JP2010200361A - Optical relay transmission system and optical relay transmission method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve transmission characteristics in an optical relay transmission system installed with a plurality of Raman amplifiers on a transmission line. <P>SOLUTION: The plurality of Raman amplifiers 30a-30e are provided on the transmission line for transmitting a wavelength multiplexed light. In the Raman amplifiers 30a-30e, a plurality of exciting lights λ1-λ4 are used. If an exciting light source generating the exciting light λ3 falls into failure in the Raman amplifier 30c, in the Raman amplifiers 30a, 30b, 30d, 30e, power of the exciting light λ3 is increased, respectively. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an optical repeater transmission system, and more particularly to an optical repeater transmission system that transmits wavelength division multiplexed light using Raman amplification.

  Conventionally, in a long-distance optical transmission system, 3R processing (timing correction, waveform shaping, signal regeneration) is performed in a state where an optical signal is once converted into an electrical signal in each repeater, and then converted into an optical signal. It was sent to the relay device. However, at present, optical amplifiers that amplify optical signals without converting them into electrical signals have been put into practical use, and transmission systems that use optical amplifiers as linear repeaters are being studied. By replacing the repeater with optical / electrical conversion as described above with an optical amplification repeater, the number of parts constituting each repeater is greatly reduced, reliability is improved, and cost is further reduced. Expected.

  On the other hand, with the spread of the Internet and the like, the amount of information transmitted over the network is increasing, and techniques for increasing the capacity of the transmission system are being actively studied. As one of the methods for realizing an increase in capacity of a transmission system, a wavelength division multiplex (WDM) optical transmission method has attracted attention. Wavelength multiplexed optical transmission is a method of multiplexing and transmitting a plurality of signals using a plurality of carrier waves having different wavelengths, and the amount of information that can be transmitted via one optical fiber increases dramatically.

  FIG. 26 is a configuration diagram of a general optical repeater transmission system. In this system, wavelength multiplexed light is transmitted from the optical transmitter 100 to the optical receiver 200. In other words, the optical transmitter 100 generates wavelength multiplexed light by combining signal lights having different wavelengths, and sends them to the transmission line. On the other hand, the optical receiver 200 detects each signal by demultiplexing the received wavelength multiplexed light for each wavelength. Here, the transmission line is an optical fiber, and an optical amplifier is provided at predetermined intervals.

  Each optical amplifier is typically an erbium-doped fiber amplifier (EDFA). Here, the gain wavelength band of a general EDFA is a 1.55 μm band, and that of a gain shift EDFA (GS-EDFA) is a 1.58 μm band. Each of these bandwidths is about 30 nm. Therefore, when an EDFA is provided on the transmission line of the wavelength division multiplexing optical transmission system, the signal light is transmitted using a carrier wave within these gain wavelength bands.

  In order to increase the capacity of a transmission system, it is effective to increase the number of wavelength multiplexing, and one effective method for increasing the number of wavelength multiplexing is to widen the gain wavelength band. In recent years, a Raman amplifier using Raman scattering has attracted attention as an optical amplification method capable of securing a wider gain wavelength band than EDFA.

  In Raman amplification, gain is obtained on the longer wavelength side of the pumping light by applying pumping light to the optical fiber. For example, in the 1.55 μm band, as shown in FIG. 27 (a), a gain is obtained on the wavelength side longer by about 100 nm than the wavelength of the excitation light. This shift amount is 13.2 terahertz when converted to frequency. Further, the Raman amplifier can amplify an arbitrary wavelength as long as pumping light can be prepared.

  The Raman amplifier is realized by utilizing the above property. In order to obtain a wide gain wavelength band, a plurality of pump lights having different center frequencies are used as shown in FIG. 27 (b). This method is described in, for example, Y. Emori, et al., “100 nm bandwidth flat gain Raman amplifiers pumped and gain-equalized by 12-wavelength channel WDM high power laser diodes”, OFC'99 PD19 1999. . Thus, a wide gain wavelength band can be secured by using a plurality of pumping lights.

  FIG. 28 is a configuration diagram of a wavelength division multiplexing optical transmission system using Raman amplification. Excitation light for Raman amplification is basically applied to the transmission line optical fiber so that it is transmitted in the opposite direction to the signal light. At this time, when a plurality of pump lights are used as shown in FIG. 27 (b), pump lights output from a plurality of light sources having different oscillation frequencies are given to the transmission line optical fiber by a wavelength synthesizer or the like. .

  In a long-distance optical transmission system that requires a plurality of Raman amplifiers on the transmission line, there remains a problem to be technically improved. Specifically, it is desired to equalize the power of each signal light included in the wavelength multiplexed light, that is, to flatten the gain wavelength characteristic for the wavelength multiplexed light. This problem should also be taken into account when the transmission line characteristics change due to repairs or aging.

  An object of the present invention is to improve the transmission characteristics in an optical repeater transmission system in which a plurality of Raman amplifiers are provided on a transmission line. In particular, it is an object to improve the transmission characteristics of an optical repeater transmission system that uses a plurality of pump lights in each Raman amplifier.

