JP6625946B2 - Optical transmission system, optical node device, and optical transmission method - Google Patents

Description

  The present invention relates to an optical transmission system, an optical node device, and an optical transmission method.

  With the recent increase in the use of the Internet, the amount of communication traffic in networks using optical fibers has been increasing year by year. In the near future, due to the explosive use of the Internet of things and high-definition video technology, it is expected that the amount of traffic that cannot be covered by the current network infrastructure will increase in the near future. Then, as one of the technologies corresponding to the traffic which increases explosively, the spatial multiplexing technology in the optical signal has attracted attention. The spatial multiplexing technique is a technique for realizing a large transmission capacity per transmission path by using a plurality of optical paths for one transmission path. In particular, in a core network which is a trunk line in a network, since it plays a role of aggregating the traffic of the entire region and transmitting between regions, it is necessary to realize a long-distance and large-capacity optical transmission system.

The optical transmission system used in the current core network is a mesh network in which transmission lines using optical fibers that pass optical signals are arranged in a mesh, and the path switching of signals called nodes is made at the contact point of each transmission line. And branch points for relay amplification and monitoring. The current transmission line uses a single-mode optical fiber having one core that can pass one optical mode per fiber as a transmission line for polarization- and wavelength-multiplexed optical signals. By using a multi-core fiber (MCF) having a plurality of cores per fiber, the transmission capacity can be greatly increased.
Also, as for nodes, a plurality of transmission lines having a large capacity are input, so that a larger scale is required than the transmission lines.

(Conventional optical transmission system)
FIG. 29 is a configuration diagram of a conventional optical transmission system. The figure shows an example of an optical transmission system including a transmission device 910, optical nodes 920a and 920b, a reception device 930, and optical transmission lines 801 to 807 using single mode fibers. The transmitting device 910 has an optical multiplexed signal generating unit 911, and the receiving device 930 has an optical multiplexed signal receiving unit 931. Each of the optical nodes 920a and 920b has an optical cross connect (OXC) 921a and 921b composed of an optical switch group.

FIG. 30 is a diagram illustrating a single mode fiber used as the optical transmission lines 801 to 807. A single mode fiber has one core for transmitting light.
FIG. 31 is a diagram showing an outline of the optical cross connects 921a and 921b. The optical cross connects 921a and 921b output an optical signal input from an input route to an arbitrary output route. FIG. 2 shows an example in which the number of input routes and the number of output routes are each two. By providing an optical channel monitor (power monitor) on the optical path, the optical intensity of an optical signal can be measured.

  In the optical transmission system shown in FIG. 29, an optical multiplex signal to be transmitted passes from the transmission device 910 to the optical transmission line 801 → the optical node 920 a → the optical transmission line 803 → the optical node 920 b → the optical transmission line 806, and Will be described. The optical signal is generated by the optical multiplexed signal generation unit 911 of the transmission device 910, transmitted through the optical transmission line 801 and then input to the optical node 920a. The optical node 920a uses the optical transmission paths 801 and 802 as input paths and the optical transmission paths 803 and 804 as output paths. All routes are connected to the optical cross connect 921a in the optical node 920a, and optical signals from the optical transmission lines 801 and 802 as input routes are sent to the optical transmission lines 803 and 804 as arbitrary output routes. Can output. The optical node 920b uses the optical transmission paths 803 and 805 as input paths and the optical transmission paths 806 and 807 as output paths. All routes are connected to the optical cross-connect 921b in the optical node 920b, and optical signals from the optical transmission lines 803 and 805 as input routes are sent to the optical transmission lines 806 and 807 as arbitrary output routes. Can output. Each of the optical nodes 920a and 920b can include an optical signal transmission line including an add / drop unit in an input / output path. The optical signal transmitted through the optical transmission line 806 is received by the optical multiplexed signal receiving unit 931 of the receiving device 930.

