JP5522229B2 - Optical transmission system - Google Patents

Description

  The present invention relates to an optical transmission system. For example, when a change in an optical transmission path or a change in the type of an optical node device is performed, a user can quickly determine whether or not wavelength division multiplexed light can be transmitted. The present invention relates to an optical transmission system.

  In an optical transmission system based on wavelength division division multiplexing (WDM), a plurality of optical node devices that transmit wavelength multiplexed light are connected to each other via an optical transmission line. In such an optical transmission system, a change in the optical transmission path of wavelength division multiplexed light or a change in the type of an optical node device (for example, from an optical amplification repeater (ILA: In Line Amp) to an optical add / drop in response to a change in communication request A device (change to OADM: Optical Add-Drop Multiplexer) may be performed. When the optical transmission path of the wavelength multiplexed light is changed or the type of the optical node device is changed, the number of times the wavelength multiplexed light passes through the optical node device varies.

  By the way, when the optical node device constituting the optical transmission system is an OADM, a wavelength selective switch (WSS) capable of switching and outputting signal light of an arbitrary wavelength in an arbitrary direction and a signal for each wavelength. In many cases, a filter such as an arrayed waveguide grating (AWG) having a spectral function for extracting light is used. In such a filter, the wavelength band is narrowed every time wavelength multiplexed light is transmitted. For this reason, there is an upper limit to the number of times wavelength multiplexed light passes through the optical node device. Therefore, in the optical transmission system, when the number of times that the wavelength multiplexed light passes through the optical node device exceeds the upper limit value, the wavelength multiplexed light cannot be transmitted.

  In a conventional optical transmission system, whether or not wavelength multiplexed light can be transmitted, such as the number of times wavelength multiplexed light passes through the optical node device, when the optical transmission path is changed or the type of the optical node device is changed. This information (hereinafter referred to as “transmission availability information”) is stored in advance on the management system side that manages this system.

JP-A-9-247104

  However, in the above-described conventional optical transmission system, there is a problem that it takes time to determine whether or not wavelength division multiplexed light can be transmitted when the optical transmission path is changed or the type of the optical node device is changed. was there. That is, in the conventional optical transmission system, each time the optical transmission path is changed or the type of the optical node equipment is changed, each optical node equipment needs to inquire the management system side about the transmission permission / inhibition information. Took a long time to confirm the transmission availability information. For this reason, it is difficult for the user to instantaneously determine whether or not the wavelength multiplexed light can be transmitted. Note that, as shown in FIG. 12, the above-described problem also occurs when the optical transmission path is changed so as to straddle a plurality of optical transmission systems having different management systems.

  The present invention has been made to solve the above-described problems caused by the prior art, and is it possible to transmit wavelength division multiplexed light when the optical transmission path is changed or the type of the optical node device is changed? An object of the present invention is to provide an optical transmission system capable of speeding up the judgment on the user side of whether or not.

  In order to solve the above-described problems and achieve the object, an optical transmission system disclosed in this application includes, in one aspect, wavelength multiplexed light including a plurality of signal lights having different wavelengths connected to each other via an optical transmission line. An optical transmission system that is transmitted by a plurality of optical node devices, wherein the optical node device is common to each of the plurality of signal lights included in the input wavelength division multiplexed light. A superposed signal light generating means for superposing a low-frequency signal that is a frequency of the low-frequency signal, a low-frequency signal extracting means for extracting a low-frequency signal having a frequency in a predetermined range for each of the plurality of signal lights, and the plurality of signals Based on the frequency of the low-frequency signal extracted by the low-frequency signal extraction means for each of the lights, the number of optical node devices that have passed through before being transmitted to the optical node device. And a transit node number measuring means for measuring the number of transit nodes, respectively.

  When the optical transmission path is changed or the type of the optical node device is changed, it is possible to speed up the determination on the user side whether or not the wavelength division multiplexed light can be transmitted.

FIG. 1 is a diagram illustrating a schematic configuration of the optical transmission system according to the first embodiment. FIG. 2 is a functional block diagram showing the configuration of the optical node device. FIG. 3 is a functional block diagram showing the configuration of the wavelength selective switch. FIG. 4 is a flowchart illustrating the processing procedure of the optical transmission process performed by the optical transmission system according to the first embodiment. FIG. 5 is a functional block diagram of the configuration of the optical node device included in the optical transmission system according to the second embodiment. FIG. 6 is a functional block diagram showing the configuration of the wavelength selective switch. FIG. 7 is a diagram illustrating an example of a frequency spectrum analyzed by the frequency spectrum analysis unit. FIG. 8 is a flowchart illustrating a processing procedure of optical transmission processing by the optical transmission system according to the second embodiment. FIG. 9 is a functional block diagram of the configuration of the optical node device included in the optical transmission system according to the third embodiment. FIG. 10 is a diagram illustrating an example of a frequency spectrum analyzed by the frequency spectrum analysis unit. FIG. 11 is a flowchart of a process procedure of an optical transmission process performed by the optical transmission system according to the third embodiment. FIG. 12 is a diagram for explaining a problem when the optical transmission path is changed so as to straddle a plurality of optical transmission systems having different management systems.