  An optical repeater system according to an aspect of the present invention is an optical repeater transmission system in which a plurality of Raman amplifiers are provided in series on an optical transmission line, the Raman amplifier including an optical fiber for Raman amplification, and Optical transmission lines interconnecting the Raman amplifiers are connected to both ends of the optical fiber, and the first Raman amplifier of the plurality of Raman amplifiers and the second Raman amplifier adjacent to the first Raman amplifier are connected to each other. When the transmission loss of the optical transmission line increases, the power of pumping light to be supplied to the Raman amplification optical fiber is increased.

  According to the present invention, in the optical repeater transmission system in which a plurality of Raman amplifiers are provided on the optical transmission line, when a factor that changes the Raman gain occurs, the gain is adjusted according to the factor, so that signal transmission is performed. The characteristic does not deteriorate.

  Specifically, when the pumping light source fails, the power of other pumping light sources is automatically adjusted to maintain the gain, and when the transmission loss of the optical transmission path changes, the predetermined pumping light source The power is adjusted to maintain the gain.

It is a block diagram of the optical repeater transmission system of one Embodiment of this invention. It is a block diagram of a Raman amplifier. It is an Example of a multiplexer. It is an example of the 2 input / 2 output 3dB coupler which comprises the multiplexer shown in FIG. It is an Example of a Raman amplifier. It is a modification (the 1) of a Raman amplifier. It is a modification (the 2) of a Raman amplifier. It is a modification (the 3) of a Raman amplifier. It is a modification (the 4) of a Raman amplifier. It is a modification (the 5) of a Raman amplifier. It is a modification (the 6) of a Raman amplifier. It is a modification (the 7) of a Raman amplifier. It is a modification (the 8) of a Raman amplifier. It is a figure which shows the structure by which the optical fiber for Raman amplification is provided in an amplifier. It is an example of the apparatus which produces | generates the excitation light with which a plane of polarization is orthogonal for Raman amplification. It is a block diagram of the optical repeater transmission system of this embodiment. It is a figure explaining the operation | movement when the excitation light source fails in the transmission system of this embodiment. It is a figure explaining the function which adjusts pumping light power in a Raman amplifier. It is a flowchart of operation | movement of the terminal station for implement | achieving the function shown in FIG. It is a figure explaining other operation | movement at the time of the excitation light source failing in the transmission system of this embodiment. It is a flowchart of operation | movement of the terminal station for implement | achieving the function shown in FIG. FIG. 10 is a diagram for explaining still another operation when the excitation light source fails in the transmission system of the present embodiment. It is a figure which shows an example of the method of adjusting excitation light when a transmission line is repaired. It is a figure which shows the characteristic of a multiplexer. It is a figure explaining the construction method of a transmission system. It is a block diagram of a general optical repeater transmission system. It is a figure explaining the principle of Raman amplification. It is a block diagram of a wavelength division multiplexing optical transmission system using Raman amplification.

  FIG. 1 is a configuration diagram of an optical repeater transmission system according to an embodiment of the present invention. This transmission system includes a terminal station 10 and a terminal station 20, which are connected by a multi-core optical fiber cable. A signal is transmitted bidirectionally between the terminal station 10 and the terminal station 20.

  The terminal station 10 includes a plurality of optical transmitters 11 and a plurality of optical receivers 12. On the other hand, the terminal station 20 includes a plurality of optical receivers 21 and a plurality of optical transmitters 22. The signal transmitted from each optical transmitter 11 is transmitted via an optical fiber and received by the corresponding optical receiver 21. On the other hand, a signal transmitted from each optical transmitter 22 is transmitted through an optical fiber and received by the corresponding optical receiver 12. Each of the transmitters 11 and 22 transmits wavelength multiplexed light. That is, in this transmission system, wavelength division multiplexed light is transmitted through each optical fiber constituting the multi-fiber cable.

  A plurality of Raman amplifiers 30-1 to 30-n are provided on the transmission path between the terminal station 10 and the terminal station 20. Each of the Raman amplifiers 30-1 to 30-n amplifies the wavelength multiplexed light transmitted through each optical fiber constituting the multi-core optical fiber cable. In addition, when amplification light is given to the optical fiber, Raman amplification occurs in the optical fiber itself. Therefore, the “Raman amplifier” is composed of an optical fiber and a device that supplies the pumping light to the optical fiber, but the device that supplies the pumping light to the optical fiber is sometimes called a “Raman amplifier”. Each Raman amplifier may be provided in the optical repeater.

  FIG. 2 is a configuration diagram of the Raman amplifier 30. The Raman amplifiers 30-1 to 30-n basically have the same configuration. The “Raman amplifier 30” represents any one of the Raman amplifiers 30-1 to 30-n.

  The Raman amplifier 30 includes a plurality of excitation light sources 31, a multiplexer 32, and a multiplexer 33. The plurality of excitation light sources 31 generate excitation light having different wavelengths. In this embodiment, excitation light having wavelengths λ1 to λ4 is generated by four excitation light sources. Each excitation light source 31 is, for example, a laser diode. A laser diode generally outputs light having a power corresponding to a given current. Many laser diodes also have a back power monitor function for detecting the light emission power. In the following, it is assumed that the emission power of each excitation light source 31 can be detected by the back power monitor function or other methods.

  The multiplexer 32 multiplexes the excitation light output from the plurality of excitation light sources 31. In this embodiment, excitation light of wavelengths λ1 to λ4 is multiplexed by the multiplexer 32. The multiplexer 32 includes a plurality of output ports, and outputs the excitation light combined from each output port. The configuration of the multiplexer 32 will be described in detail later.