(Optical transmission system with large capacity of conventional optical transmission system)
As a system in which the capacity of the conventional optical transmission system shown in FIG. 29 is increased, a spatial multiplexing transmission system shown in FIG. 32 can be considered. The figure shows an example of a spatial multiplexing transmission system including a transmitting device 950, spatial multiplexing nodes 960a and 960b, a receiving device 970, and optical transmission lines 211 to 217. For the optical transmission lines 211 to 217, a bundle fiber in which a plurality of single mode fibers (SMF: Single mode fiber) are bundled, or a multi-core fiber (MCF: Multi-core fiber) having a plurality of cores in one fiber is used. The transmitting device 950 has an optical multiplexed signal generation unit 951, and the receiving device 970 has an optical multiplexed signal receiving unit 971. The spatial multiplexing nodes 960a and 960b have optical cross-connects 961a and 961b, respectively, composed of optical switch groups.

  In the spatial multiplexing transmission system shown in FIG. 32, an optical multiplex signal to be transmitted passes from transmitting apparatus 950 to optical transmission path 211 → spatial multiplexing node 960a → optical transmission path 213 → spatial multiplexing node 960b → optical transmission path 216. , The receiving device 970 will be described. The optical multiplexed signal is generated by the optical multiplexed signal generator 951 of the transmitting device 950, and is input to the spatial multiplexing node 960a after being transmitted through the optical transmission line 211. The spatial multiplexing node 960a uses the optical transmission paths 211 and 212 as input paths and the optical transmission paths 213 and 214 as output paths. All the paths are connected to the optical cross connect 961a in the spatial multiplexing node 960a, and the optical multiplexed signals from the optical transmission paths 211 and 212, which are input paths, are transmitted to the optical transmission path 213, which is an arbitrary output path. 214. The spatial multiplexing node 960b uses the optical transmission lines 213 and 215 as input routes and the optical transmission lines 216 and 217 as output routes. All the paths are connected to the optical cross connect 961b in the spatial multiplexing node 960b, and the optical multiplexed signals from the optical transmission paths 213 and 215, which are input paths, are converted to the optical transmission paths 216 and 216 which are arbitrary output paths. 217. Each of the spatial multiplexing nodes 960a and 960b can include an optical signal transmission path from an add / drop unit in an input / output path. The optical multiplexed signal transmitted through the optical transmission line 216 is received by the optical multiplexed signal receiving unit 971 of the receiving device 970.

(Issues of large capacity optical transmission systems)
In the above-described spatial multiplexing transmission system, crosstalk (TX) from different spatial channels occurs during transmission on the optical transmission lines 211 to 217, which are multi-core fibers, and in the optical cross-connects 961a and 961b. Noise ratio (OSNR) is degraded.

  FIG. 33 shows the occurrence of crosstalk in an optical transmission system using a single mode fiber, and FIG. 34 shows the occurrence of crosstalk in a spatial multiplexing transmission system. In FIG. 33, crosstalk occurs in the optical cross-connect, but crosstalk does not occur in the transmission path, so that the crosstalk accumulated in the optical signal received by the receiving device is small. On the other hand, as shown in FIG. 34, in the spatial multiplexing transmission system, crosstalk generated in each unit such as a transmission path and an optical cross connect is accumulated. Further, when crosstalk occurs due to an external factor at an arbitrary point in the system, it is conceivable that further deterioration of OSNR occurs, which affects transmission quality. However, conventional optical transmission systems and spatial multiplexing transmission systems have no function of monitoring crosstalk between channels, and thus have a problem in that the amount of crosstalk cannot be determined.

T. Kawai et al., "Multi-degree ROADM based on massive port count WSS with integrated Colorless ports", OFC / NFOEC, 2011, OTuD2 K. Takenaga et al., "An Investigation on Crosstalk in Multi-Core Fibers by Introducing Random Fluctuation along Longitudinal Direction", IEICE TRANSACTIONS on Communications, 2011, Vol.E94-B, No.2, p.409-416 Tanaka et al., "Simplified Equation for Understanding Behavior of Crosstalk between Cores in Multicore Optical Fiber", The Institute of Electronics, Information and Communication Engineers, Transactions of the Institute of Electronics, Information and Communication Engineers B, 2014, Vol.J97-B, No. 5, p.383-392 H. Ono et al., "Inter-core crosstalk measurement in multi-core fiber amplifier using multiple intensity tones", Electronics Letters, 2014, Vol. 50, No. 14, p. 1009-1010.