  Embodiments of an optical transmission system disclosed in the present application will be described below in detail with reference to the drawings. In the following embodiments, the optical transmission system disclosed in the present application shows an example in which a plurality of optical node devices are connected to each other in a grid pattern through an optical transmission path. The node devices may be configured to be connected to each other in a linear or other shape via an optical transmission line.

  First, the configuration of the optical transmission system according to the first embodiment will be described. FIG. 1 is a diagram illustrating a schematic configuration of the optical transmission system according to the first embodiment.

  As shown in FIG. 1, an optical transmission system 1 according to the present embodiment includes a plurality of optical node devices 2 that transmit wavelength multiplexed light in which a plurality of signal lights having different wavelengths are multiplexed. The optical node devices 2 are connected to each other in a grid pattern through an optical transmission line. The optical node device 2 is an OADM device that performs insertion (Add) or branching (Drop) of signal light allocated for each wavelength.

  In the optical transmission system 1 according to the present embodiment, each optical node device 2 has a low frequency signal (A · sin (ω · t) having the same (common) frequency in each optical node device 2, where A is a constant, A low frequency signal is superimposed on each of the signal light by performing amplitude modulation on each of the signal light included in the wavelength-multiplexed light by performing amplitude modulation with ω being an angular velocity and t being time. Each optical node device 2 extracts a low-frequency signal having a predetermined range of frequencies from each of the plurality of signal lights included in the wavelength multiplexed light, and analyzes the frequency spectrum of the extracted low-frequency signal.

  Here, the result of analyzing the frequency spectrum of the low-frequency signal by each optical node device 2 will be described. When wavelength-multiplexed light passes through one optical node device 2, one optical node device 2 superimposes a low-frequency signal on the wavelength-multiplexed light, so the frequency spectrum of the low-frequency signal is A · sin (ω · t). When the wavelength multiplexed light passes through the two optical node devices 2, the two optical node devices 2 superimpose the low frequency signal on the wavelength multiplexed light, so that the frequency spectrum of the low frequency signal is A · sin ( ω · t) × A · sin (ω · t) = B · cos (2ω · t) + C (B and C are constants). When the wavelength multiplexed light passes through the three optical node devices 2, the three optical node devices 2 superimpose the low frequency signal on the wavelength multiplexed light, so the frequency spectrum of the low frequency signal is A · sin ( ω · t) × A · sin (ω · t) × A · sin (ω · t) = D · sin (3ω · t) + E · sin (ω · t) (where D and E are constants) . That is, when wavelength multiplexed light passes through n optical node devices 2, the maximum value of the frequency of the signal component included in the frequency spectrum of the low frequency signal is n · ω · t (where n is a natural number). .

  Then, each optical node device 2 measures the number of optical node devices 2 through which the wavelength multiplexed light has passed before being transmitted to the optical node device 2 based on the analyzed frequency spectrum. Specifically, the optical node device 2 identifies the signal component having the highest frequency among the signal components included in the frequency spectrum, and sets the frequency of the identified signal component to the same low frequency in each optical node device 2. The number of passing nodes is measured by dividing by the frequency of the signal. That is, when wavelength multiplexed light passes through n optical node devices 2, the frequency of the signal component having the highest frequency is n · ω · t as described above, and therefore the number of passing nodes is n · ω. T / (ω · t) = n is measured. The number of passing nodes is displayed on a predetermined display device or the like provided in each optical node device 2.

  As described above, in the optical transmission system 1 according to the present embodiment, each optical node device 2 transmits a low-frequency signal having the same frequency in each optical node device 2 to each of a plurality of signal lights included in the wavelength multiplexed light. Superimpose. Each optical node device 2 extracts a low frequency signal having a predetermined frequency range from a plurality of optical signals included in the wavelength multiplexed light, and analyzes the frequency spectrum of the extracted low frequency signal. Then, each optical node device 2 measures the number of optical node devices 2 through which the wavelength multiplexed light has passed before being transmitted to the optical node device 2 based on the analyzed frequency spectrum. As a result, when the optical transmission path is changed or the type of the optical node device is changed, the number of passing nodes can be presented to the user side. The conventional process of inquiring to can be omitted. As a result, it is possible to speed up the determination on the user side as to whether or not wavelength multiplexed light can be transmitted.