  The multiplexer 33 is provided for each optical fiber accommodated in the multi-core optical fiber cable, and supplies the pumping light output from the multiplexer 32 to the corresponding optical fiber. At this time, the excitation light is incident on the optical fiber so as to be transmitted in the opposite direction to the signal light. In FIG. 2, the “fiber system” refers to each optical fiber accommodated in a multi-core optical fiber cable.

  In the example shown in FIG. 2, four excitation light sources 31 are provided in the Raman amplifier 30, but the present invention is not limited to this. The number of excitation light sources 31 may be determined based on, for example, a required gain wavelength bandwidth. In this example, the number of pumping light sources 31 and the number of optical fibers match each other. However, the present invention is not limited to this, and these numbers may be different from each other.

FIG. 3 shows an embodiment of the multiplexer 32. In this example, configured to output from the pump light generated by the 2 ⁿ excitation light source (LD1 ~LD (2 ⁿ⁾⁾ combined to the 2 ⁿ output ports (P1~P (2 ⁿ⁾⁾ Indicates.

  The multiplexer 32 is realized by an optical coupler group having an n-stage configuration. Here, each optical coupler is a 2-input / 2-output 3 dB coupler shown in FIG. This 2-input / 2-output 3 dB coupler combines the light input from the two input ports and outputs the combined light from each output port. The combined light output from each output port is basically the same as each other. Therefore, combined light obtained by combining the excitation light generated by each excitation light source is output from each output port of the multiplexer 32 shown in FIG. At this time, the combined lights output from each output port are basically the same.

FIG. 5 shows an embodiment of the Raman amplifier 30. Here, the Raman amplifier 30 includes 8 (= 2 ³ ) laser diodes LD1 to LD8 as the plurality of excitation light sources 31. The multi-core optical fiber cable accommodates eight optical fibers.

  The laser diodes LD1 to LD8 output excitation light having different wavelengths. The multiplexer 32 is a group of three-stage optical couplers, and includes eight output ports. Here, the multiplexer 32 corresponds to the case of “n = 3” in FIG. The multiplexer 32 multiplexes the excitation light generated by the laser diodes LD1 to LD8, and outputs the combined excitation light from each output port.

  Each optical fiber accommodated in the multi-core optical fiber cable is provided with a multiplexer 33. Each multiplexer 33 receives the combined pumping light output from the corresponding output port of the multiplexer 32 and enters it into the corresponding optical fiber. At this time, the combined excitation light is input so as to be transmitted in the opposite direction to the signal light. Thereby, the excitation light generated by the laser diodes LD1 to LD8 is supplied to each optical fiber. In each optical fiber, an amplification action as shown in FIG. 27B is obtained.

  Next, a modified example of the Raman amplifier described above is shown. The Raman amplifier shown below is based on the configuration described with reference to FIGS. However, in the following embodiments, it is assumed that excitation light is supplied to four optical fibers.

  In the configuration shown in FIG. 6, an EDFA is provided for each optical fiber. That is, in this configuration, wavelength multiplexed light including a plurality of signal lights is amplified by a Raman amplifier and then further amplified by an EDFA.

  In the configuration shown in FIG. 7, a gain equalizer is provided for each optical fiber. This gain equalizer is designed or compensated for, for example, so as to compensate the wavelength characteristic of the gain of the Raman amplifier, or to equalize the power of each signal light included in the wavelength multiplexed light amplified by the Raman amplifier. It is adjusted.

  In the configuration shown in FIG. 8, an OTDR (Optical Time Domain Reflectometry) path is provided between a pair of upstream optical fiber and downstream optical fiber. The OTDR path is provided before and after each multiplexer 33. Thereby, a fiber sensor for position determination is realized.

  In the configuration shown in FIG. 9, an SV signal receiving module is provided for each optical fiber, and the SV signal received by each SV signal receiving module is processed by the SV control unit. Here, the SV signal is a control signal for monitoring the optical transmission system, and is transmitted from the terminal station 10 or the terminal station 20 using a carrier wave having a predetermined wavelength, for example. In this case, the SV signal receiving module includes a demultiplexer that demultiplexes the signal light including the SV signal from the wavelength multiplexed light, and a photoelectric element that converts the signal light demultiplexed by the demultiplexer into an electric signal (for example, Photodiode PD). Then, the SV control unit detects the normality of the transmission path or the normality of another optical repeater based on the SV signal transmitted through each optical fiber. 6 to 9, the excitation light source is omitted.

  The configuration shown in FIG. 10 is provided with a function (ALC: Automatic Level Control) for feedback control so that the power of the wavelength multiplexed light output from this apparatus becomes a predetermined constant value. This function includes a branch coupler for branching a part of the wavelength multiplexed light, a photoelectric element (eg, photodiode PD) for detecting a part of the wavelength multiplexed light branched by the branch coupler, and the output of the multiplexer 32. This is realized by an optical variable attenuator that adjusts the level and a control unit that adjusts the attenuation of the optical variable attenuator according to the output of the photoelectric element.

  In the configuration shown in FIG. 11, an optical isolator is inserted between the multiplexer 32 and each multiplexer 33. Each optical isolator blocks light from the multiplexer 33 toward the multiplexer 32.