  The current transmission network is composed of a transmission line and a node using a single-mode single-core fiber, but with an increase in traffic in recent years, an increase in the throughput of the node is required. The throughput is represented by the product of the transmission capacity per route and the number of routes. To increase the node throughput, (1) increase the number of routes and (2) increase the capacity per route It is considered necessary. However, it is conceivable that the number and the scale of the optical switches required for switching the transmission path of the optical signal passing through the node in any of the methods become huge.

  When the number of switches increases, it is considered that the number of crosstalk signals mixed with a certain optical signal increases inside the optical cross connect, and the deterioration of the optical signal-to-noise ratio (OSNR) due to crosstalk increases. Also, it is considered that when the switch scale increases, the crosstalk amount of the switch alone increases, which leads to deterioration of OSNR.

  The above-described signal deterioration is cumulative, and if the signal deterioration within a node increases, the signal deterioration will accumulate due to passing through a plurality of nodes, and demodulation at the receiving end will not be possible. However, crosstalk cannot be monitored by the optical channel monitor (power monitor) installed in the current node.

  In view of the above circumstances, an object of the present invention is to provide an optical transmission system, an optical node device, and an optical transmission method that achieve both the maintenance of signal quality and the expansion of transmission capacity.

  One embodiment of the present invention is an optical transmission system having an optical node device connected to two or more input routes and two or more output routes, wherein each of the input routes has an optical multiplexed signal. One or more input optical paths to be input, and one or more of the input paths have two or more of the input optical paths, and the output paths each have an output optical path from which an optical multiplexed signal is output. One or more output paths, the one or more output paths have two or more output optical paths, and the optical node device comprises an optical signal multiplexed into an optical multiplexed signal input by the input optical path. Comprises an optical cross-connect switch unit for outputting from the output optical path arbitrarily selected, wherein the optical cross-connect switch unit converts the wavelength band of the optical multiplex signal into the optical multiplex signal input from the input optical path. Modules that provide monitor light of different bands At least one of a monitor light extraction unit and a monitor light extraction unit that extracts, from an optical multiplexed signal in which the optical signal to be output from the output optical path is multiplexed, monitor light in a band different from the wavelength band of the optical multiplexed signal. Is provided.

  One embodiment of the present invention is the optical transmission system described above, wherein the optical cross-connect switch unit includes at least the monitor light extraction unit, and the optical node device transmits the monitor light extracted by the monitor light extraction unit. The monitor light receiving unit further includes a monitor light receiving unit that receives the signal, and a signal processing unit that acquires an optical characteristic obtained by measuring the monitor light received by the monitor light receiving unit.

  One aspect of the present invention is the optical transmission system described above, wherein the signal processing unit estimates the optical characteristics of the optical multiplexed signal based on the optical characteristics, and the optical cross-connect switch unit based on the estimation result. Reset the optical path from the input path to the output path.

  According to one aspect of the present invention, in the above-described optical transmission system, the optical cross-connect switch unit includes at least the monitor light providing unit, and the optical node device branches an optical multiplex signal transmitted by the input optical path. An optical branching unit, comprising a light intensity measuring unit that measures the light intensity of each optical signal included in the optical multiplexed signal branched by the optical branching unit, the signal processing unit is measured by a light intensity measuring unit And correcting the optical characteristics based on the light intensity.

  According to one aspect of the present invention, in the above-described optical transmission system, the optical cross-connect switch unit includes at least the monitor light providing unit, and the optical node device branches an optical multiplex signal transmitted by the input optical path. An optical branching unit, comprising a light intensity measuring unit that measures the light intensity of each optical signal included in the optical multiplexed signal branched by the optical branching unit, the monitor light providing unit, the light intensity measuring unit Monitor light whose light intensity is set according to the average value of the measured light intensity is provided.

