarization controller is provided in the optical section and the optical circulation section, the polarization plane of the light wave incident on the SSB optical modulator can be adjusted, and the generation efficiency of the sideband spectrum by the SSB optical modulator can be improved. It becomes.

Further, according to the invention according to claim 8 , in the connection between the light source unit and the optical circuit unit, the connection of the optical components in the optical circuit unit, and the connection between the optical circuit unit and the output unit, the polarization maintaining optical fiber is used, Since an optical coupler having a polarization maintaining function is used for the optical coupler, the sideband spectrum generation efficiency by the SSB optical modulator can be improved as in the case of claim 7 .

According to the invention of claim 9 , since the frequency interval Δf of the light demultiplexed by the demultiplexing element is set to an integral multiple of the frequency f applied to the SSB optical modulator, it can be transmitted by the demultiplexing element. Wavelength light can be efficiently generated by the SSB optical modulator.
Further, by selecting a frequency f that satisfies the above conditions, even an SSB optical modulator that is difficult to perform high-speed modulation corresponding to the frequency Δf can be used for the multi-wavelength light source according to the present invention.

Since the invention according to Claim 10, by changing the frequency applied to the SSB optical modulator, it is possible to selectively switching each capable of emitting light waves from該分wave device, for example, multi-wavelength light source In the case of switching the emission or non-emission state of the light wave from the optical switch, it is not necessary to separately install an optical switch on the optical path of the output part of the multi-wavelength light source. For this reason, not only the entire apparatus of the multi-wavelength light source can be made compact, but also the emission or non-emission state can be switched at a high speed at a speed at which the frequency applied to the SSB optical modulator is changed.

FIG. 1 is a diagram showing a basic concept of a multi-wavelength light source according to the present invention.
A light source unit A that supplies a light wave of a specific wavelength like a laser light source, and a propagating light wave forms a circular optical path, and a single side band (SSB) light modulation is performed on the optical path of the circular circuit. And an output circuit C including a demultiplexing element for separating a specific wavelength from light waves including a plurality of wavelengths and outputting them to the outside.

As a light source A, if there is one single mode laser light source, continuous light having a number of wavelengths having a precisely controlled constant frequency interval is generated by a sideband spectrum generated by an SSB optical modulator described below. Can be generated.
Further, by using laser light sources having a plurality of different wavelengths, it is possible to superimpose light having a large number of wavelengths generated by the SSB optical modulator for each laser light source.

Here, the light lambda _1-1 having a plurality of wavelengths generated from the wavelength lambda ₁ of the light source, lambda _1-2, lambda _1-3, · · ·, and lambda _1-n, the wavelength lambda ₂ of the light source Let λ _2-1 , λ _2-2 , λ _2-3 ,..., Λ _2-n be generated light having multiple wavelengths. However, it is assumed that λ ₁ > λ _1-n and λ ₂ > λ _{2 -n} .
Depending on the setting state of λ ₁ and λ _2, the state of the light wave that is finally output from the light circulating unit B differs. For example, when the relationship of λ ₁ > λ ₂ > λ _1-1 is set, _{λ 1> λ 2> λ 1-1} > λ 2-1 ···· λ 1-n> λ 2-n , and the comparison with the case of a single wavelength only, subdivided frequency intervals light circulating unit generates To play a role.

Also, by setting λ _1-n > λ ₂ , λ ₁ > λ _1-1 > λ _1-2 > λ _1-3 ...> Λ _1-n > λ ₂ > λ _2-1 > λ _2-2 > λ _2-3 ...> Λ _2-n , and it is possible to expand the wavelength band of the light wave emitted from the optical circulation unit as compared with the case of only a single wavelength. However, even when only a single wavelength is used, it is possible to generate an infinite sideband spectrum in accordance with the number of light waves that pass through the SSB optical modulator. However, the number of times the light wave passes through the SSB optical modulator is naturally limited. Here, the limit value that can be used is indicated by λ _1-n , for example.

Furthermore, by setting λ _1-1 = λ ₂ , λ ₁ > λ ₂ = λ _1-1 > λ _2-1 = λ _1-2 ...> Λ _1-n = λ _2-n For light waves having overlapping wavelengths, the light intensity can be increased.

In addition, when using the laser light source which has several different wavelengths, it is necessary to comprise so that it may supply to the optical circulation part B in the state combined with one optical fiber.
In addition, the light source unit A is provided with a polarization controller in order to arrange an isolator on the optical path of the emitted light and to adjust the polarization plane of the light wave emitted from the light source unit A so that the laser beam does not re-enter the laser light source. It is also possible to arrange on the optical path of laser light.

