JP2004093884A - Multiplexing/demultiplexing system of different wavelength multiplexing light, and optical amplifier and ase light source utilizing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical multiplexing/demultiplexing system which performs multiplexing and demultiplexing of different wavelength light of a number of wavelengths and which has high multiplexing efficiency in multiplexing, has high demultiplexing efficiency in demultiplexing, and has high degree of wavelength separation. <P>SOLUTION: The system includes a number of multiplexer/demultiplexers having evanescent coupling sections between two optical waveguides, in which the two branching terminals of the one multiplexer/demultiplexer are connected to the collection end of the multiplexer/demultiplexer of the next stage to optically connect the multiplexer/demultiplexers to ≥2 stages of tree structures. The system multiplexes or demultiplexes a number of the wavelength light having wavelength strings arrayed with the wavelength intervals Δλ between the respective adjacent signal light wavelengths. The wavelength band width expressed by the wavelength half period of the output characteristics of the respective stages of the multiplexer/demultiplexers viewed from the trunk side end to the branch side end of the tree structures is set substantially twice the wavelength band width of the output characteristics of the multiplexer/demultiplexer of the previous stage. In addition, the wavelength band width of the output characteristics of the multiplexer/demultiplexer of the initial stage is set substantially equal to the above wavelength intervals. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical multiplexing / demultiplexing apparatus for an optical multiplex transmission system that multiplexes a plurality of laser lights having different wavelengths or demultiplexes a combined wave into component light. The present invention also relates to a different wavelength optical multiplexer / demultiplexer that provides fiber amplification for amplifying signal light with a plurality of pump lights combined by the optical multiplexer / demultiplexer and generation of spontaneous emission light.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in an optical multiplex transmission system that transmits and receives a data signal and the like using a plurality of transmission lights, an optical multiplexing device or a demultiplexing device is used to multiplex or demultiplex each transmission light. In the above system, the multiplexing device is a device that introduces a plurality of lights having different wavelengths through respective fibers, efficiently combines the lights onto one optical fiber, and outputs multi-wavelength light, The optical demultiplexer introduces a combined optical signal containing multiple wavelength components from one optical fiber, and separates each wavelength light into the corresponding optical fiber efficiently and with a certain degree of wavelength separation. It is a device to do.
[0003]
Conventionally, with respect to two optical signals having different wavelengths, a device that performs demultiplexing or multiplexing is performed by fusing and extending some side portions of two single-mode optical cladding fibers in parallel to form an evanescent coupling portion. The formed optical fiber coupler is widely known.
[0004]
Japanese Patent Laid-Open No. 7-198987 discloses a conventional multi-wavelength optical signal multiplexer / demultiplexer (hereinafter, referred to as a multiplexer / demultiplexer) in which a large number of optical fiber couplers are arranged in a multi-stage tree structure. A demultiplexing device in which an optical connection is made and the tree structure demultiplexes the combined light input to the trunk side end and outputs an optical signal separated for each wavelength from the corresponding branch side end. Has been disclosed. This device may be a multiplexing device in which input and output are reversed, and a large number of optical signals are input to the branch side end and multiplexed light is output from the trunk side end.
[0005]
In this prior art, the intensity of each output light and its wavelength when the combined light input to the collective end of the fiber coupler is output to each branch end is set by setting the length of the fusion-stretched portion of the optical fiber coupler. Takes advantage of being able to control the width. Then, this device inputs a combined optical signal of a number of wavelengths to the collective end of the optical fiber coupler on the trunk side, and the coupler converts the output light at the two branch ends to a high wavelength region with a wavelength separation boundary as a boundary. Separate into low wavelength regions. Since each of these separated output lights still includes a plurality of lights of different wavelengths, they are respectively input to the next-stage optical fiber couplers, and each optical fiber coupler separates the input light into two narrower bands. You are doing In this way, the fiber couplers at each stage are set so that the wavelength band to be demultiplexed becomes narrower from the trunk side to the branch side of the fiber coupler tree. Is output.
[0006]
Japanese Patent Application Laid-Open No. 6-75139 discloses an optical fiber coupler that splits combined light having two different wavelengths in order to optimize the separation ratio of the two wavelength light outputs at the branch end. A method of manufacturing an optical fiber coupler in which a fusion stretching operation is performed by setting the length of a fusion stretching portion is disclosed.
[0007]
[Problems to be solved by the invention]
In a duplexer using a fiber coupler, the wavelength separation characteristic curve of the output light is substantially similar to the SIN square function with respect to the wavelength at one branch end using the length of the extending portion of the coupler as a parameter, as described later. , And the other branch end is similarly similar to the COS squared function, and the cycle gives the wavelength width in any case.
[0008]
The above-described conventional apparatus divides a wavelength band to be separated into two parts by a wavelength width of a half cycle thereof, and outputs, for example, light in a high wavelength region with high efficiency from one branch end of the coupler. , The light output in the low wavelength region is reduced (the other branch end has the opposite output distribution), but from the characteristics of the periodic function, the output light in the low wavelength region is not sufficiently reduced. Light in the low wavelength region remains in the output in the high wavelength region and the degree of separation is low. Similarly, the other branch end includes light of a high wavelength band component in light output of a low wavelength band and has a low degree of separation. The remaining unnecessary wavelength light may be output from the final branch side end without being removed from the output characteristics of the fiber couplers at the next and subsequent stages.