  Next, a specific configuration of the optical node device 2 will be described. FIG. 2 is a functional block diagram showing the configuration of the optical node device 2. As shown in FIG. 2, each optical node device 2 includes a preamplifier 3, a wavelength selective switch 4, and a postamplifier 5. The preamplifier 3 and the postamplifier 5 are optical amplifiers that amplify wavelength multiplexed light, and are disposed on the upstream side and the downstream side of the wavelength selective switch 4, respectively.

  The wavelength selective switch 4 drops (drops) signal light of an arbitrary wavelength from the wavelength multiplexed light input to the optical node device 2 or inserts (Add) signal light of an arbitrary wavelength into the wavelength multiplexed light. . Further, the wavelength selective switch 4 selects signal light of an arbitrary wavelength from the wavelength multiplexed light, and outputs the signal light of the selected wavelength to an arbitrary output port. Specifically, the wavelength selective switch 4 includes a spectroscopic device such as an AWG and a diffraction grating, and an optical switch device such as a MEMS mirror and a liquid crystal device. The output port is switched by moving the optical switch device corresponding to each wavelength.

  FIG. 3 is a functional block diagram showing a configuration for executing extraction / superimposition of a low-frequency signal included in the wavelength selective switch 4. In the example shown in FIG. 3, only the configuration related to the extraction / superposition characteristics of the wavelength selective switch 4 is shown, and the configuration corresponding to a plurality of inputs or a plurality of outputs is omitted.

  As illustrated in FIG. 3, the wavelength selective switch 4 includes a demultiplexing unit 15, a multiplexing unit 16, and low-frequency signal extraction / superimposition units (10-1 to 10 -n). The low-frequency signal extraction / superimposition units 10-1 to 10-n respectively receive the signal lights having wavelengths λ1 to λn demultiplexed by the demultiplexing unit 15, and receive the superimposed signal light generation unit 11, the signal extraction unit 12, The frequency spectrum analyzing unit 13 and the passing node number measuring unit 14 are included.

  The superimposed signal light generation unit 11 performs amplitude modulation on each signal light included in the wavelength multiplexed light by performing amplitude modulation with a low frequency signal having the same frequency in each optical node device 2, and the low frequency is superimposed on each signal light. Wavelength multiplexed light (hereinafter referred to as “low frequency superimposed signal multiplexed light”) is generated.

  Specifically, the superimposed signal light generation unit 11 includes a low frequency signal generation unit 11a, a superposition circuit unit 11b, and a low frequency superposition unit 11c. The low-frequency signal generator 11a outputs a low-frequency signal (A · sin (ω · t), where A is a constant, ω is an angular velocity, and t is time) having the same frequency in each optical node device 2.

  The superimposing circuit unit 11b multiplies the low frequency signal extracted by the signal extracting unit 12 and the low frequency signal A · sin (ω · t) output from the low frequency signal generating unit 11a. Outputs a frequency signal. The low-frequency superimposing unit 11c generates low-frequency superimposed signal multiplexed light by performing amplitude modulation on the signal light λ1 demultiplexed by the demultiplexing unit 15 using the superimposed low-frequency signal.

  The signal extraction unit 12 extracts a low frequency signal having a frequency within a predetermined range from the superimposed signal light generated by the superimposed signal light generation unit 11 in the immediately preceding optical node device 2, and the extracted low frequency signal is a frequency spectrum analysis unit. 13 to output. For example, when the wavelength multiplexed light has already passed through the two optical node devices 2, the signal extraction unit 12 extracts the low frequency signal A · sin (ω · t) × A · sin (ω · t), The extracted low frequency signal is output to the spectrum analysis unit 13. At this time, the superimposing circuit unit 11b is obtained by multiplying the low frequency signal extracted by the signal extracting unit 12 and the low frequency signal A · sin (ω · t) generated by the low frequency signal generating unit 11a. A new low frequency signal Asin (ω · t) × Asin (ω · t) × Asin (ω · t) is superimposed on the wavelength multiplexed light.

  The frequency spectrum analysis unit 13 includes a spectrum analyzer, analyzes the frequency spectrum of the low frequency signal extracted by the signal extraction unit 12, and outputs the analyzed frequency spectrum to the passing node number measurement unit 14.