  In the configuration shown in FIG. 12, an optical fiber grating filter is provided between each of the excitation light sources LD <b> 1 to LD <b> 4 and the multiplexer 32. As the optical fiber grating filter, one having a narrow band (for example, 3 dB bandwidth is 1 nm or less) and a low reflectance (for example, 1 to 15 percent) is used. Thereby, the oscillation wavelength of the excitation light generated by each excitation light source is fixed.

  In the configuration shown in FIG. 13, an optical circulator is provided instead of the multiplexer 33. In this case, the excitation light output from the multiplexer 32 is incident on the optical fiber so as to be transmitted in the opposite direction to the signal light.

  5 to 13 show a configuration in which Raman amplification is performed using an optical fiber connected to the Raman amplifier, the Raman amplifier of the present invention is for Raman amplification as shown in FIG. The optical fiber may be provided in the Raman amplifier.

  FIG. 15 shows an embodiment of an apparatus that generates pumping light having orthogonal polarization planes for Raman amplification. This apparatus has a plurality of light source modules 40 that generate excitation light having different wavelengths. Each light source module 40 includes a pair of pumping light sources that generate pumping light having the same wavelength, and a polarization beam combiner 41 that combines the pumping light generated by the one pumping light source. Thereby, each light source module 40 outputs the excitation light whose polarization planes are orthogonal to each other. The excitation light output from each light source module 40 is multiplexed by the multiplexer 32. The combined excitation light is supplied to a plurality of optical fibers.

  In the embodiment shown in FIG. 15, the ratio of the number of optical fibers to which pumping light is to be supplied and the number of pumping light sources is 1: 2, and the pumping light generated by one set of pumping light sources is subjected to polarization synthesis. However, the present invention is not limited to this configuration. That is, according to the present invention, the ratio of the number of optical fibers to be supplied with pumping light and the number of pumping light sources is 1: 2, and the wavelengths of pumping light generated by one set of pumping light sources are different from each other. Good. In this case, the excitation light generated by one set of excitation light sources is multiplexed by the wavelength multiplexer.

  As described above, in the Raman amplifier of this embodiment, a plurality of pumping lights having different wavelengths are combined, and the combined pumping lights are respectively supplied to the plurality of optical fibers. Here, as described with reference to FIGS. 3 to 4, the plurality of excitation lights are combined using a plurality of optical elements (in the embodiment, optical couplers). At this time, it is desirable that the levels of the excitation light for each wavelength included in the combined excitation light are basically the same.

  However, in the above configuration, the characteristics (particularly the branching ratio) of each optical coupler vary slightly. For this reason, the levels of pumping light for each wavelength included in the multiplexed pumping light obtained by the multiplexer 32 often do not match each other. When Raman amplification is performed using such multiplexed pump light, the gain for amplifying the signal light has wavelength dependency. Further, as shown in FIG. 1, in the transmission system in which a plurality of Raman amplifiers are provided on the transmission line, there is a possibility that the above-described advantageous wavelength characteristics are accumulated.

  FIG. 16 is a configuration diagram of the optical repeater transmission system of this embodiment. This transmission system includes a plurality of Raman amplifiers 30 on a transmission path between the optical transmitter 11 and the optical receiver 21. The Raman amplifier 30 is as described with reference to FIGS. Further, FIG. 16 shows a transmission path between one set of the optical transmitter 11 and the optical receiver 21, but this transmission path may be a part of the system shown in FIG. In this case, each Raman amplifier 30 collectively amplifies signals transmitted through a plurality of optical fibers accommodated in a multi-core optical fiber cable.

  In the present embodiment, one or a plurality of gain equalizers 50 are provided on this transmission line. Specifically, for example, one gain equalizer 50 is provided for several tens of Raman amplifiers. The gain equalizer 50 is provided for each optical fiber. That is, in the system shown in FIG. 1, a gain equalizer 50 is provided for each optical fiber.

  As the gain equalizer 50, an equalizer whose equalization characteristic is fixedly set in advance may be used, or a variable equalizer that can dynamically change the equalization characteristic may be used. In the case of using the former equalizer, for example, an appropriate equalizer is selected while transmitting a signal after the transmission system is constructed. Specifically, for example, a gain equalizer that actually transmits wavelength multiplexed light and equalizes the powers of a plurality of signal lights included in the wavelength multiplexed light is selected and installed.

  On the other hand, when a variable gain equalizer is used, the gain characteristic of each variable equalizer is dynamically adjusted by feedback control. Specifically, for example, each of the variable equalizers is configured such that a part of the wavelength multiplexed light received by the optical receiver 21 is branched and a plurality of signal lights included in the branched wavelength multiplexed light are equivalent. Adjust the characteristics. In this configuration, the gain deviation remains small even when the characteristics of the transmission line change. The gain equalizer 50 can be an existing one. A gain equalizer (in particular, a variable gain equalizer) is described in, for example, Japanese Patent Application Laid-Open No. 11-212044 or Japanese Patent Application Laid-Open No. 11-224967.

  In the transmission system having the above configuration, even if the gain by the Raman amplifier 30 has wavelength dependence, the gain deviation is reduced by providing the equalizer 50. That is, even if the powers of the plurality of pump lights supplied for Raman amplification are not uniform, the wavelength multiplexed light transmitted through this transmission path is appropriately equalized. Further, in the system configured as described above, even when there are variations in the transmission loss of the transmission line fiber, the nonlinear execution area, and the Raman gain coefficient, the gain deviation as a whole system becomes small.