Next, a single sideband (SSB) optical modulator used for the optical circuit B will be described.
FIG. 2 shows the operation of the SSB optical modulator.
Paper "Optical SSB-SC modulator using X-cut LiNbO3" (Nippon, 4 others, p.17-21, "Sumitomo Osaka Cement Technical Report 2002 Edition", published by Sumitomo Osaka Cement Co., Ltd., New Technology Research Laboratory) As described in detail in Non-Patent Document 1 above, the SSB optical modulator operates by applying a microwave from a normal signal generator. For example, if the microwave frequency is f, the light incident on the SSB optical modulator is shifted in frequency by f. As shown in FIG. 2, the frequency f0 of the incident light becomes f0 + f after passing through the SSB optical modulator. This output light is called a sideband spectrum. Thus, the SSB optical modulator operates as a light frequency shifter. Note that the frequency of the output light can be shifted in the negative direction, such as f0-f, depending on how microwaves are added to the SSB optical modulator.

Further, in the optical circulation part B, the optical wave propagating is set so as to draw a circular optical path by using an optical component such as a waveguide formed on an optical fiber or a substrate or a lens, a mirror, and the like. The operation when the SSB optical modulator is arranged on the optical path will be described.
As shown in FIG. 3, when the frequency of the light wave propagating through the light circulation unit is first set to f ₀ (0 turn), the frequency of the light wave that has passed through the SSB optical modulator for the first time is f ₀ + f (1 time Lap). Similarly, the second and third times are f ₀ + 2f and f ₀ + 3f, and light waves having many wavelengths can be generated at the same frequency interval f.

Since a light wave having a specific wavelength is continuously supplied from the light source unit A to the light circulation unit B, light waves having a large number of wavelengths as shown in FIG. It will exist at the same time.
In general, the sideband spectrum generated by the SSB optical modulator has a light intensity lower than that of a light wave input to the SSB optical modulator. For this reason, by arranging an optical amplifier on the optical path that the optical circuit B circulates, the decrease in the light intensity of the sideband spectrum is compensated for and the light intensity that can be used as a multi-wavelength light source is ensured.

Furthermore, an optical filter can be provided on the optical path that the optical circuit B circulates in correspondence with the wavelength range of the light that is demultiplexed by the demultiplexing element provided in the output unit.
By matching the transmission wavelength range of this optical filter with the wavelength range that can be demultiplexed by the demultiplexing element, as shown in FIG. 3, the wavelength of the light wave that circulates the optical circulation unit is limited, and the required wavelength range. It is possible to suppress noise included in the light wave finally emitted from the multi-wavelength light source without generating any other light wave.

  In addition, on the optical path that the optical circuit B circulates, an isolator for suppressing the light wave that reenters the SSB optical modulator from the opposite direction, or the polarization plane of the optical wave so that the modulation efficiency of the SSB optical modulator is increased. It is also possible to arrange a polarization controller for adjusting.

Next, the demultiplexing element used for the output unit C will be described.
As the demultiplexing element, various demultiplexing elements can be used as long as a specific wavelength can be separated from light waves including a large number of wavelengths, but an arrayed waveguide grating is preferable.
The arrayed waveguide grating is, for example, a quartz-based waveguide circuit formed on a Si substrate as in Patent Document 2, and is composed of a number of waveguide arrays and slab waveguides as shown in FIG. Has been.
When light having a plurality of wavelengths (light waves including frequencies f ₀ ,..., F _n−1 ) is incident on the input waveguide to the arrayed waveguide grating, light is output from different waveguides corresponding to the respective wavelengths. Is done.
That is, the arrayed waveguide grating operates as an optical demultiplexer. At this time, light of a predetermined frequency that is different at equal intervals is output from the n output waveguides.

The polyimide half-wave plate shown in FIG. 4 is provided for adjusting the demultiplexing characteristics of the arrayed waveguide grating, and is not necessarily required.
Other methods for adjusting the demultiplexing characteristics of the arrayed waveguide grating include a method of forming a film such as optical glass on the slab waveguide and applying mechanical stress to the waveguide.
In addition, since the light wave output from the optical circuit B includes a number of wavelengths having a precisely controlled constant frequency interval, when adjusting the demultiplexing characteristics of the arrayed waveguide grating It is preferable to adjust the arrayed waveguide grating while inputting the lightwaves from the circular portion B to the arrayed waveguide grating and measuring the lightwaves emitted from the output waveguides of the arrayed waveguide grating.