  The passing node number measuring unit 14 is based on the frequency spectrum analyzed by the frequency spectrum analyzing unit 13 and is a passing node that is the number of optical node devices 2 through which wavelength multiplexed light has passed before being transmitted to the optical node device 2. Measure the number. Specifically, the passing node number measuring unit 14 identifies a signal component having the highest frequency among the signal components included in the frequency spectrum analyzed by the frequency spectrum analyzing unit 13, and determines the frequency of the identified signal component. In each optical node device 2, the number of passing nodes is measured by dividing by the frequency ω · t of the same low-frequency signal A · sin (ω · t). That is, when wavelength multiplexed light passes through n optical node devices 2, the frequency of the signal component having the highest frequency is n · ω · t, so the number of passing nodes is nω · t / (ω · t ) = N.

  Next, optical transmission processing by the optical transmission system 1 according to the first embodiment will be described. FIG. 4 is a flowchart of the process procedure of the optical transmission process performed by the optical transmission system 1 according to the first embodiment.

  As shown in FIG. 4, in each optical node device 2 constituting the optical transmission system 1, the superimposed signal light generation unit 11 of the wavelength selective switch 4 performs a low-frequency signal Asin (ω having the same frequency in each optical node device 2. T) is superimposed on each signal light included in the wavelength multiplexed light (step S101). Each optical node device 2 transmits the wavelength multiplexed light on which the low frequency signal is superimposed to the optical node device 2 immediately after as the low frequency superimposed wavelength multiplexed light.

  In each optical node device 2, the signal extraction unit 12 of the wavelength selective switch 4 has a low frequency with a frequency within a predetermined range from the low-frequency superimposed signal light generated by the superimposed signal light generation unit 11 of the immediately preceding optical node device 2. A signal is extracted (step S102). Then, the signal extraction unit 12 outputs the extracted low frequency signal to the frequency spectrum analysis unit 13.

  Subsequently, the frequency spectrum analysis unit 13 analyzes the frequency spectrum of the low frequency signal extracted by the signal extraction unit 12 (step S103). Subsequently, the passing node number measuring unit 14 measures the number of passing nodes based on the frequency spectrum analyzed by the frequency spectrum analyzing unit 13 (step S104). The measured number of passing nodes is displayed on a predetermined display device or the like provided in the optical node device 2.

  As described above, in the optical transmission system 1 according to the first embodiment, each optical node device 2 converts a low-frequency signal having the same frequency in each optical node device 2 into a plurality of signal lights included in the wavelength multiplexed light. Superimpose. Each optical node device 2 extracts a low-frequency signal having a frequency within a predetermined range from the low-frequency superimposed signal light, and analyzes the frequency spectrum of the extracted low-frequency signal. Each optical node device 2 measures the number of passing nodes based on the analyzed frequency spectrum. As a result, when the optical transmission path is changed or the type of the optical node device is changed, the number of passing nodes can be presented to the user side. The conventional process of inquiring to can be omitted. As a result, it is possible to speed up the determination on the user side as to whether or not wavelength multiplexed light can be transmitted.

  In the first embodiment, an example in which the number of passing nodes is measured by superimposing a low frequency signal on each signal light included in the wavelength multiplexed light and analyzing the frequency spectrum of the superimposed low frequency signal will be described. did. On the other hand, in the second embodiment, the low frequency signal is superimposed on each of the signal lights included in the wavelength multiplexed light, and the frequency spectrum of the superimposed low frequency signal is analyzed, thereby the optical node device. An optical transmission system that identifies a passing optical node device, which is an optical node device through which wavelength multiplexed light has passed before transmission, will be described.

  First, the configuration of the optical node device 6 included in the optical transmission system according to the second embodiment will be described. FIG. 5 is a functional block diagram of the configuration of the optical node device 6 included in the optical transmission system according to the second embodiment. In addition, below, the detailed description is abbreviate | omitted as attaching | subjecting the same code | symbol to the site | part which has a function similar to Example 1. FIG. The schematic configuration of the optical transmission system according to the second embodiment is the same as the schematic configuration shown in FIG.

  As illustrated in FIG. 5, each optical node device 6 newly includes a wavelength selective switch 104 and a superimposed signal light generation unit 51 instead of the wavelength selective switch 4 included in the optical node device 2 illustrated in FIG. 2.

  The wavelength selective switch 104 drops (drops) signal light of an arbitrary wavelength from the wavelength multiplexed light input to the optical node device 6, or inserts (Add) signal light of an arbitrary wavelength into the wavelength multiplexed light. . Further, the wavelength selective switch 104 selects signal light having an arbitrary wavelength from the wavelength multiplexed light, and outputs the signal light having the selected wavelength to an arbitrary output port. Specifically, the wavelength selective switch 104 includes a spectroscopic device such as an AWG or a diffraction grating, and an optical switch device such as a MEMS mirror or a liquid crystal device. The output port is switched by moving the optical switch device corresponding to each wavelength.