  Next, a method for minimizing the influence when a failure occurs in the optical repeater transmission system will be described. FIG. 17 is a diagram for explaining the operation when the excitation light source fails in the transmission system of the present embodiment. Here, it is assumed that each Raman amplifier 30 is supplied with four pump lights (λ1 to λ4) having different wavelengths.

  In the method shown in FIG. 17, when an arbitrary excitation light source in a Raman amplifier fails, the influence of the failure is adjusted by adjusting the power of the corresponding excitation light source in another Raman amplifier in the vicinity of the Raman amplifier. Is compensated. In the example shown in FIG. 17, the pumping light source that generates the pumping light λ3 in the Raman amplifier 30c is out of order. In this case, in the Raman amplifiers 30a, 30b, 30d, and 30e, the power of the excitation light source that generates the excitation light λ3 is increased. Thereby, the gain deviation caused by the failure of the pumping light source can be kept small. This method is effective when the wavelength interval of the excitation light (λ1 to λ4) is relatively wide. Also, this method does not require excessive redundancy.

  If the number of Raman amplifiers (four Raman amplifiers 30a, 30b, 30d, and 30e in FIG. 17) whose pumping light power should be increased is small, the burden on a specific pumping light source becomes large, and the pumping light source It deteriorates quickly. On the other hand, if the number of Raman amplifiers that should increase the pumping light power is large, the optical signal-to-noise ratio of the entire transmission system is greatly degraded. Therefore, it is necessary to appropriately determine the number of Raman amplifiers that increase the pumping light power. As an example, there are about three.

  The above method is realized by monitoring the state of each excitation light source in the terminal station 10 or 20 and giving an instruction to the corresponding Raman amplifier when an abnormality is detected. FIG. 18 is a diagram for explaining the function of adjusting the pumping light power in each Raman amplifier 30. Here, the Raman amplifier 30 includes a plurality of excitation light sources 61. Each excitation light source 61 is driven by a corresponding drive circuit 62. Here, the excitation light source 61 is a laser diode. Further, the drive circuit 62 supplies a current instructed by the control unit 64 to the corresponding excitation light source 61. The detection circuit 63 detects the light emission power of the corresponding excitation light source 61. The light emission power is detected based on, for example, the back power of the laser diode.

  The control unit 64 checks the state of each excitation light source 61 in accordance with an inquiry from the terminal station 10 or 20. Specifically, the light emission power of the excitation light source 61 is detected based on the output of the detection circuit 63. At this time, the current value supplied to the excitation light source 61 may be examined. Then, the terminal 10 or 20 is notified of the detection result. The control unit 64 controls the drive circuit 62 in accordance with an instruction from the terminal station 10 or 20. Thereby, according to the instruction | indication from the terminal station 10 or 20, the light emission power of the specific excitation light source 61 is adjusted.

FIG. 19 is a flowchart of the operation of the terminal station 10 or 20 for realizing the function shown in FIG. The process of this flowchart is executed at predetermined intervals, for example.
In step S1, each Raman amplifier 30 is inquired about the state of the excitation light source. At this time, each Raman amplifier 30 checks the state of each excitation light source in response to this inquiry and returns the result. The failure of the excitation light source is detected, for example, when the light emission power is below a predetermined value. In step S2, the response from each Raman amplifier 30 is received, and it is checked whether there is a faulty pumping light source. Then, if there is a faulty excitation light source, the processing after step S3 is executed, and if not, the processing is terminated.

  In step S3, the Raman amplifier provided with the failed pumping light source is identified. In step S4, the wavelength of the failed excitation light source is specified. In step S5, a Raman amplifier whose pumping light power is to be adjusted is determined based on the result of step S3. In step S6, a control signal is created. This control signal includes an instruction for increasing the pumping light power of the wavelength specified in step S4 to the Raman amplifier determined in step S5. At this time, for example, it is assumed that a loss of “L (dB)” has occurred due to a failure of the pumping light source, and an instruction to increase the power of pumping light is given to a Raman amplifier. For the a Raman amplifiers, a value corresponding to “L / a (dB)” in terms of gain is designated as the amount of increase in pumping light power. In step S7, the control signal is sent out. At this time, the Raman amplifier 30 adjusts the power of the corresponding excitation light according to the control signal.

  FIG. 20 is a diagram illustrating another operation when the excitation light source fails in the transmission system of the present embodiment. Here, it is assumed that each Raman amplifier 30 is supplied with eight pump lights (λ1 to λ8) having different wavelengths.

  In the method shown in FIG. 20, if an arbitrary pumping light source in a Raman amplifier fails, by adjusting the power of the pumping light having a wavelength adjacent to the wavelength of the pumping light source that has failed in the Raman amplifier, The effect of the failure is compensated. In the example shown in FIG. 20, the pumping light source that generates the pumping light λ5 in the Raman amplifier 30c is out of order. In this case, in the Raman amplifier 30c, the emission powers of the excitation light λ4 and the excitation light λ6 are increased. As a result, the gain deviation caused by the failure of the excitation light source is suppressed to a small value. This method is effective when the wavelength interval of the excitation light (λ1 to λ8) is narrow. In the embodiment shown in FIG. 20, when a pump light source in the Raman amplifier 30c fails, the optical power of the other pump light source in the Raman amplifier 30c is adjusted. The pumping light power may be adjusted. For example, in the Raman amplifiers 30b and 30d, the emission powers of the excitation light λ4 and the excitation light λ6 may be increased, respectively.