  One aspect of the present invention is a transmission device that generates an optical multiplexed signal to be input to the input optical path and provides and transmits monitor light in a band different from the wavelength band of the optical multiplexed signal in the optical transmission system described above. A receiving device to which a monitor light is provided and receives the optical multiplexed signal output from the output optical path, and branches the monitor light in a band different from the wavelength band of the optical multiplexed signal from the optical multiplexed signal. Equipped with one.

  One aspect of the present invention is an optical node device connected to two or more input paths and two or more output paths, wherein the input paths are respectively input optical paths to which an optical multiplexed signal is input. And one or more of the input paths have two or more of the input optical paths, and the output path has one or more output optical paths from which an optical multiplexed signal is output. And one or more of the output paths have two or more of the output optical paths, and each of the optical signals multiplexed into the optical multiplexed signal input by the input optical path is output from the arbitrarily selected output optical path. An optical cross-connect switch section for outputting, wherein the optical cross-connect switch section applies monitor light to the optical multiplexed signal input from the input optical path, to provide monitor light in a band different from the wavelength band of the optical multiplexed signal. And output from the output optical path From serial optical multiplex signal light signals are multiplexed, comprising at least one of the monitor light extraction section for extracting the monitor light different band than the wavelength band of the optical multiplexed signal.

  One aspect of the present invention is an optical transmission method executed by an optical transmission system having an optical node device connected to two or more input routes and two or more output routes, wherein the input route is Each has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths, and the output paths each have an optical multiplexed signal. The optical node device has one or more output optical paths to be output, and one or more of the output paths has two or more of the output optical paths, and the optical node device includes an optical multiplexed signal input to the input optical path. Each of the multiplexed optical signals has an optical cross-connect switch unit for outputting the arbitrarily selected output optical path from the output optical path, and a monitor light providing unit included in the optical cross-connect switch unit or the transmission device is input from the input optical path. Optical multiplexed signal A monitor light providing step of providing monitor light of a band different from the wavelength band of the optical multiplexed signal, and a monitor light extraction unit provided in the optical cross-connect switch unit or the receiving device, wherein the optical signal output from the output optical path is A monitor light extracting step of extracting, from the multiplexed optical multiplexed signal, monitor light in a band different from the wavelength band of the optical multiplexed signal.

  According to the present invention, it is possible to achieve both the maintenance of signal quality and the expansion of transmission capacity in an optical transmission system.