[0009]
Further, in the conventional multiplexer / demultiplexer, when each coupler divides the wavelength range of the combined light into two and outputs the light of the low wavelength range and the light of the high wavelength range to the corresponding branch ends, the light Since the low wavelength region does not always coincide with the wavelength region exhibiting the efficiency of the maximum value of the periodic characteristic, there is a problem that the output efficiency is considerably reduced and the total insertion loss of the device is reduced.
[0010]
In view of the above problems, the present invention is a multiplexing / demultiplexing device formed by optically coupling a multiplexer / demultiplexer having a large number of evanescent coupling portions into a tree structure, and improves the optical wavelength separation characteristics of the multiplexer / demultiplexer. It is the purpose.
[0011]
Another object of the present invention is to reduce the total insertion loss of demultiplexed or multiplexed light in such a tree structure multiplexing / demultiplexing device.
The present invention further seeks to provide an optical amplifier and an ASE light source that can use such a multiplexer / demultiplexer as an optical amplifier or an oscillator for spontaneous emission light.
[0012]
[Means for Solving the Problems]
The multiplexing / demultiplexing device of the present invention connects two branch terminals of a multiplexing / demultiplexing device by distributed coupling by evanescent coupling to a collecting end of a next-stage multiplexing / demultiplexing device, and optically connects to a tree structure of two or more stages, This is a multiplexing / demultiplexing device for multiplexing / demultiplexing light of a wavelength train arranged at approximately equal wavelength intervals Δλ. The wavelength bandwidth expressed by the wavelength half cycle of the output characteristics of the multiplexer is substantially twice the wavelength bandwidth of the output characteristics of the preceding multiplexer / demultiplexer, and the wavelength bandwidth of the output characteristics of the first multiplexer / demultiplexer. Is set substantially equal to the wavelength interval.
[0013]
Each multiplexer / demultiplexer used here has an output characteristic in which, at each of the two branch terminals, a peak and a valley of the transmission output with respect to the wavelength between one branch terminal and the collecting end with respect to the wavelength of light. The evanescent coupling portion is set so as to draw periodicity and to draw valleys and peaks of the transmission output between the other branch end and the collecting end in a phase opposite to that of the wavelength. In particular, the wavelength between the peak of the above-mentioned wavelength versus output characteristic curve and the valley adjacent thereto is defined as a wavelength half cycle, and this is defined as the wavelength bandwidth of the output characteristic.
[0014]
In particular, in the different wavelength optical multiplexer / demultiplexer of the present invention, the output characteristic of the multiplexer / demultiplexer at each stage is such that, for the light of the wavelength sequence at the collecting end, the wavelength characteristic of the output stage of the previous stage is provided at one branch end. With the characteristic of transmitting every other wavelength light and blocking the light of the remaining wavelength series, and having the other branch end blocking the light of the other wavelength series and transmitting the remaining wavelength series. Is preferred.
[0015]
According to the multiplexer / demultiplexer of the present invention, in the demultiplexer, the light of the wavelength train input to the first-stage multiplexer / demultiplexer, which is the trunk end of the tree structure, is separated, and each multiplexer / demultiplexer at the branch end is separated. Can output only light of one wavelength corresponding to each branch end. In addition, as a multiplexer, by inputting only the light of the corresponding wavelength in the wavelength train to each branch end of each multiplexer / demultiplexer at the branch side end, the combined wave is efficiently output from the trunk side end. Can be output.
[0016]
As such each multiplexer / demultiplexer at each stage, one having the above-mentioned wavelength bandwidth and the coupling length L of the evanescent coupling part that expresses transmission and blocking of the wavelength train at each branch end is used.
[0017]
Further, in each multiplexer / demultiplexer, a fiber coupler including an optical fiber as the optical waveguide and a fusion extending portion of two optical fibers as an evanescent coupling portion can be used. By adjusting the conditions and the coupling length L thereof, the above-described transmission blocking characteristics can be adjusted relatively easily and inexpensively as compared with other multiplexers / demultiplexers.
[0018]
In particular, the fiber couplers of each stage that are optically connected to each other are continuously connected by any one of the two adjacent optical fibers forming each fusion-spreading section without interposing a splice connection section. This device does not include a splice connection portion (that is, a connection portion in which the cut ends of the optical fibers are fused together), so that insertion loss can be reduced.
[0019]
Furthermore, all the fiber couplers are arranged on a single substrate, so that the different wavelength multiplexing / demultiplexing device can be formed as a single module, and there is an advantage that a compact device can be configured.
[0020]
In each multiplexer / demultiplexer, preferably, a polarization maintaining fiber can be used as an optical fiber, and the polarization of the output light and the polarization of the input light can be substantially maintained and combined or separated.
[0021]
In this different wavelength multiplexer / demultiplexer, any one of the fibers constituting each of the above multiplexers / demultiplexers can be a rare earth-doped fiber, and an optical amplifier of signal light or an oscillator of spontaneous emission light by the rare earth-doped fiber. Available as The rare-earth-doped fiber can be connected to the collecting end of the first-stage multiplexer / demultiplexer, which is the trunk end of the tree structure. Further, when the multiplexer / demultiplexer is constituted by a fiber coupler, it is preferable that one end of one rare-earth-doped fiber constituting an amplifier or an oscillator is arranged so as to constitute a fusion-spread portion of the first-stage fiber coupler. .
[0022]
To use a multiplexer / demultiplexer connected with such a rare earth-doped fiber as an optical amplifier, a fiber for signal light and a pump are added to the branch end of the multiplexer / demultiplexer in the next and subsequent stages of the different wavelength multiplexer / demultiplexer. The optical fiber is connected to the optical fiber, and the signal light is amplified by the rare earth-doped fiber connected to the multiplexer / demultiplexer.