  The above method is realized by monitoring the state of each excitation light source in the terminal station 10 or 20 and giving an instruction to the Raman amplifier in which the failure has occurred when an abnormality is detected.

  FIG. 21 is a flowchart of the operation of the terminal station 10 or 20 for realizing the function shown in FIG. Steps S1 to S4 are the same as those in the flowchart shown in FIG. That is, the terminal station 10 or 20 recognizes the Raman amplifier and the excitation light source in which the failure has occurred.

  In step S11, an excitation light source whose excitation light power is to be adjusted is determined based on the detection results in steps S3 and S4. Specifically, the excitation light source that generates the excitation light having a wavelength adjacent to the wavelength of the excitation light generated by the excitation light source in which the failure has occurred is specified. Here, it is assumed that the number of excitation light sources whose output power is to be adjusted is determined in advance. If the number of pumping light sources whose output power is to be increased is reduced, the burden on the pumping light source is increased. If the number of pumping light sources whose output power is to be increased is increased, it is difficult to flatten the gain. Therefore, the number of excitation light sources that should increase the output power is determined in consideration of these factors.

  Subsequently, in step S6, a control signal is created. This control signal includes an instruction for increasing the pumping light power of the pumping light source specified in step S11 to the Raman amplifier in which the failure has occurred. At this time, the increase amount of the excitation light power may be notified. In step S7, the control signal is sent out. At this time, the Raman amplifier 30 that has received the control signal adjusts the power of the corresponding pumping light according to the control signal.

  FIG. 22 is a diagram illustrating still another operation when the excitation light source fails in the transmission system of the present embodiment. Here, it is assumed that each Raman amplifier 30 is supplied with four pumping lights (λ1 to λ4) having different wavelengths.

  In the method shown in FIG. 22, when the transmission loss of an arbitrary transmission line increases, the transmission loss is compensated by adjusting the power of the pumping light of a plurality of Raman amplifiers. In the example shown in FIG. 22, the transmission loss of the transmission line between the Raman amplifiers 30b and 30c increases. Possible causes for the increase in transmission loss include, for example, repair of the transmission path and deterioration over time.

  At this time, if the pumping light power is increased only in the Raman amplifier directly connected to the transmission line with increased transmission loss, the burden on the pumping light source becomes heavy, and the characteristics of the optical fiber and the multiplexer are increased. The gain deviation occurs due to the variation of the branching ratio. Therefore, in the present embodiment, the above-described problem is avoided by gradually increasing the pumping light power in several Raman amplifiers before and after the transmission line in which the transmission loss has increased. In the example shown in FIG. 22, when the transmission loss of the transmission line between the Raman amplifiers 30b and 30c increases, the pumping light powers of the Raman amplifiers 30a to 30d are increased little by little. Note that the number of Raman amplifiers that should increase the pumping light power is, for example, about three. Further, when a plurality of pump lights are used for Raman amplification in each Raman amplifier, the power of all the pump lights is increased.

  By the above method, the gain deviation is reduced as a whole transmission system while avoiding the concentration of a load on a specific excitation light source. This method is realized by giving an instruction from the terminal station 10 or 20 to a plurality of corresponding Raman amplifiers when recognizing an increase in transmission loss of the transmission line.

  When repairing a transmission line, the optical fiber in that transmission line is usually replaced with another optical fiber. Here, each optical fiber has a unique wavelength characteristic. That is, when a certain optical fiber is replaced with another optical fiber, the gain of Raman amplification using that optical fiber also changes. Hereinafter, a problem caused by this will be described with reference to FIG.

  In the example shown in FIG. 23, Raman amplifiers 30a to 30d are provided on a pair of transmission paths (upstream transmission path and downstream transmission path). In FIG. 23, an excitation light source and a multiplexer are drawn for the Raman amplifier 30c, but they are omitted for the other Raman amplifiers. In addition, it is assumed that the excitation light is input to each optical fiber so as to be transmitted in the opposite direction to the signal light.

  In the above configuration, it is assumed that the transmission path between the Raman amplifiers 30b and 30c has been repaired. At this time, when the pumping light power of the Raman amplifier 30c is adjusted, the Raman gain differs between the upstream transmission path and the downstream transmission path. That is, in the upstream transmission path, the pumping light power supplied to the newly installed optical fiber is adjusted, whereas in the downstream transmission path, the pumping light power supplied to the optical fiber that has been used before. Is adjusted. As a result, the gain of the uplink transmission path and the gain of the downlink transmission path may be different from each other.

  Therefore, in this embodiment, when compensating for the increased transmission loss during the repair of the transmission line, the pump light power for Raman amplification may be adjusted in a transmission line other than the repaired transmission line. Good. For example, in FIG. 22, when the transmission loss of the transmission line between the Raman amplifiers 30b and 30c increases, the pumping light powers of the Raman amplifiers 30d to 30f may be increased little by little.

  If the transmission loss increases by “L (dB)” due to the repair of the transmission line and the power of pumping light increases in a Raman amplifiers to compensate for this loss, a The increase in pumping light power in the Raman amplifier corresponds to “L / a (dB)” in terms of gain. That is, the burden is equally distributed to the plurality of Raman amplifiers.