  The superimposed signal light generation unit 51 generates wavelength multiplexed light (hereinafter referred to as “superimposed signal light”) obtained by superimposing low frequency signals having different frequencies on the wavelength multiplexed light in each optical node device 6. . For example, if the optical transmission system of the present embodiment has nine optical node devices 6 from the optical node device (1) to the optical node device (9), the superimposed signal light generation unit 51 may A low-frequency signal having a frequency α (N) is superimposed on the wavelength multiplexed light passing through the node device (N) (where N = 1 to 9, and when N is different, the value of α (N) is also different. Suppose).

  In the example illustrated in FIG. 5, the superimposed signal light generation unit 51 outputs a low-frequency signal having a different frequency in each optical node device 6 to the post-amplifier 5, and the low-frequency signal is wavelength-multiplexed in the post-amplifier 5. Superimpose. Thereby, the superimposed signal light generation unit 51 can collectively superimpose the low frequency signals on the signal light of all wavelengths included in the wavelength multiplexed light.

  FIG. 6 is a functional block diagram illustrating a configuration for executing extraction / superimposition of a low-frequency signal included in the wavelength selective switch 104. In the example illustrated in FIG. 6, only the configuration related to the extraction / superimposition characteristics of the wavelength selective switch 104 is illustrated, and the configuration corresponding to multiple inputs or multiple outputs is omitted.

  As illustrated in FIG. 6, the wavelength selective switch 104 includes a demultiplexing unit 115, a multiplexing unit 116, and low frequency signal extraction units (10-1 to 10-n). The low frequency signal extraction units 10-1 to 10-n respectively receive the signal lights having wavelengths λ1 to λ demultiplexed by the demultiplexing unit 115, and the signal extraction unit 112, the frequency spectrum analysis unit 113, A node device specifying unit 114.

  The signal extraction unit 112 extracts a low-frequency signal having a frequency within a predetermined range from the superimposed signal light generated by the superimposed signal light generation unit 51 in the immediately preceding optical node device 2, and the extracted low-frequency signal is used as the frequency spectrum analysis unit 113. Output to.

  The frequency spectrum analysis unit 113 is configured by a spectrum analyzer, analyzes the frequency spectrum of the low frequency signal extracted by the signal extraction unit 112, and outputs the analyzed frequency spectrum to the pass node device specifying unit 114.

  Based on the frequency spectrum analyzed by the frequency spectrum analyzing unit 113, the passing node device specifying unit 114 is a passing optical node device that is an optical node device 6 through which wavelength multiplexed light has passed before being transmitted to the optical node device 6. Is identified. Specifically, the transit node device identification unit 114 identifies the transit node device by identifying the frequency of the low frequency signal included in the frequency spectrum analyzed by the frequency spectrum analysis unit 113.

  Here, a method in which the transit node device identification unit 114 identifies the transit node device will be described. FIG. 7 is a diagram illustrating an example of a frequency spectrum analyzed by the frequency spectrum analysis unit 113. In FIG. 7, when the optical transmission system of the present embodiment has ten optical node devices 6 from the optical node device (1) to the optical node device (10), the optical node device (10) The frequency spectrum analyzed by the spectrum analysis unit 113 is shown. The superimposed signal light generation unit 51 superimposes a low-frequency signal having a frequency α (N) on the wavelength multiplexed light that passes through the optical node device (N) (where N = 1 to 9). , When N is different, the value of α (N) is also different).

  As shown in FIG. 7, the frequency spectrum analyzed by the frequency spectrum analysis unit 113 includes low-frequency signals having frequencies α1, α3, α4, and α6-α9, but includes low-frequency signals having frequencies α2 and α5. Not. In this case, the transit node device specifying unit 114 identifies the frequencies α1, α3, α4, and α6 to α9 of the low-frequency signal included in the frequency spectrum, so that the optical node device (1 ), (3), (4) and (6) to (9) are specified as transit node devices. Since the low-frequency signals having the frequencies α2 and α5 are not included in the frequency spectrum, the wavelength multiplexed light reaching the optical node device (10) does not pass through the optical node devices (2) and (5). I understand that.

  Next, optical transmission processing by the optical transmission system according to the second embodiment will be described. FIG. 8 is a flowchart illustrating a processing procedure of optical transmission processing by the optical transmission system according to the second embodiment.

  As shown in FIG. 8, in each optical node device 6 constituting the optical transmission system, the superimposed signal light generation unit 51 converts a low frequency signal having a different frequency in each optical node device 2 into a signal light included in the wavelength multiplexed light. (Step S201). Each optical node device 6 transmits the wavelength multiplexed light on which the low-frequency signal is superimposed to the optical node device 6 immediately after as the superimposed signal light.