FIG. 1 is a configuration diagram of an optical cross-connect system according to a first embodiment of the present invention. FIG. 2 is a diagram illustrating a bundle fiber used in the optical cross-connect system of the embodiment. FIG. 2 is a diagram illustrating a multi-core fiber used in the optical cross-connect system of the embodiment. FIG. 3 is a diagram illustrating a configuration near an optical node according to the first embodiment. It is a figure showing the example of composition of the monitor light transmission part and the monitor light provision part of the embodiment. It is a figure showing the example of composition of the monitor light transmission part and the monitor light provision part of the embodiment. It is a figure showing the example of composition of the monitor light transmission part and the monitor light provision part of the embodiment. It is a figure showing the example of composition of the monitor light transmission part and the monitor light provision part of the embodiment. It is a figure showing the example of composition of the monitor light transmission part and the monitor light provision part of the embodiment. It is a figure showing the example of composition of the monitor light transmission part and the monitor light provision part of the embodiment. It is a figure showing the example of composition of the monitor light transmission part and the monitor light provision part of the embodiment. It is a figure showing an example of composition of a monitor light extraction part and a monitor light reception part of the embodiment. It is a figure showing an example of composition of a monitor light extraction part and a monitor light reception part of the embodiment. It is a figure showing an example of composition of a monitor light extraction part and a monitor light reception part of the embodiment. It is a figure showing an example of composition of a monitor light extraction part and a monitor light reception part of the embodiment. It is a figure showing a monitor time chart of the embodiment. It is a figure showing an example of composition of a monitor light extraction part and a monitor light reception part of the embodiment. FIG. 5 is a configuration diagram of an optical cross-connect system according to a second embodiment. FIG. 2 is a diagram illustrating a device configuration near an optical node and a transmission device according to the first embodiment. FIG. 13 is a configuration diagram of an optical cross-connect system according to a third embodiment. FIG. 2 is a diagram illustrating a device configuration near an optical node and a transmission device according to the first embodiment. It is a figure showing the device composition near the optical node by a 4th embodiment. FIG. 3 is a diagram illustrating a device configuration near an optical node according to the same embodiment. It is a figure showing the example of composition of the monitor light transmission part and the monitor light provision part of the embodiment. It is a figure showing the example of composition of the monitor light transmission part and the monitor light provision part of the embodiment. It is a figure showing the device composition near the optical node by a 5th embodiment. It is a figure which shows the outline | summary of the monitor light output adjustment system of the embodiment. It is a figure which shows the outline | summary of the monitor light output adjustment system of the embodiment. FIG. 2 is a configuration diagram of a conventional optical transmission system. FIG. 2 is a diagram illustrating a single mode fiber used in a conventional optical transmission system. It is a figure which shows the outline | summary of the conventional optical cross connect. FIG. 1 is a configuration diagram of a conventional spatial multiplex transmission system. FIG. 11 is a diagram illustrating a state of occurrence of crosstalk in a conventional optical transmission system. FIG. 11 is a diagram illustrating a state of occurrence of crosstalk in a conventional spatial multiplexing transmission system.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

(1st Embodiment)
[Overall structure explanation]
FIG. 1 is a configuration diagram of a large-capacity optical transmission system 11 according to the present embodiment. The large-capacity optical transmission system 11 includes a transmitting device 100, an optical node 401a, an optical node 401b, a receiving device 300, and optical transmission lines 211 to 217. The transmission device 100 and the optical node 401a are connected by the optical transmission line 211. The optical node 401a and the optical node 401b are connected by an optical transmission line 213. The optical node 401b and the receiving device 300 are connected by an optical transmission line 216. The other optical transmission lines 212, 214, 215, and 217 connected to the optical node 401a or the optical node 401b are connected to other optical nodes.

The transmission device 100 includes a signal generation unit 110. The signal generation unit 110 generates an optical multiplex signal, and the generated optical multiplex signal is transmitted through the optical transmission line 211. The optical multiplex signal is an optical signal obtained by multiplexing an optical signal using one or more optical frequencies.
The receiving device 300 includes a signal receiving unit 310. The signal receiving unit 310 receives an optical multiplex signal transmitted through the optical transmission line 216.

  The optical node 401a and the optical node 401b have the same configuration. When the optical node 401a and the optical node 401b are not distinguished, they are described as an optical node 401. The optical node 401 includes a monitor light providing unit 430, an optical switch group 440, and a monitor light extraction unit 450. In the present embodiment, the monitor light giving unit 430, the optical switch group 440, and the monitor light extracting unit 450 are collectively called an optical cross connect (OXC) switch. In the optical cross connect switch, a monitor light giving section 430 and a monitor light extracting section 450 are connected to the optical switch group 440. The input path is connected to the monitor light giving section 430, and the output path is connected to the monitor light extraction section 450.

As the optical transmission paths 211 to 217 of the large-capacity optical transmission system 11, a bundle fiber or a multi-core fiber can be used.
FIG. 2 is a diagram illustrating a bundle fiber. The bundle fiber has a configuration in which a plurality of single mode fibers are bundled. Each single mode fiber has one core.
FIG. 3 is a diagram illustrating a multi-core fiber. The multi-core fiber has a plurality of cores.

[Detailed explanation of each part]
The main components of the optical node 401 in the configuration of the large-capacity optical transmission system 11 shown in FIG. 1 will be described with reference to FIG.