[0023]
Further, as a spontaneous emission light oscillator, a pumping light fiber is connected to a branch end of a multiplexer / demultiplexer in a subsequent stage of a different wavelength multiplexer / demultiplexer, and a spontaneous emission from the rare earth-doped fiber is performed. Light is output and used as an ASE light source.
[0024]
BEST MODE FOR CARRYING OUT THE INVENTION
The multiplexer / demultiplexer of the present invention utilizes a multiplexer or a duplexer in which an evanescent coupling portion is formed between optical waveguides. Such a multiplexer / demultiplexer includes two optical waveguides in a light-transmitting substrate. Are formed so as to be optically exchangeable in proximity to each other, and an optical element in which an evanescent coupling portion is formed between the two waveguides is used. In the multiplexer / demultiplexer, the ends of the two optical waveguides are respectively used as branch ends for input and output of light on one end side of the evanescent coupling section, whereas the other end of the evanescent coupling section is used. On the part side, one of the two waveguides is referred to as a collecting end here, and is used for input and output of the combined wave light, and the remaining waveguides are free ends.
[0025]
The multiplexer / demultiplexer appropriately adjusts the evanescent coupling section as described below, so that when light of different wavelengths is input from each branch end, the light is combined at the evanescent coupling section and a combined wave is output from the collecting end. On the other hand, if a synthetic wave containing light components of different wavelengths is input from the collecting end, the light is separated into light of different wavelengths in the evanescent coupling unit and output separately from the two branch ends.
[0026]
In the multiplexer / demultiplexer, the collecting end of each multiplexer / demultiplexer in the second-stage multiplexer / demultiplexer row is connected to each branch end of the first-stage multiplexer / demultiplexer having a tree structure. The branch end of each multiplexer / demultiplexer in the multiplexer / demultiplexer array is connected to the collective end of each multiplexer / demultiplexer in the next-stage multiplexer / demultiplexer array. The collective terminal of the first stage multiplexer / demultiplexer becomes the trunk side end of the tree structure and is connected to the input / output of the combined light, while the branch end of each multiplexer / demultiplexer of the final stage multiplexer / demultiplexer row is It is shared by the input and output of each corresponding wavelength light as the edge of the tree structure.
[0027]
In such a multiplexing / demultiplexing device having a tree structure, a large number of component lights to be multiplexed or demultiplexed have multiplexed light transmission in which a wavelength train is formed at substantially constant wavelength intervals Δλ and substantially equally spaced. Handle the system. Regarding the multiplexer / demultiplexer at each stage constituting the multiplexer / demultiplexer, the multiplexer / demultiplexer at the first stage, when viewed from the trunk end of the tree structure, has a wavelength half cycle T _λ1 Is generally set to Δλ, and the multiplexer / demultiplexer array of each stage has a wavelength bandwidth represented by a wavelength half cycle of its output characteristic curve substantially equal to the wavelength bandwidth of the output characteristic of the preceding stage multiplexer / demultiplexer. Is set to twice.
[0028]
When operating as a demultiplexer, one branch end of the first-stage demultiplexer outputs light of every other wavelength in the wavelength train with respect to the input of the combined light having the wavelength interval Δλ, These remaining wavelength trains are output from the other branch end without outputting the remaining one wavelength train. These outputs include a wavelength train with a wavelength spacing of 2Δλ. The two multiplexer / demultiplexers, which are the next-stage multiplexer / demultiplexer group that connects the collecting end to the branch end of the first-stage demultiplexer, receive light at an interval of 2Δλ. Wavelength half cycle T of the multiplexing / demultiplexing characteristics of the multiplexing / demultiplexing device in the stage _λ2 Is set to about twice the wavelength interval Δλ, so that the light of the wavelength train at the 2Δλ interval is further transmitted from one branch end to the light of the other wavelength train and to the other branch end. Are separated into the lights of the other wavelengths and output. These output wavelength trains are spread four times the wavelength interval Δλ.
Here, when the wavelength half cycle is set to be approximately twice the wavelength interval Δλ, a change in a range of ± 10% of twice Δλ is allowed.
[0029]
Further, the collecting end of each of the third-stage duplexers is joined to each branch end of each of the second-stage duplexers, and the wavelength of the multiplexing / demultiplexing characteristic of each of the third-stage multiplexing / demultiplexing devices. Half cycle T _λ3 Is the wavelength half-period T _λ2 Is set to about twice, that is, about four times Δλ, and similarly, only the light of the wavelength train is separated and output from every other branch end. In this way, the number of stages of the tree can be determined such that a single light is separated and output from the branch side end of the tree.
In this case as well, when the value is set to about twice or about four times, a change in the range of ± 10% is acceptable.
[0030]
In order to use this as a multiplexer, the light of the wavelength train is applied to the branch end of the multiplexer at the branch side end of the tree structure, and the number of tree stages is N, respectively. Where, for each multiplexer, the wavelength spacing between the two branches of the same multiplexer is 2 ^N When two lights different by Δλ are input, the wavelength half period T _λN Is 2 ^N Since it is set to Δλ, the two signals can be output to the wave aggregation end without loss. This output light is input to each multiplexer at the preceding stage, and the two branch ends of each multiplexer have a wavelength interval of 2 ^N-1 Wavelength sequences different by Δλ are input, and a wavelength interval of 2 ^N-2 Δλ The combined light is output. Finally, a completely combined light is output from the trunk side end.
[0031]
In the device of the present invention, the multiplexer or demultiplexer has wavelength periodicity of the output light intensity as the multiplexer or demultiplexer from the evanescent coupling part, and sets the coupling length. One that can control the wavelength half cycle is used. As such a multiplexer or a demultiplexer, a fiber coupler in which cladding portions of two single mode fibers are partially parallel-fused and stretched to form an evanescent coupling portion can be used.