  Next, a method for constructing a transmission system in consideration of variations in characteristics of the multiplexer 32 that multiplexes a plurality of pump lights will be described. When supplying a plurality of pumping lights to a plurality of optical fibers, for example, a multiplexer composed of a plurality of 2-input / 2-output 3 dB couplers as shown in FIG. 3 is used. At this time, it is desirable that the branching ratio of the multiplexer is uniform. For example, when a plurality of pump lights (λ1 to λ4) having the same power are input, as shown in FIG. 24 (a), a combined pump light in which the powers of the plurality of pump lights are evenly combined. Is preferably output from each output port.

  However, in practice, it is not easy to manufacture a 2-input / 2-output 3 dB coupler with a perfect branching ratio of 1: 1. For this reason, when the multiplexer 32 is configured by combining a large number of 2-input / 2-output 3 dB couplers, for example, as shown in FIG. 24 (b), a plurality of pump lights may be multiplexed non-uniformly. is there. Here, the gain of Raman amplification depends on the power of the given pumping light. Therefore, if the pumping light (λ1 to λ4) is multiplexed by the multiplexer 32 shown in FIG. 24 (b) and supplied to each optical fiber, the gain in each transmission path is not flat. For example, in the case shown in FIG. 24B, in the optical fiber 1, the gain in the wavelength band corresponding to the wavelength λ3 increases and the gain in the wavelength bands corresponding to the wavelengths λ1 and λ4 decreases. .

  In this embodiment, in order to solve the above problem, the combination of the multiplexers 32 provided in each Raman amplifier 30 is optimized. Specifically, first, the characteristics (particularly, branching ratio) of a large number of multiplexers 32 are measured in advance. Subsequently, several to several tens of multiplexers 32 are appropriately selected so that the average value of the characteristics is in the ideal state shown in FIG. Then, the selected several to several tens of multiplexers 32 are made into one group, and they are used for Raman amplifiers provided continuously on the transmission line. In the example shown in FIG. 25, five multiplexers 32 are selected and used for the Raman amplifiers 30a to 30e so that the average value of characteristics becomes an ideal state. In this case, in the transmission path from the node A to the node B, the wavelength characteristics of the gain obtained by the Raman amplifiers 30a to 30e are averaged. That is, in the transmission line during this period, a gain in which variation of the multiplexer 32 is compensated is obtained.

  In the system construction described above, the multiplexer 32 is selected and installed for each of the same number as the number of optical fibers accommodated in the multi-core optical fiber cable, or for every integral multiple of the number of optical fibers. You may do it.

  In the above-described example, the average value of the characteristics of several to several tens of multiplexers 32 is ideal, but the present invention is not limited to this. That is, the multiplexer is appropriately selected so that the average value of the characteristics of the multiplexers for all the Raman amplifiers 30 provided in the transmission path between the terminal stations 10 and 20 is ideal. You may do it. However, considering the work efficiency when constructing the transmission path, it is preferable to select the multiplexer 32 for each group of several to several tens.

  Further, in the method shown in FIG. 17 or FIG. 22, the pump light power is adjusted in a plurality of Raman amplifiers. In this case, several average values of the characteristics of the multiplexer 32 are in an ideal state. The excitation light of the Raman amplifier may be adjusted. For example, in FIG. 22, when the average values of the characteristics of the multiplexers 32 included in the Raman amplifiers 30a to 30e are selected and arranged so as to be in an ideal state, the excitation light of the Raman amplifiers 30a to 30e Each power is increased a little. According to this configuration, since the pump light is adjusted in a group of Raman amplifiers in which the multiplexer 32 is appropriately selected, the Raman gain can be adjusted even if such pump light is adjusted. The deviation does not increase.