  FIG. 4 is a diagram showing a configuration near the optical node 401, and only the configuration related to the present embodiment is extracted and shown. There are two or more optical transmission paths to and from the optical node 401, and at least one of the paths includes two or more optical paths per path. In the case of the optical node 401a, input routes using the optical transmission lines 211 and 212 are referred to as input routes 1 and 2, and output routes using the optical transmission lines 213 and 214 are referred to as output routes 1 and 2. The input paths 1 and 2 include optical paths 1 to 3, respectively, and the output paths 1 and 2 include optical paths 1 to 3, respectively. In the following, like the optical node 401a, the number n1 of the input routes and the number n2 of the output routes are two, which is the number of optical paths included in one input route, and one output route. A case where k, which is the number of optical paths included, is 3 will be described as an example. The number p1 of optical paths combining all input paths and the number p2 of optical paths combining all output paths are respectively 6.

  The optical node 401 has an optical cross connect (OXC) switch unit 410. The OXC switch unit 410 includes a monitor light giving unit 430, an optical switch group 440, and a monitor light extraction unit 450. Note that the amplification functions and the like before and after the OXC switch unit 410 are omitted.

  The optical switch group 440 has optical input ports connected to a total of six (p1) optical paths in two optical input paths, and a total of six (p2) optical paths in the optical output paths. ) Has an optical output port connected to the optical path. Further, the optical switch group 440 includes an optical switch (SW) 443 connected to each optical input port and an optical switch (SW) 445 connected to each optical output port. An optical switch is an element having a function of outputting an optical signal input to an optical input port to an arbitrary optical output port. Each of the optical switches 443 can output an optical multiplexed signal input from a corresponding optical input port to an arbitrary optical path by switching to an arbitrary optical path for each optical signal. Each optical switch 445 receives an optical signal whose optical path has been switched by each optical switch 443 and outputs the optical signal to a corresponding output port. Hereinafter, an optical switch 443 connected to an optical input port to which an optical multiplexed signal transmitted through an optical path j (j = 1,..., K) of an input path i (i = 1,. An optical switch 445 connected to an optical output port that outputs an optical multiplexed signal to an optical path of an optical path j in an output path i (i = 1,..., N2) is referred to as an optical switch 443-ij. -Ij.

  In the present embodiment, six (p1) wavelength multiplexers 431 are used as the monitor light giving section 430. An input optical path, an output optical path, and an optical path for monitor light are connected to the wavelength multiplexer 431. The wavelength multiplexer 431 gives monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the optical path serving as the input optical path. An optical path j (j = 1,..., K) of an input path i (i = 1,..., N1) is set as an input optical path, and a wavelength multiplexer 431 for providing monitor light to an optical multiplexed signal input from the input optical path. Is described as a wavelength multiplexer 431-ij.

  In the present embodiment, six (p2) wavelength demultiplexers 451 are used as the monitor light extraction unit 450. An input optical path, an output optical path, and an optical path for monitor light are connected to the wavelength demultiplexer 451. The wavelength demultiplexer 451 demultiplexes the optical multiplexed signal and the monitor light from the optical multiplexed signal to which the monitor light is added, and outputs the light in the monitor light band to the monitor optical path, and the optical multiplex signal in the wavelength band of the optical multiplex signal. To the optical path of the output path. The optical path j of the output path i is set as the output optical path, and the wavelength demultiplexer 451 that outputs the demultiplexed optical multiplexed signal is referred to as a wavelength demultiplexer 451-ij. In the present embodiment, each wavelength demultiplexer 451 is configured so that the monitor light is output only to the monitor light optical path and not to the output optical path.

  The optical node 401 has a monitor light transmission unit 420 and a monitor light reception unit 460 in addition to the OXC switch unit 410 (omitted in FIG. 1). The monitor light transmitting section 420 is provided outside the monitor light providing section 430, and supplies monitor light within the monitor light band to the monitor light providing section 430. The monitor light transmission section 420 has six (p1) monitor light sources 421. The monitor light supplied from the monitor light source 421 is input to the wavelength multiplexer 431. The monitor light source 421 that supplies the monitor light to the wavelength multiplexer 431-ij is referred to as a monitor light source 421-ij.