[0032]
Further, in another multiplexer / demultiplexer, two parallel optical waveguides are formed on a translucent substrate (for example, a quartz-based or LN-based substrate), and a gap between these two waveguides is formed. There is one in which an evanescent coupling portion is configured so as to be optically exchangeable and close to each other. In this case, a multiplexing / demultiplexing device can be configured on a single element substrate by forming such a plurality of coupling portions in a tree structure. In this multiplexer / demultiplexer, the end of the waveguide at each stage is connected to an optical fiber by a fiber array type component.
[0033]
In the following embodiment, an example of a different wavelength multiplexer / demultiplexer in which a multiplexer or a demultiplexer is a fiber coupler will be described. The different wavelength multiplexing / demultiplexing apparatus 1 of FIG. 1 uses a fiber coupler 3 in which an evanescent coupling section is formed by a fusion-spreading section in a multiplexer / demultiplexer, and optically connects the fiber couplers 3 to each other to form a three-stage tree structure. I'm in. In this multiplexer / demultiplexer, the collective terminals 30, 30 of the second-stage fiber couplers 22a, 22b are respectively connected to the two branch terminals 32, 33 of the first-stage fiber coupler 21, and the fiber coupler 22a of this stage is connected. , 22b are connected to one collective terminal 30, 30 of the fiber couplers 23a to 23d of the next stage (in this example, the last stage). Thus, the multiplexer / demultiplexer is composed of three stages of multiplexer / demultiplexer groups 21, 22, and 23, and eight branch-side terminals 11 are formed for one trunk-side terminal. Are connected to an optical fiber (not shown) for a laser to which different laser light wavelengths are assigned.
[0034]
In the following, an example of a duplexer using a fiber coupler will be described. First, the operation of the duplexer will be described. As shown in FIGS. 6 and 8, light of a single wavelength λ is collected as an input Pi. When input to the terminal 30, the outputs Po1 and Po2 that are separated at the evanescent coupling portion and emitted from the two branch terminals 32 and 33 are combined with the coupling length L of the evanescent coupling portion (in a fiber coupler, In the duplexer, the core 41 of the fiber at the input end 30 is connected through the evanescent coupling part 34 to the branch terminal 32 of the output side. When directly connected to the fiber 4, the branch end 32 (first output port)
P (λ) o1 = E ₁ ・ Cos ² [Κ (λ) · L] + E ₂ (1)
An output P (λ) o1 expressed by the following appears.
On the other hand, when the other branch terminal 33 (second output port) is connected by the evanescent coupling unit 34 to an optical fiber that is provided in addition to the core unit 41 and optically coupled, the branch terminal 33 The output P (λ) o2 appearing at 33 (second output port) is
P (λ) o2 = E ₁ ・ Sin ² [Κ (λ) · L] + E ₂ (2)
Given by
[0035]
In both equations, κ (λ) is a mutual optical coupling coefficient between the cores of the evanescent coupling part. It also depends on the propagating wavelength λ. In these equations, the output from the output port is a periodic function of the evanescent coupling length L (for a fiber coupler, the length of the melt-stretched portion), and by adjusting the coupling length L, the output P (λ) o1 P (λ) o2 is the boat E ₂ From (E ₁ + E ₂ ) Changes periodically. FIG. 8 shows that P (λ) o2 greatly changes depending on the coupling portion length L according to the above equation (2).
[0036]
In the above equations (1) and (2), the coefficient κ (λ) in the equations is a function of the wavelength λ, and the above-mentioned periodic functions for two lights having different wavelengths λ are as shown in FIG. The cycle for the coupling length L is different. Two wavelengths λ ₁ , Λ ₂ When the coupling length L is changed with respect to the input light, the output of the second output port is P (λ ₁ ) O2 maximum (E ₁ + E ₂ ), P (λ ₂ ) Minimum E for o1 ₂ Length L ₀ (See FIG. 8, the bond length L ₀ , The output of the first output port is, on the contrary, P (λ ₁ ) O1 is minimum E ₂ And P (λ ₂ ) O1 is the maximum (E ₁ + E ₂ )). Thus, two wavelengths λ ₁ And λ ₂ The bond length L defined by ₀ Can split the combined light into a first output port and a second output port and separate them efficiently (in the case of a multiplexer, The multiplexer having the coupling length L is used for the two wavelengths λ. ₁ And λ ₂ By inputting each light of the above to the branching end, the collecting end can be used as an output port to efficiently combine them.)
[0037]
The light separation degree of such a duplexer has a wavelength λ ₁ Light and wavelength λ ₂ The highest degree of separation for light is given by E2 / (E1 + E2) at each output port. In practice, the wavelength λ of the input light ₁ And λ ₂ Does not completely coincide with the peak wavelength and the valley wavelength of the output characteristic curve, respectively, and may be slightly worse than the maximum degree of separation. The excess light loss of the duplexer is given by (Po1 + Po2) / Pi with respect to the total output of both ports, which indicates the light transmittance of the evanescent coupling unit.
[0038]
In the above formulas (1) and (2), when the wavelength λ of the input light is input into the duplexer having the coupling length L while being changed in a wide range, κ (λ) is As shown in FIG. 7, the output light from the output port periodically changes with respect to the wavelength λ because the output light monotonically changes (the two output ports have a phase difference of 180 degrees and the outputs are opposite to each other). .