  Further, in each optical node device 6, the signal extraction unit 112 of the wavelength selective switch 104 has a low frequency in a predetermined range from the low frequency superimposed signal light generated by the superimposed signal light generation unit 51 in the immediately preceding optical node device 6. A signal is extracted (step S202). Then, the signal extraction unit 112 outputs the extracted low frequency signal to the frequency spectrum analysis unit 113.

  Subsequently, the frequency spectrum analysis unit 113 analyzes the frequency spectrum of the low frequency signal extracted by the signal extraction unit 112 (step S203). Subsequently, the transit node device identification unit 114 identifies the transit node device based on the frequency spectrum analyzed by the spectrum analysis unit 113 (step S204). The transit node device is displayed on a predetermined display device provided in the optical node device 6.

  As described above, in the optical transmission system according to the second embodiment, each optical node device 6 superimposes a low frequency signal having a different frequency in each optical node device 6 on a plurality of signal lights included in the wavelength multiplexed light. To do. Each optical node device 6 extracts a low-frequency signal having a predetermined range of frequencies from the superimposed signal light, and analyzes the frequency spectrum of the extracted low-frequency signal. Then, each optical node device 6 identifies a passing node device based on the analyzed frequency spectrum. Thereby, when the optical transmission path is changed or the type of the optical node device is changed, the passing node device can be presented to the user side. This information on the transit node device is useful when considering a traffic bias in the entire optical transmission system and a detour route when a transmission failure occurs.

  In the second embodiment, an example of specifying a passing optical node device by superimposing a low frequency signal on each of signal light included in wavelength multiplexed light and analyzing a frequency spectrum of the superimposed low frequency signal. explained. On the other hand, the third embodiment is an optical node device in which a signal light having an arbitrary wavelength is inserted into the wavelength multiplexed light among the optical node devices included in the passing optical node device while specifying the passing optical node device. An optical transmission system that identifies an insertion node device will be described.

  First, the configuration of the optical node device 7 included in the optical transmission system according to the third embodiment will be described. FIG. 9 is a functional block diagram of the configuration of the optical node device 7 included in the optical transmission system according to the third embodiment. In addition, below, the detailed description is abbreviate | omitted as attaching | subjecting the same code | symbol to the site | part which has the same function as Example 2. FIG. The schematic configuration of the optical transmission system according to the third embodiment is the same as the schematic configuration shown in FIG.

  As shown in FIG. 9, each optical node device 7 includes a first superimposed signal light generation unit 52 and a second superimposed signal instead of the superimposed signal light generation unit 51 included in the optical node device 6 shown in FIG. And a light generation unit 54.

  The first superposed signal light generation unit 52 is configured to transmit the first low-frequency signal having a different frequency in each optical node device 7 upstream from the position of branching (Drop) or insertion (Add) by the wavelength selective switch 104. The optical signal is superimposed on each of the optical signals included in the wavelength multiplexed light. For example, if the optical transmission system of this embodiment has nine optical node devices 7 from the optical node device (1) to the optical node device (9), the first superimposed signal light generator 52 is provided. Superimposes a low-frequency signal of frequency α (N) as a first low-frequency signal on the wavelength multiplexed light that passes through the optical node device (N) (where N = 1 to 9, N being different) In this case, the value of α (N) is also different).

  In the example illustrated in FIG. 9, the first superimposed signal light generation unit 52 outputs the first low-frequency signal to the preamplifier 3, and the first low-frequency signal is output to the wavelength multiplexed light in the preamplifier 3. Superimposed. Thereby, the 1st superimposition signal light generation part 52 can superimpose a 1st low frequency signal collectively with respect to the signal light of all the wavelengths contained in wavelength multiplexing light.

  The second superimposed signal light generation unit 54 branches the second low-frequency signal having a frequency different from each optical node device 7 and having a frequency different from that of the first low-frequency signal by the wavelength selective switch 104 (Drop). Alternatively, it is superimposed on each of the signal lights included in the wavelength multiplexed light on the downstream side of the insertion (Add) position. For example, if the optical transmission system of this embodiment has nine optical node devices 7 from the optical node device (1) to the optical node device (9), the first superimposed signal light generation described above is performed. The unit 52 superimposes a low-frequency signal having a frequency α (N) as a first low-frequency signal on each of the signal lights included in the wavelength multiplexed light that passes through the optical node device (N) (where N = 1 to 9, and when N is different, the value of α (N) is also different). On the other hand, the second superimposed signal light generation unit 54 outputs a low-frequency signal having a frequency β (N) to the second low-frequency signal for each of the signal lights included in the wavelength multiplexed light passing through the optical node device (N). Superposed as a frequency signal (where N = 1 to 9, and when N is different, the value of β (N) is also different and α (N) ≠ β (N)).