  The monitor light receiving section 460 is located outside the monitor light extraction section 450, and receives the monitor light within the monitor light band extracted by the monitor light extraction section 450. The monitor light receiving section 460 includes six (p2) monitor light receiving units 461. The monitor light receiving unit 461 includes a monitor light splitter 462 and a plurality of light receivers 463. Each output port of the monitor light splitter 462 is connected to a different light receiver 463. The monitor light receiving unit 461 to which the monitor light is input to the monitor light splitter 462 from the wavelength splitter 451-ij of the monitor light extracting unit 450 via the monitoring optical path is referred to as a monitor light receiving unit 461-ij. Describe. The monitor light splitter 462 included in the monitor light receiving unit 461-ij is referred to as a monitor light splitter 462-ij, and six monitor light splitters 462-ij connected to the monitor light splitter 462-ij. The light receiver 463 is described as light receivers 463-ij-1 to 463-ij-6.

  The large-capacity optical transmission system 11 according to the present embodiment includes a signal processing device 501 (omitted in FIG. 1). The signal processing device 501 may be provided in the optical node 401 or may be provided outside the optical node 401. The signal processing device 501 has a function of transmitting a control signal to the optical switch group 440 based on the monitor signal received by the monitor light receiving unit 460.

[Description of monitor method]
In the present embodiment, the large-capacity optical transmission system 11 performs crosstalk on the optical multiplexed signal S1123 input from the input path 1 and the optical path 1 and output to the output path 2 and the optical path 3 from the other path and another optical path. A method for monitoring the data will be described. The large-capacity optical transmission system 11 also monitors an optical multiplexed signal input from another route / another optical path in the same manner. The present embodiment is characterized in that monitor light is input to all the optical paths in the optical path from the monitor light providing unit 430 and thereafter to the monitor light extracting unit 450.

First, the optical multiplex signal S1123 input from the input path 1 optical path 1 is input to the monitor light providing section 430 inside the optical cross connect switch section 410.
Further, each monitor light source 421 of each monitor light transmission unit 420 outputs monitor light M11 to M23 having a different optical frequency. That is, the monitor light source 421-ij outputs the monitor light Mij. Here, monitor light other than the C band which is the wavelength band of the optical multiplex signal in the CW (continuous) light is used. Thus, the monitor light does not overlap with the optical multiplexed signal light.

  The monitor light output from each monitor light source 421 is added to each optical multiplex signal by the wavelength multiplexer 431. For example, to the optical multiplexed signal S1123 input to the input path 1 optical path 1, the monitor light M11 output from the monitor light source 421-1-1 is added by the wavelength multiplexer 431-1-1.

  The optical multiplex signal S1123 to which the monitor light M11 is added is input into the optical switch group 440. The optical multiplexed signal S1123 input to the optical switch group 440 is switched by the optical switch 443-1-1 to an arbitrary output path and an arbitrary optical path. This time, it is assumed that the switching to the output path 2 and the optical path 3 is performed.

  At this time, the optical switch 443 superimposes the crosstalk components of the optical multiplexed signal from the other path and the other optical path and the monitor light. That is, the optical multiplexed signal S1123 includes the crosstalk components XT_12, XT_13, XT_21, XT_22, and XT_12 of the optical multiplexed signal input from the optical paths 2 and 3 of the input path 1 and the optical paths 1 to 3 of the input path 2 respectively. XT_23 and crosstalk components XT_m12, XT_m13, XT_m21, XT_m22, and XT_m23 of five monitor lights M12, M13, M21, M22, and M23, which are monitor lights in the same optical path, are superimposed.

  The optical signal output from the optical switch group 440 is input to the monitor light extraction unit 450, and the wavelength demultiplexer 451 causes the monitor light M11 and the crosstalk components XT_m12, XT_m13, XT_m21, XT_m22, XT_m23, and the optical multiplex signal S1123. And XT_12, XT_13, XT_21, XT_22, and XT_23. The monitor light M11 and the crosstalk components XT_m12, XT_m13, XT_m21, XT_m22, and XT_m23 are output to an optical path for monitor light, and the optical multiplexed signal S1123 and the crosstalk components XT_12, XT_13, XT_21, XT_22, and XT_23 are output to an output path.