[0039]
Half of the period of the periodic function of the output characteristic curve with respect to the wavelength (that is, the wavelength period) is defined as the wavelength half period T of the multiplexing / demultiplexing characteristic. _λ And This value gives the bandwidth between the wavelength showing the maximum power and the wavelength showing the minimum power. Wavelength half period T _λ , The two wavelength light λ ₁ , Λ ₂ Is input from any one of the output ports of the branch terminals. ₁ Only output light, and other λ ₂ Do not output light (from the other output port, ₂ Output light), wavelength half cycle T _λ And the coupling length L can be defined.
[0040]
According to the present invention, a series of a large number of wavelength lights arranged at substantially equal wavelength intervals are demultiplexed or combined into respective component lights by a tree structure demultiplexer or a multiplexer composed of a plurality of stages of demultiplexers. The wavelength half-period of the multiplexer / demultiplexer at each stage is doubled from the trunk end toward the branch end by two times, so that the demultiplexing or multiplexing separation efficiency or This is to improve the multiplexing efficiency.
[0041]
Here, a series of wavelengths λ arranged in order of wavelength magnitude ₁ , Λ ₂ , Λ ₃ , Λ ₄ , ... λ _n Have a wavelength interval Δλ, and the first-stage duplexer has the above-mentioned wavelength half cycle T T of the output characteristic curve as shown in FIG. _λ Is set equal to Δλ, and the coupling length L of the duplexer is set such that the output shows the maximum value at one of the adjacent wavelengths and shows the minimum value at the other wavelength.
At this time, when the wavelength train is input to the collecting end of the demultiplexer, only the light having the wavelength corresponding to the peak of the output characteristic curve of the output port is output to each of the two output ports that are the branch ends. Therefore, the wavelength lights of the above wavelength train are alternately output one by one, and λ ₁ , Λ ₃ , Λ ₅ ... and λ ₂ , Λ ₄ , Λ ₆ .. Can be separated into two wavelength light groups. In this case, the output wavelength λ of one output port ₁ , Λ ₃ , Λ ₅ .. Are twice as large as Δλ (the other output wavelength λ ₂ , Λ ₄ , Λ ₆ .. Are similarly 2Δλ). Then, the first group (λ) from the first output port ₁ , Λ ₃ , Λ ₅ ..), An output corresponding to the maximum peak value of the output characteristic curve is obtained, and the wavelength λ of the second group is obtained. ₂ , Λ ₄ , Λ ₆ (Similarly, the output Po2 of the second group maximizes the output of the wavelength of the first group, and the component light of the wavelength of the first group Po2). Output can be minimized).
[0042]
When the length L of the evanescent coupling portion of the fiber coupler is reduced, κ (λ) L in the equations (1) and (2) is reduced, and therefore, the wavelength half cycle T _λ (I.e., the wavelength bandwidth) increases. Utilizing this property of the fiber coupler, the coupling length L of the next-stage duplexer is sequentially reduced, so that the coupling length L that defines the wavelength interval Δλ is １ ／, １ ／, Can be set and adjusted to 1/8..., And the wavelength half cycle T of the output characteristic curve _λ Can be prepared as a multiplexer / demultiplexer having a wider wavelength bandwidth such as twice, four times, eight times...
[0043]
That is, as shown in FIG. 2B, in the above example, the wavelength group λ which is the output from the first-stage fiber coupler 21 is used. ₁ , Λ ₃ , Λ ₅ .., The wavelength half cycle T _λ Is input to the fiber coupler 22b of the second-stage duplexer in which is set to twice the wavelength interval Δλ, λ is output to the output ports of the two branch terminals 32 and 33. ₁ , Λ ₅ ... and λ ₃ , Λ ₇ ... are separated into lower groups.
Similarly, in FIG. 2B, the other wavelength group λ ₂ , Λ ₄ , Λ ₆ The wavelength half cycle T _λ Is input to the fiber coupler 22a of another demultiplexer whose is 2Δλ, so that the two lower groups λ ₂ , Λ ₆ ... and λ ₄ , Λ ₈ Are output separately.
[0044]
The light of the wavelength train of these subgroups, for example, λ ₁ , Λ ₅ .. Have a wavelength interval that is four times the above Δλ. The wavelength group of the lower group further includes a wavelength half cycle T _λ Is input to the third-stage duplexers 23a to 23d set to 4Δλ, whereby the signals can be further separated into lower groups (secondary lower groups). FIG. 2C shows a wavelength half cycle T of each of the third-stage fiber couplers. _λ3 Is set to 4Δλ, and the peaks and valleys that the characteristic output curves of the third-stage fiber couplers should have are individually set to match the wavelengths of the above-mentioned wavelength train. This shows that this wavelength sequence can be further separated into secondary lower groups.
[0045]
In FIG. 1, the behavior of the third-stage duplexers 23a to 23d is, for example, the output λ from the second stage in the above example. ₁ , Λ ₅ .. Are output to two output ports by a demultiplexer 23d having a wavelength half cycle of 4Δλ. ₁ , Λ ₉ ... group, λ ₅ , Λ _Thirteen .. Are output separately. When the wavelength trains of the lower group are all separated by the four demultiplexers, the wavelength trains of the secondary lower group can be separated into eight.
[0046]
The combined input light is a series of wavelength trains λ ₁ , Λ ₂ , Λ ₃ , Λ ₄ , ... λ ₈ In the case of the eight-component light, as shown in FIG. 1, the demultiplexers are arranged in a tree structure with three stages of demultiplexers. For each of the ₁ , Λ ₂ , Λ ₃ , Λ ₄ , ... λ ₈ Can be completely separated and output.