  In the example illustrated in FIG. 9, the second superimposed signal light generation unit 54 outputs the second low-frequency signal to the post-amplifier 5, and the second low-frequency signal is wavelength-multiplexed within the post-amplifier 5. Is superimposed. Thereby, the 2nd superimposition signal light generation part 54 can superimpose a 2nd low frequency signal collectively with respect to the signal light of all the wavelengths contained in wavelength multiplexing light.

  The pass node device specifying unit 114 (see FIG. 6) of the wavelength selective switch 104 specifies the pass node device based on the frequency spectrum analyzed by the spectrum analyzing unit 113, and the optical node device 7 included in the pass node device. Among these, the insertion node device is specified.

  Here, a method in which the transit node device identification unit 114 identifies the transit node device and the insertion node device will be described. FIG. 10 is a diagram illustrating an example of a frequency spectrum analyzed by the frequency spectrum analysis unit 113. In FIG. 10, when the optical transmission system of the present embodiment has ten optical node devices 7 from the optical node device (1) to the optical node device (10), the optical node device (10) The frequency spectrum analyzed by the frequency spectrum analysis unit 113 is shown. The first superimposed signal light generation unit 52 superimposes a low-frequency signal having a frequency α (N) as a first low-frequency signal on the wavelength multiplexed light that passes through the optical node device (N). (However, N = 1 to 9, and when N is different, the value of α (N) is also different). The second superimposed signal light generation unit 54 superimposes a low-frequency signal having a frequency β (N) as a second low-frequency signal on the wavelength multiplexed light that passes through the optical node device (N). (However, if N = 1 to 9 and N is different, the value of β (N) is also different, and α (N) ≠ β (N)).

  As shown in FIG. 10, the frequency spectrum analyzed by the frequency spectrum analysis unit 113 includes the first low-frequency signals having the frequencies α1, α3, α4, α6 to α9, and the frequencies β1, β2, β3, β4, β6 to and a second low-frequency signal of β9. On the other hand, this frequency spectrum does not include the first low-frequency signal having the frequencies α2 and α5 and the second low-frequency signal having the frequency β5. In this case, the transit node device identification unit 114 identifies nine frequencies by identifying the frequencies α1, β1, β2, α3, β3, α4, β4, α6, β6, α7, β7, α8, β8, α9, and β9. Among the optical node devices 7, the optical node devices (1), (2), (3), (4), and (6) to (9) are identified as transit node devices.

  Further, the transit node device specifying unit 114 inserts the optical node device (2) among the optical node devices included in the transit node device by identifying the frequency β2 of the second low-frequency signal included in the frequency spectrum. Identifies as a node device.

  That is, as described above, the first superimposed signal light generation unit 52 converts the first low-frequency signal of the optical signal included in the wavelength multiplexed light upstream of the branching or inserting position by the wavelength selective switch 104. Superimpose for each. On the other hand, the second superimposed signal light generation unit 54 superimposes the second low-frequency signal on each of the optical signals included in the wavelength multiplexed light on the downstream side of the branch or insertion position by the wavelength selective switch 104. To do. For this reason, the signal light of an arbitrary wavelength inserted by the wavelength selective switch 104 should include only the second low frequency signal, not including the first low frequency signal. Therefore, the pass node device specifying unit 114 inserts the optical node device (2) among the optical node devices included in the pass node device by identifying the frequency β2 of the second low frequency signal included in the frequency spectrum. It can be specified as a node device.

  Next, an optical transmission process performed by the optical transmission system according to the third embodiment will be described. FIG. 11 is a flowchart of a process procedure of an optical transmission process performed by the optical transmission system according to the third embodiment.

  As shown in FIG. 11, in each optical node device 7 configuring the optical transmission system, the first superimposed signal light generation unit 52 selects the first low-frequency signal having a different frequency in each optical node device 7 by wavelength selection. The optical signal is superimposed on each of the optical signals included in the wavelength multiplexed light upstream of the position of branching or insertion by the switch 104. At the same time, the second superimposed signal light generator 54 branches the second low-frequency signal having a frequency different from each optical node device 7 and having a frequency different from that of the first low-frequency signal by the wavelength selective switch 104. Alternatively, it is superimposed on each of the optical signals included in the wavelength multiplexed light downstream from the insertion position (step S301). Each optical node device 7 transmits the wavelength multiplexed light on which the low-frequency signal is superimposed to the optical node device 7 immediately after as the superimposed signal light.