The relationship between the frequency interval Δf of light waves emitted from the arrayed waveguide grating, which is a demultiplexing element, and the frequency f applied to the SSB optical modulator will be described.
In the case of Δf = f, the light wave having a large number of wavelengths generated by the SSB optical modulator is demultiplexed by the arrayed waveguide grating and output to the outside without waste. Therefore, the light wave generated by the optical circuit B Use efficiency is the highest.
However, the frequency interval of multi-wavelength light used in normal optical communication is very high, for example, about 50 GHz, and it is difficult to maintain stable light modulation.
Therefore, by adjusting the frequency applied to the SSB optical modulator so as to satisfy the relationship of Δf = mf (m is an integer), light waves having a large number of wavelengths generated by the SSB optical modulator are selected. , Light waves generated at a ratio of 1 / m can be output to the outside by the arrayed waveguide grating.

In order to selectively switch the output light emitted from the output unit C to the emission or non-emission state, it can be controlled by arranging an optical switch on the optical path of the output light of the arrayed waveguide grating. The frequency f applied to the SSB optical modulator can also be controlled by shifting it from the state of Δf = mf.
That is, when f is shifted by 1/10 and a frequency of 1.1f is applied to the SSB optical modulator, only the light wave having a wavelength corresponding to Δf of 10 times or 20 times from the arrayed waveguide grating. Is emitted from the 10th or 20th output waveguide. Then, the other light waves generated by the SSB optical modulator are inconsistent with the wavelength demultiplexed by the arrayed waveguide grating, and are not emitted.
Further, when f is shifted by 1/100 to 1.01f, in the arrayed waveguide grating having 20 output waveguides, no output light is emitted, and all wavelengths are in a non-emission state. Become.

Next, a method of optical coupling between the light source unit A and the light circulating unit B or between the light circulating unit B and the output unit C will be described.
For these optical couplings, optical couplers known in the art can be used.
In particular, in order to reduce the manufacturing cost and reduce the overall size of the apparatus, the optical coupler that couples the light source unit and the optical circulating unit and the optical coupler that couples the optical circulating unit and the output unit are shared, It is preferable to reduce the number of optical components used.
Specific examples will be described below. For such an optical coupler, an optical fiber coupler, a combination of an optical circulator and an optical fiber grating, or the like can be used.

In addition, since the SSB optical modulator used in the optical circulating unit B and the arrayed waveguide grating used in the output unit C have polarization dependency, the light source unit A and the optical circulating unit B, or the optical circulating unit In the optical coupling between the part B and the output part C, and in the optical coupling in each member such as connection of optical components in the optical circulation unit, it is preferable to appropriately adjust the polarization plane.
Therefore, in these connections, a single mode optical fiber is used, and a polarization controller is provided in the light source unit A and the optical circuit B, or a polarization maintaining optical fiber is used in the connection, and the optical coupler is used. A method using an optical coupler having a polarization maintaining function is desirable.

Next, as a specific example, FIG. 5 shows a reference example.
The multi-wavelength light source according to the reference example includes three parts, ie, a light source unit (1A), an optical circulation unit (1B), and an output unit (1C), which are coupled by an optical coupler (104).
The light source unit (1A) includes a single mode laser (101), an isolator (102), and a polarization controller (103). The isolator (102) is installed to prevent the reflected return light from returning to the laser.

The optical circuit (1B) includes an SSB optical modulator (105), an isolator (108), an optical filter (109), an optical amplifier (107), a polarization controller (115), and a single mode optical fiber (112) connecting them. ) Or polarization maintaining fiber. Note that when a polarization maintaining fiber is used, a polarization controller is not necessary.
The single sideband optical modulator (105) is driven by a signal generator (106). The output section (1C) includes an arrayed waveguide grating (110) and an optical switch (111). As described above, the optical switch is not always necessary depending on the application.

Next, the operation of the multi-wavelength light source according to the reference example will be described.
The light emitted from the single mode laser (101) having the oscillation frequency f ₀ is converted into an appropriate polarization state by the polarization controller (103) through the isolator (102), and is then transmitted by the optical coupler (104). The light is branched into an optical loop on the side of the loop (1B) and an arrayed waveguide grating on the side of the output (1C). By adjusting the branching ratio to both, it is possible to adjust the light intensity between the wavelengths of the output light, in particular, the frequency f ₀ and other frequencies (f ₀ + f etc.).