[0047]
Similarly, the tree structure of the above-described demultiplexer can be used as it is as a multiplexer, and FIG. 3 shows the input wavelength train λ to the branch side end 11 of the three-stage tree structure. ₁ , Λ ₂ , Λ ₃ , Λ ₄ , ... λ ₈ 2 shows the multiplexing process in each stage, and multiplexed light is output from the trunk side end 10 of the tree.
[0048]
Similarly, if a tree-type demultiplexer of a four-stage demultiplexer group is used, it is possible to combine lights of 16 wavelength trains at a constant wavelength interval Δλ, and to almost completely separate the combined lights. .
[0049]
In this embodiment, a fiber coupler is used in the multiplexer / demultiplexer using the evanescent coupling, and the fiber coupler optically couples a pair of fibers arranged closely in the evanescent coupling. By matching the output transmission wavelength and the cutoff wavelength of the output characteristic curve to the wavelengths of the incident wavelength train, a high transmission efficiency and a large separation ratio can be obtained, and an optical fiber is used as an optical waveguide. Therefore, there is an advantage that the propagation loss or the passage loss of the optical fiber itself can be reduced. In particular, since the multiplexing / demultiplexing device of the present invention does not differ in the distance that each light transmits through the fiber coupler and the optical fiber even if the wavelength is different, the separated wavelength lights have a large output due to the difference in transmission distance. There is an advantage that no difference occurs.
[0050]
Preparation of a fiber coupler as a multiplexer / demultiplexer is to align two optical fibers in parallel, locally heat the aligned portion with a burner, fuse both claddings, and simultaneously stretch from both sides, In the molten core glass, the two core portions are brought close to each other over a predetermined length to form an evanescent coupling portion. At this time, if the fusion-stretched portion is elongated, the length L of the bonding portion can be increased, and the half-wavelength period of the bonding can be reduced. The peak wavelength and the valley wavelength of the output characteristic curve of each fusion-bonded stretched portion can be adjusted by changing the conditions for the first melting. Therefore, the length L of the joining portion is set by adjusting the amount of pulling of the fusion-stretched portion in consideration of the required wavelength half-period from the wavelength train required for the multiplexer / demultiplexer at each stage and the wavelength interval. This operation can be performed according to the fusion stretching method described in JP-A-6-75139.
[0051]
The fiber couplers constituting each multiplexer / demultiplexer are preferably arranged adjacent to each other on the optical fiber without splicing. For this purpose, a set of fiber couplers that connect the fiber coupler groups of each stage in series is provided with a desired interval on a single continuous fiber, and a fusion-spread portion for each stage is provided to form a fiber coupler. . In this case, at a predetermined position of the single long fiber, the end sides of separate fibers are added in parallel, and are fused and drawn to form a set of fiber couplers. The above-mentioned separate fibers connected to these fiber couplers are used as continuous fibers, and one or two or more separate fibers are fused and drawn to form a fiber coupler. The multiplexer / demultiplexer having this structure is excellent in that there is no light loss due to splice connection since there is no connection between the fibers except for the fusion stretching of the fiber coupler.
[0052]
The multiplexing / demultiplexing device having such a configuration can be configured by arranging and mounting a number of fusion extending portions on one substrate. Thereby, it can be charged and fixed in a compact container. FIG. 4 shows an example in which a two-stage tree including three fiber couplers 21 and 22 is attached on a single substrate 50 with an adhesive or the like.
[0053]
The multiplexing device of the present invention can be used as a multiplexing device for an optical amplifier. A rare earth-doped fiber is connected to the trunk end of the multiplexer, and two or more pump light sources and signal light sources are connected to the branch end of the multiplexer to guide the combined light to the rare earth-doped fiber. To form an optical amplifier. Alternatively, two or more excitation light sources can be used to guide the rare earth-doped fiber to excite the rare earth-doped fiber and allow it to emit spontaneously.
[0054]
In this case, the signal light and the two or more pump light sources are arranged in four wavelength arrays λ that can be arranged at a wavelength interval of Δλ. ₁ , Λ ₂ , Λ ₃ , Λ ₄ For example, assuming one signal light and two or three pump lights, the multiplexer can use a tree having a two-stage multiplexer as shown in FIG. Two pairs of wavelengths having a wavelength interval of 2Δλ are created from the pump light and the signal light (for example, λ ₁ And λ ₃ And λ ₂ And λ ₄ ), Each pair of wavelength trains is input to two predetermined branch ends of the two fiber couples 22a and 22b at the branch ends of the tree. These fiber couplers have a wavelength half period T _λ Is set to approximately 2Δλ, so that the combined wave of the wavelength pair is output to the collective terminal 30 of each fiber coupler with high efficiency. Each synthesized wave has a wavelength half period T _λ Is input to the two branch ends of the first stage fiber coupler set to approximately Δλ, and the combined wave is output to the collecting end, that is, the trunk end.
[0055]
FIG. 5 shows an example in which a rare earth-doped fiber 44 is connected to the trunk end 10 of the multiplexer 5 to form an optical amplifier. The combined output from the multiplexer is transmitted to the trunk end 10. The signal light is input to the rare-earth-doped fiber 14 having one end connected thereto, and is amplified in the rare-earth-doped fiber 44. Emitted into the optical circuit.
[0056]
In the synthesis of the signal light and the pumping light, the relationship of the above four wavelengths is set for the two-stage tree structure, but the pumping light source of any of these wavelengths is omitted (see the example shown in FIG. 5). As described above, the present invention can also be realized by inputting two pump light sources and signal light. Furthermore, the input of the signal light is omitted, and it can be realized with only two pump light sources, which can be applied to the oscillation of the spontaneous emission light.