(Appendix 1)
An optical repeater transmission system in which one or a plurality of Raman amplifiers are provided on an optical transmission line, and each Raman amplifier includes a plurality of pump light sources that generate pump light for Raman amplification, and the plurality of pump light sources. An optical repeater transmission system comprising a multiplexer that multiplexes generated pumping light and supplies it to the optical transmission line, and a gain equalizer is provided on the optical transmission line.
(Appendix 2)
In the optical repeater transmission system according to attachment 1, the gain wavelength characteristic of the gain equalizer is fixedly set.
(Appendix 3)
In the optical repeater transmission system according to attachment 1, the gain wavelength characteristic of the gain equalizer is dynamically adjusted so that the gain of the optical repeater transmission system becomes a predetermined value.
(Appendix 4)
An optical repeater transmission system in which a plurality of Raman amplifiers are provided on an optical transmission line, and a plurality of pump lights are used in each Raman amplifier, wherein the plurality of Raman amplifiers in the first Raman amplifier In the one or more Raman amplifiers other than the first Raman amplifier, when the power of the pump light of the first wavelength in the pump light drops below a predetermined level, the first wavelength or the first wavelength thereof An optical repeater transmission system that increases the power of pumping light having substantially the same wavelength as the wavelength of.
(Appendix 5)
An optical repeater transmission system in which a plurality of Raman amplifiers are provided on an optical transmission line, and a plurality of pump lights are used in each Raman amplifier, wherein the plurality of Raman amplifiers in the first Raman amplifier among the plurality of Raman amplifiers. When the power of the pumping light having the first wavelength in the pumping light of the first wavelength falls below a predetermined level, the pumping light having a wavelength adjacent to the first wavelength in the first Raman amplifier or another Raman amplifier. Optical repeater transmission system that increases the power of
(Appendix 6)
An optical repeater transmission system in which a plurality of Raman amplifiers are provided on an optical transmission line, the first Raman amplifier among the plurality of Raman amplifiers and a second Raman amplifier adjacent to the first Raman amplifier. An optical repeater transmission system that increases the power of pumping light in at least the first and second Raman amplifiers when the transmission loss of the optical transmission line increases.
(Appendix 7)
An optical repeater transmission system in which a plurality of Raman amplifiers are provided on an optical transmission line, the first Raman amplifier among the plurality of Raman amplifiers and a second Raman amplifier adjacent to the first Raman amplifier. An optical repeater transmission system for increasing the power of pumping light to be supplied to a transmission line other than the transmission line between the first and second Raman amplifiers when the transmission loss of the optical transmission line increases.
(Appendix 8)
An optical repeater transmission system in which a plurality of Raman amplifiers are provided on an optical transmission line, and a plurality of pump lights are used in each Raman amplifier. Each Raman amplifier combines the plurality of pump lights and A plurality of multiplexers provided to the optical transmission line, such that the average value of the characteristics of the plurality of multiplexers provided in the plurality of Raman amplifiers has a predetermined characteristic. An optical repeater transmission system that is selected and arranged.
(Appendix 9)
The optical repeater transmission system according to appendix 8, wherein the multiplexer is selected and arranged so that an average value of the characteristics of the multiplexer becomes a predetermined characteristic determined every predetermined number.
(Appendix 10)
In the optical repeater transmission system according to attachment 9, when the optical transmission line accommodates m optical fibers, the predetermined number is m or an integer multiple of m.
(Appendix 11)
The optical repeater transmission system according to appendix 4 or 5, wherein the optical transmission line accommodates m optical fibers, and in each Raman amplifier, m-wave excitation lights having different wavelengths are combined. Each of the m optical fibers is supplied.
(Appendix 12)
The optical repeater transmission system according to appendix 4 or 5, wherein the optical transmission path accommodates m optical fibers, and each Raman amplifier includes m input ports and m output ports. The m input ports receive polarization multiplexed light obtained by combining the two excitation light beams with polarization, and the multiplexer includes the m input ports. Are further combined and supplied to the m optical fibers.
(Appendix 13)
The optical repeater transmission system according to any one of appendix 4 to appendix 7, wherein each Raman amplifier includes a multiplexer that multiplexes a plurality of pumping lights and supplies them to the optical transmission path, and a predetermined number The plurality of multiplexers are selected and arranged so that the average value of the characteristics of the multiplexers included in the predetermined number of Raman amplifiers becomes a predetermined predetermined characteristic for each of the Raman amplifiers. The power of pumping light is increased in a predetermined number of Raman amplifiers.
(Appendix 14)
The optical repeater transmission system according to appendix 7, wherein when the amount of increase in transmission loss of the optical transmission line is L and the number of Raman amplifiers that should increase the pumping light is a, the number of a The pumping light is adjusted so that the gain increase by the Raman amplifier is L / a.
(Appendix 15)
An optical repeater transmission method in which a plurality of Raman amplifiers are provided on an optical transmission path between a first optical terminal station and a second optical terminal station, and a plurality of pump lights are used in each Raman amplifier, The first optical terminal station detects the power of each pumping light of the plurality of Raman amplifiers, and a first wavelength in the plurality of pumping lights in the first Raman amplifier of the plurality of Raman amplifiers. When the power of the pumping light drops below a predetermined level, the first wavelength or the first wavelength thereof is transmitted from the first optical terminal station to one or more Raman amplifiers other than the first Raman amplifier. An optical repeater transmission method in which a control signal for increasing the power of pumping light having substantially the same wavelength as that of the first wavelength is transferred, and the pumping light is adjusted according to the control signal in the one or more Raman amplifiers.
(Appendix 16)
An optical repeater transmission method in which a plurality of Raman amplifiers are provided on an optical transmission path between a first optical terminal station and a second optical terminal station, and a plurality of pump lights are used in each Raman amplifier, The first optical terminal station detects the power of each pumping light of the plurality of Raman amplifiers, and a first wavelength in the plurality of pumping lights in the first Raman amplifier of the plurality of Raman amplifiers. In order to increase the power of the pumping light having a wavelength adjacent to the first wavelength from the first optical terminal station to the first Raman amplifier when the power of the pumping light of the first optical terminal decreases to a predetermined level or lower. An optical repeater transmission method in which the control signal is transferred and the pump light is adjusted in accordance with the control signal in the first Raman amplifier.

10, 20 Terminal station 11, 22 Optical transmitter 12, 21 Optical receiver 30 Raman amplifier 31 Excitation light source 32, 33 Mux 40 Light source module 41 Polarization synthesizer

Claims (1)

An optical repeater transmission system in which a plurality of Raman amplifiers are provided in series on an optical transmission line,
The Raman amplifier includes a Raman amplification optical fiber, and optical transmission lines that connect the Raman amplifiers to each other are connected to both ends of the Raman amplification optical fiber.
When the transmission loss of the optical transmission line between the first Raman amplifier of the plurality of Raman amplifiers and the second Raman amplifier adjacent to the first Raman amplifier increases, the optical fiber is supplied to the Raman amplification optical fiber. An optical repeater transmission system that increases the power of pumping light.

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