The light having the frequency f ₀ incident on the arrayed waveguide grating (110) is demultiplexed into the first channel by the arrayed waveguide grating.
On the other hand, the SSB modulator (105) in the optical loop is driven by a signal generator (106) that oscillates the modulation frequency f. Therefore, the light (frequency f ₀ ) incident on the optical loop is shifted by the frequency f by the SSB modulator and converted to light having a frequency of (f ₀ + f).

  The converted light passes through the isolator (108) and the optical filter (109), is amplified by the optical amplifier (107), and then is converted into an appropriate polarization state by the polarization controller (115), and goes around the optical loop. In the optical coupler (104), a part of the light wave is again guided to the arrayed waveguide grating, and the rest circulates in the optical loop again.

Since the light guided to the arrayed waveguide grating (110) has a frequency of (f ₀ + f), it is demultiplexed into the second channel.
Here, in order to simplify the description, the frequency interval Δf of the light waves to be demultiplexed by the arrayed waveguide grating is set to be equal to the modulation frequency f of the SSB optical modulator (Δf = f). For this reason, in the arrayed waveguide grating, light is demultiplexed into each channel at intervals of the frequency f.
As described above, the values of Δf and f can be set so as to satisfy the condition of Δf = mf (m is an integer).

On the other hand, the light that has entered the optical loop again undergoes frequency shift again by the SSB modulator (105), and is converted into light having a frequency of (f ₀ + 2f). After optical amplification again, a part of the light is guided to the arrayed waveguide grating (110) by the optical coupler (104) and is demultiplexed into the third channel.
The remaining part circulates in the optical loop and is converted into light having a frequency of (f ₀ + 3f).
By repeating these operations, the light is converted to a frequency of (f ₀ + (n−1) f) when it goes around the optical loop (n−1) times (n is an integer of 1 or more), and the arrayed waveguide A part guided to the grating is demultiplexed into the nth last channel.

Thereafter, the light guided to the optical loop is again converted to a frequency of (f ₀ + nf). However, since this light cannot pass through the optical filter, the circulation ends here. This is because the frequency characteristics of the optical filter, as shown in FIG. 3, light with a frequency of (f ₀ + (n−1) f) or less passes, but light with a frequency of (f ₀ + nf) or more passes. It is because it is set not to do.
When light goes around the optical loop n times or more, light having a frequency higher than (f ₀ + nf) is generated, and this becomes noise even if it enters the arrayed waveguide grating.

As a result of the above operation, since light is always supplied to the loop as continuous light from the single mode laser, light of n different wavelengths is always emitted from the arrayed waveguide grating.
Depending on the application, an optical switch (111) after the arrayed waveguide grating (110) can be provided to select any desired wavelength.
In the above description, the case where the frequency of light is increased by the SSB optical modulator has been described. However, the frequency of light can also be reduced by the setting method of the SSB optical modulator and the method of applying the modulation signal. A similar operation is possible.

Actually, a 25 GHz modulation signal was added to the SSB optical modulator, and a DFB (Distribution Feed-Back) semiconductor laser beam oscillating at 1561 nm was used as a starting light source, and an experiment was performed using an arrayed waveguide grating consisting of 20 channels at 50 GHz intervals. .
As a result, it was possible to accurately extract 20 waves of light at intervals of 50 GHz between 1561 nm and 1553 nm from each channel of the arrayed waveguide grating. When the intensity distribution of the optical spectrum from each channel was measured, the average output in each channel was −15 dBm, the variation was 3.5 dB, and the SN ratio was 13 dB.

Next, the actual施例in FIG.
As the optical coupler, as shown in FIG. 6, an optical fiber grating (114) and an optical circulator (113) were used, and the others were performed in the same system as in the first embodiment.
In this case, the reflection band of the optical fiber grating is on the short wavelength side including 1553 nm.
As in the reference example, a 25 GHz modulation signal is applied to the SSB optical modulator (105), and a DFB semiconductor laser beam oscillating at 1553 nm is used as a starting light source (101). ).
Here, the SSB optical modulator (105) is set so that the light frequency is reduced by 25 GHz.

The 1553 nm light emitted from the DFB semiconductor laser (101) of the light source unit (2A) is reflected by the optical fiber grating (114) through the optical circulator (113), and again passes through the optical circulator (113). Enter (2B).
Therefore, when the light is shifted to the 25 GHz long wavelength side by the SSB optical modulator (105) and then enters the optical fiber grating (114), the light passes as it is because it is on the long wavelength side from the reflection band.
By repeating this, the light circulates many times, and it becomes possible to generate a large number of light at 25 GHz intervals on the long wavelength side by the SSB optical modulator each time.
A part of these lights is led out to the output part (2C) side by the optical coupler (104), and enters the arrayed waveguide grating (110). The arrayed waveguide grating demultiplexes the incident light wave for each wavelength and outputs it from each channel.