[0057]
In another embodiment of the present invention, the optical amplifier or the multiplexing device includes an optical amplifier or a spontaneous emission light, wherein at least one of the fibers is a rare earth-doped fiber in an optical fiber group forming a tree. Including use as an oscillator. In this case, the rare-earth-doped fiber may be provided with a fusion-stretched portion on the end side of the fiber in parallel with the side of the separate optical fiber to constitute a part of the fiber coupler. Since the light is directly incident on the rare-earth-doped fiber by the optical coupling in the section, there is an advantage that the loss of the signal light can be reduced and the characteristic of the amplified light can be prevented from deteriorating.
[0058]
【Example】
An example of a multiplexing / demultiplexing device used for multiplexing / demultiplexing in an 8-channel multiplex transmission system for metro is shown below. Here, a narrow-band DFB semiconductor laser is used as a laser light source, a wavelength interval Δλ is set to 20 nm, and laser light having eight wavelengths of λ1 = 1470 nm, λ2 = 1490 nm,. Here is an example of usage. These optical signals were synthesized by a multiplexing device described below, and the multiplexed light was separated into each wavelength light by a demultiplexing device having the same configuration.
[0059]
As shown in FIGS. 1 and 3, the multiplexer and the demultiplexer have the fiber coupler 3 in a three-stage tree configuration. Each fiber coupler 3 was prepared using a single mode optical fiber. The end portions of separate optical fibers of the same quality are arranged in parallel at three locations in the longitudinal direction of one long fiber to form a melt-stretched portion to form a coupler. Further, the end side of a separate optical fiber of the same quality was melt-drawn to form an array of melt-drawn portions shown in FIG. At the time of preparing the fiber coupler, the first-stage fiber coupler 21 extends from the trunk end to the branch end of the multiplexing device (and the demultiplexing device) to have the length L of the melt-drawn portion. ₁ Is set to 52 mm and the wavelength half cycle Tλ ₁ Was set to 20 nm. The second-stage fiber coupler group 22 has a length L of the melt-drawn portion. ₂ Is 26 mm, and its wavelength half cycle T _λ2 Is set to 40 nm, and the fiber coupler group 23 of the third stage similarly has the length L of the melt-drawn portion. ₃ Is 13 mm and T _λ3 Was set to 80 nm.
The multiplexing device and the demultiplexing device were arranged in a container having a length of 100 mm and a diameter of 5 mm, and were appropriately fixed with an adhesive material and sealed.
[0060]
In the multiplexing device, optical fibers (not shown) from the eight DFB semiconductor lasers having different wavelengths are connected to the branch side end 11 of the device by an optical fiber, and output from the trunk side end 10 as multiplexed light. did. On the other hand, in the demultiplexer, the same configuration as the above and the demultiplexer is used, and the multiplexed output light multiplexed by using the above-described multiplexing device is output to the trunk end of the demultiplexer by an optical fiber. 10 and input, and the wavelength light separated from the eight branch terminals 11 of the demultiplexer was output.
[0061]
According to the measurement results, the maximum input power of each wavelength light is 150 mW, the insertion loss of each port is 1.0 dB or less, the adjacent channel separation ratio is 15 dB or more, the uniformity is 0.5 dB or less, and the PDL is 0.5 dB or less. Can be.
[0062]
It can be seen that the multiplexer / demultiplexer of the above embodiment can be used as a transmitter-side multiplexer for C-WDM transmission and a receiver-side multiplexer in a multiplexed optical communication system.
[0063]
In the next embodiment, as a multiplexing device, a rare earth-doped fiber is connected to the trunk end, and signal light and pump light having two or more different wavelengths are input to the branch end which is the input side. This is a device for multiplexing pump light of a fiber amplifier. This multiplexer has four wavelengths λ as shown in FIG. ₁ ~ Λ ₄ And a tree structure of a two-stage multiplexer (fiber coupler) group.
[0064]
As an example, the rare earth-doped fiber 44 is a Tm (thulium) -doped fiber, and 1460 to 1530 nm (S-band) light is used as the signal light to be amplified. In a multiplexing device that can be used for this Tm-doped fiber amplifier, for example, 1500 nm light in the S band is selected as the signal light, and in FIG. 4 and FIG. Λ as the excitation light source ₁ = 1400 nm and λ as signal light ₃ = 1500 nm, λ as the second excitation light source ₄ = 1550 nm (empty port λ ₂ = 1450 nm is not input). At this time, the first-stage fiber coupler 21 has a wavelength half cycle T _λ1 Is set to approximately 50 nm, which is approximately equal to Δλ, and the wavelength half period T of the second-stage fiber couplers 22a and 22b is set to _λ2 Is set approximately equal to 2Δλ and about 100 nm.
[0065]
In this multiplexer, the signal light λ ₃ = 1500 nm corresponds to the first excitation light λ ₁ = 1400 nm, and the multiplexed light is combined with the second excitation light λ ₄ = 1550 nm are multiplexed, and the output light is input to the Tm-doped fiber connected to the trunk end. In the Tm-doped fiber 44, the excitation light in the composite wave excites the rare-earth ions to increase the radiation intensity of the signal light. The amplified light is extracted from the other end of the rare-earth-doped fiber 44 via an in-line isolator 82.