  In each optical node device 7, the signal extraction unit 112 of the wavelength selective switch 104 is generated by the first superimposed signal light generation unit 52 and the second superimposed signal light generation unit 54 in the immediately preceding optical node device 7. A low frequency signal having a predetermined frequency range is extracted from the low frequency superimposed signal light (step S302). Then, the signal extraction unit 112 outputs the extracted low frequency signal to the frequency spectrum analysis unit 113.

  Subsequently, the frequency spectrum analysis unit 113 analyzes the frequency spectrum of the low frequency signal extracted by the signal extraction unit 112 (step S303). Subsequently, the transit node device identification unit 114 identifies the transit node device and the insertion node device based on the frequency spectrum analyzed by the spectrum analysis unit 113 (step S304). The transit node device and the insertion node device are displayed on a predetermined display device or the like provided in the optical node device 7.

  As described above, in the optical transmission system according to the third embodiment, each optical node device 7 uses the wavelength selective switch 104 to branch or insert the first low-frequency signal having a different frequency in each optical node device 7. Further, it is superimposed on a plurality of signal lights included in the wavelength multiplexed light on the upstream side. At the same time, the optical node device 7 uses the wavelength selective switch 104 to branch or insert the second low-frequency signal having a frequency different from each optical node device 7 and having a frequency different from that of the first low-frequency signal. Is also superimposed on a plurality of signal lights included in the wavelength multiplexed light on the downstream side. Each optical node device 7 extracts a low frequency signal having a frequency within a predetermined range from the superimposed signal light, and analyzes the frequency spectrum of the extracted low frequency signal. Then, each optical node device 7 specifies the passing node device and the insertion node device based on the analyzed frequency spectrum. Thus, when the optical transmission path is changed or the type of the optical node device is changed, the insertion node device can be presented to the user side in addition to the transit node device. This information on the insertion node device is useful when considering a traffic bias in the entire optical transmission system and a detour route when a transmission failure occurs.

DESCRIPTION OF SYMBOLS 1 Optical transmission system 2 Optical node apparatus 3 Preamplifier 4 Wavelength selection switch 5 Post amplifier 6 Optical node apparatus 7 Optical node apparatus 11 Superimposed signal light generation part 11a Low frequency signal generation part 11b Superimposition circuit part 12 Signal extraction part 13 Frequency spectrum analysis part 14 passing node number measuring unit 51 superimposed signal light generating unit 52 first superimposed signal light generating unit 54 second superimposed signal light generating unit 104 wavelength selective switch 112 signal extracting unit 113 frequency spectrum analyzing unit 114 passing node device specifying unit

Claims (1)

An optical transmission system in which wavelength multiplexed light including a plurality of signal lights having different wavelengths is transmitted by a plurality of optical node devices connected to each other via an optical transmission path,
The optical node device is:
For each of the plurality of signal lights included in the input wavelength division multiplexed light,
Superimposed signal light generating means for superimposing low frequency signals having different frequencies in the plurality of optical node devices;
For each of the plurality of signal lights,
Low-frequency signal extraction means for extracting low-frequency signals each having a predetermined range of frequencies;
For each of the plurality of signal lights,
By identifying the frequency of the low-frequency signal extracted by the low-frequency signal extraction means, the passing optical node device that is the optical node device through which the wavelength multiplexed light has passed before being transmitted to the optical node device is specified. And a transit node device specifying means for
The optical node device branches an optical signal having an arbitrary wavelength from the wavelength-multiplexed light, or an optical add-drop multiplexer (OADM) that inserts an optical signal having an arbitrary wavelength into the wavelength-multiplexed light. And
The superimposed signal light generation unit superimposes a first low-frequency signal having a different frequency in the plurality of optical node devices on each of the plurality of signal lights on an upstream side of the branch or the insertion position. A second low-frequency signal having a frequency different from that of the plurality of optical node devices and having a frequency different from that of the first low-frequency signal is superimposed on a downstream side of the branch or the insertion position ;
The low frequency signal extracting means extracts the first low frequency signal and the second low frequency signal as the low frequency signal,
The passing node device specifying unit is configured to detect the plurality of optical node devices when at least one of the first low frequency signal and the second low frequency signal is extracted by the low frequency signal extracting unit. Among them, an optical node device corresponding to at least one of the first low frequency signal and the second low frequency signal is specified as the passing optical node device, and further, the low frequency signal extracting unit When only the second low-frequency signal is extracted from the first low-frequency signal and the second low-frequency signal, the frequency of the second low-frequency signal in the passing optical node device is set. An optical transmission system , wherein a corresponding optical node device is specified as an inserted optical node device into which the signal light is inserted .

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