Also in real施例, the light of 20 waves of precisely 50GHz interval between 1553.4nm of 1561 nm, could be removed from the channels of the arrayed waveguide grating.
Further, when the intensity distribution of the optical spectrum from each channel was measured, the average output in each channel was -13 dBm, the variation was 2.8 dB, and the SN ratio was 13 dB.

As described above, according to the present invention, it is possible to simultaneously supply continuous light having a number of wavelengths having a precisely controlled constant frequency interval, which has been difficult in the past. Moreover, the light source for generating these multi-wavelengths may be a single mode or a small number of laser light sources, and the entire apparatus of multi-wavelength light sources can be simplified and made compact even when compared with the conventional person. It becomes possible.
Furthermore, by using the multi-wavelength light source according to the present invention, it is possible to perform inspection of optical components for wavelength multiplexing transmission, measurement of a system, etc. in a short time with high accuracy.

It is a figure which shows the basic concept of the multiwavelength light source which concerns on this invention. It is a figure explaining the operation | movement condition of an SSB optical modulator. It is a figure explaining the state of the multiwavelength light which arises in an optical circulation part. It is a figure explaining the outline of an array waveguide grating. It is a figure explaining the reference example which concerns on this invention. Is a diagram illustrating the engagement Ru real施例the present invention.

Explanation of symbols

A, 1A, 2A Light source unit B, 1B, 2B Optical circuit unit C, 1C, 2C Output unit 101 Single mode laser 102 Isolator 103 Polarization controller 104 Optical coupler 105 SSB optical modulator 106 Signal generator 107 Optical amplifier 108 Isolator 109 optical filter,
DESCRIPTION OF SYMBOLS 110 Array waveguide grating 111 Optical switch 112 Single mode optical fiber 113 Optical circulator 114 Optical fiber grating 115 Polarization controller

Claims (10)

A light source unit including a laser light source; an optical circulation unit including an SSB optical modulator; an output unit including a demultiplexing element; an optical coupler that optically couples the light source unit and the optical circulation unit ; a circumferential portion and the output portion is a multi-wavelength light source Do that from the optical coupler for optically coupling,
An optical coupler that optically couples the light source unit and the optical circulation unit includes an optical circulator and an optical fiber grating disposed in the optical circulation unit, and the optical circulator is optically coupled to the light source unit. The multi-wavelength light source is characterized in that the fiber grating is disposed upstream of the optical circulation section with respect to the optical circulator.   2. The multi-wavelength light source according to claim 1, wherein the light source unit supplies either single-wavelength light from a single-mode laser light source or multi-wavelength light obtained by combining laser light sources having a plurality of different wavelengths. A multi-wavelength light source configured as described above.   3. The multi-wavelength light source according to claim 1, wherein the optical circulation unit includes an optical amplifier.   4. The multi-wavelength light source according to claim 1, wherein an optical filter that transmits light in a wavelength range that can be demultiplexed by the demultiplexing element is provided in the optical circulation unit. Multi-wavelength light source.   5. The multi-wavelength light source according to claim 1, wherein the branching element is formed of an arrayed waveguide grating. 6. In multi-wavelength light source according to any one of claims 1 to 5, an optical coupler for optically coupling with said light circulator unit and the output unit, multi, characterized in that it consists of an optical fiber coupler Wavelength light source. The multi-wavelength light source according to any one of claims 1 to 6 , wherein the connection between the light source section and the optical circulation section, the connection of optical components in the optical circulation section, and the connection between the optical circulation section and the output section. The multi-wavelength light source is characterized in that a single mode optical fiber is used and a polarization controller is provided in the light source section and the optical circulation section. The multi-wavelength light source according to any one of claims 1 to 7 , wherein the connection between the light source unit and the optical circulation unit, the connection of optical components in the optical circulation unit, and the connection between the optical circulation unit and the output unit. A multi-wavelength light source using a polarization maintaining optical fiber and using an optical coupler having a polarization maintaining function as the optical coupler. In multi-wavelength light source according to any one of claims 1 to 8, the frequency interval Δf of the light demultiplexed by該分wave element, set to an integer multiple of the frequency f to be applied to the SSB modulator A multi-wavelength light source. The multiwavelength light source according to any one of claims 1 to 9 , wherein each light wave that can be emitted from the branching element is emitted or not emitted by changing a frequency applied to the SSB optical modulator. A multi-wavelength light source characterized by being selectively switched to

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