[0066]
In this example, the pump light λ ₄ = 1550 nm excites the Tm ion from the ground level to the next lower level in the fiber glass, and the excitation light λ on the short wavelength side ₁ = 1400 nm excites from this lower level to a higher upper level, and excites Tm ions to an energy level even higher than the ground level. While the Tm ions return to the ground level, the wavelength light of the signal light is amplified, and at this time, the light conversion efficiency of the excitation energy is improved and the degree of amplification is also improved. This energy conversion process also increases the spontaneous emission.
[0067]
In particular, the multiplexing device can input only the above two excitation lights without inputting the signal light, and input the multiplexed light to the Tm-doped fiber. , Which can be used as a spontaneous emission light source.
[Brief description of the drawings]
FIG. 1 shows a demultiplexer for different wavelength light according to an embodiment of the present invention.
FIG. 2 shows an output characteristic curve of a fiber coupler of each stage used in a tree configured in the multiplexer / demultiplexer of different wavelengths shown in the embodiment of the present invention, with a first stage fiber coupler (A) and a second stage fiber coupler. The respective characteristic curves of the coupler (B) and the third-stage fiber coupler (C) are shown.
FIG. 3 shows an optical multiplexing device for different wavelength light according to an embodiment of the present invention.
FIG. 4 shows a two-stage different wavelength optical multiplexer according to an embodiment of the present invention.
FIG. 5 is an optical connection diagram of an optical amplifier including a two-stage different wavelength optical multiplexer according to an embodiment of the present invention.
FIG. 6 is a sectional view of a fiber coupler used in an optical multiplexer / demultiplexer used in the apparatus according to the embodiment of the present invention.
FIG. 7 shows an output characteristic curve of a fiber coupler used in the optical multiplexer / demultiplexer used in the embodiment of the present invention, which is shown by wavelength versus transmission output.
FIG. 8 is a graph showing an output characteristic curve of a coupling length of a fiber coupler used in an optical multiplexer / demultiplexer used in an embodiment of the present invention versus transmission output.
[Explanation of symbols]
1 Optical multiplexer / demultiplexer
10 Trunk end
11 Branch side end
21 First-stage multiplexer / demultiplexer
22nd stage multiplexer / demultiplexer
23 Final stage multiplexer / demultiplexer
3 Fiber coupler
30 Collective terminal
31 Free end
32 (first) branch terminal
33 (second) branch terminal
34 Evanescent joint
4 Optical fiber
44 Rare earth doped optical fiber
50 substrates

Claims (10)

There are many multiplexers / demultiplexers having an evanescent coupling section between two optical waveguides, and two branch terminals of one multiplexer / demultiplexer are connected to the collective end of the next-stage multiplexer / demultiplexer to provide two or more stages. In a different wavelength light multiplexing / demultiplexing device for multiplexing or demultiplexing a large number of different wavelength lights having a wavelength train having a substantially constant wavelength interval Δλ between adjacent wavelengths, which is formed by optically connecting to a tree structure,
From the trunk side end to the branch side end of the tree structure, the wavelength bandwidth represented by the half cycle of the output characteristic curve of the multiplexer / demultiplexer at each stage is the wavelength bandwidth of the output characteristic of the former stage multiplexer / demultiplexer. Almost doubled, and
A different wavelength optical multiplexer / demultiplexer, wherein a wavelength bandwidth of an output characteristic of the first stage multiplexer / demultiplexer is set substantially equal to the wavelength interval. In each multiplexer / demultiplexer, the evanescent coupling part transmits and outputs the other wavelength light of the output wavelength train of the preceding stage to one branch end and cuts off the light of the remaining wavelength train, and the other branch end. A different wavelength optical multiplexing / demultiplexing device having an output characteristic with respect to the wavelength of the light so that the light of the other wavelength train is blocked at the end and the output of the remaining wavelength train is transmitted. 3. The coupling device according to claim 2, wherein each multiplexer / demultiplexer at each stage has a coupling length L of an evanescent coupling unit that expresses the wavelength bandwidth and transmission and cutoff of a wavelength train at each branch end. Different wavelength optical multiplexer / demultiplexer. The different wavelength optical multiplexer / demultiplexer according to any one of claims 1 to 3, wherein each multiplexer / demultiplexer is a fiber coupler including an optical fiber as the optical waveguide and a fused extension of two optical fibers as an evanescent coupling part. apparatus. The fiber couplers of each stage optically connected to each other are continuously connected by any one of the two adjacent optical fibers forming the fusion-spreading section without interposing a splice connection section, thereby forming a different wavelength optical coupler. 5. The different wavelength optical multiplexer / demultiplexer according to claim 4, wherein the demultiplexer is a single module. The different wavelength optical multiplexer / demultiplexer according to claim 4, wherein each multiplexer / demultiplexer uses a polarization-maintaining fiber as an optical fiber. 5. The different wavelength optical multiplexer / demultiplexer according to claim 4, wherein one of the optical fibers constituting each of the multiplexers / demultiplexers includes a rare earth-doped fiber. 8. The different wavelength optical multiplexer / demultiplexer according to claim 7, wherein a rare-earth-doped fiber is connected to a collecting end of the first-stage multiplexer / demultiplexer which is a trunk side end of the tree structure. 9. The rare-earth-doped optical multiplexer / demultiplexer according to claim 7 or 8, wherein a signal light fiber and a pump light fiber are connected to a branch end of a multiplexer / demultiplexer in a subsequent stage. A fiber optical amplifier characterized in that signal light is amplified by a fiber. 9. The different wavelength optical multiplexer / demultiplexer according to claim 7 or 8, wherein a spontaneous emission light is emitted from the rare-earth-doped fiber by connecting an excitation light fiber to a branch end of a multiplexer / demultiplexer in a subsequent stage. An ASE light source,

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