  The monitor light output to the monitor light optical path is input to an arrayed-waveguide grating (AWG) -type wavelength multiplexer / demultiplexer, which is a monitor light demultiplexer 462, and is provided for each optical frequency (wavelength). Output from another output port. The monitor light output from the monitor light splitter 462-2-3 is input to each of the light receivers 463-2-3-1 to 463-2-3-6 and is converted into a current value according to the light intensity. You. Information on the current value obtained in each of the light receivers 463-2-3-1 to 463-2-3-6 is sent to the signal processing device 501. The signal processing device 501 determines the amount of crosstalk from the difference in the intensity of each monitor light.

  At this time, since the same processing is performed on the other path and the other optical path, the crosstalk amount for each path and each optical path in the optical switch group 440 is determined. Since the optical frequency of the monitor light is different for each optical path, it is necessary to estimate the crosstalk component even when, for example, the used frequency band of the optical multiplexed signal S1123 and the optical multiplexed signal based on the crosstalk component XT_21 are the same. Is possible.

  Furthermore, when the crosstalk amount of the optical path through which the optical multiplexed signal S1123 passes in the optical switch group 440 is large, the signal processing device 501 compares the crosstalk amount of each optical path and switches to a path with lower crosstalk, It is possible to switch the output optical path to another optical path in the same direction. With these operations, it is possible to select an optical path that is less affected by crosstalk in the optical switch group 440, reduce the total crosstalk amount between the transmitting and receiving ends, and improve the signal quality.

[Example 1 (specific numerical values, etc.)]
In the present embodiment, as shown in FIG. 4, the optical node 401 has a configuration in which the input and the output are each two routes, and one 3-core MCF is used for each route. The three cores of the MCF are C1, C2, and C3, and the core C1 corresponds to the optical path 1, the core C2 corresponds to the optical path 2, and the core C3 corresponds to the optical path 3.

  Further, as the optical switches 443 and 445 in the optical switch group 440, wavelength selective switches (WSS) were used. A WDM (wavelength division multiplexing) coupler was used as the wavelength multiplexer 431 of the monitor light providing unit 430 and the wavelength demultiplexer 451 of the monitor light extraction unit 450, and a single wavelength laser light source was used as the monitor light source 421. An array waveguide diffraction grating (AWG) type wavelength multiplexer / demultiplexer was used as the monitor light splitter 462 of the monitor light receiver 460, and a photodiode for optical communication was used as the light receiver 463.

  Further, in the present embodiment, the band of the optical multiplex signal to be used is the C band (191.55 THz to 195.95 THz). Then, as the main signal 1, an optical multiplexed signal obtained by multiplexing two wavelengths of 192.0 THz and 192.1 THz into the input path 2 optical path 1 is input and output to the output path 1 optical path 2. . Further, as the main signal 2, an optical multiplexed signal obtained by multiplexing two wavelengths of 192.0 THz and 192.1 THz into the input path 1 optical path 1 is input and output to the output path 2 optical path 3. .

  In addition, an optical multiplexed signal obtained by multiplexing two wavelengths of 192.1 THz and 192.2 THz into the input path 2 and the optical path 2 is input as the crosstalk light, and is set so as to be output to the output path 1 and the optical path 3. In addition, the light of the L band (191.55 THz to 184.50 THz) was used as the monitor light, and the optical frequency and output value of the monitor light output from each monitor light source 421 were as shown in Table 1 below.

  In this embodiment, the threshold value of the crosstalk for switching the signal light path is set to -20 dB.

  Using the configuration of FIG. 4 and the above-described signal light / monitor light setting, each monitor light is input from each monitor light source 421 to each optical path of each input path, and the monitor light receiving unit 460 receives the monitor light. Crosstalk was detected. For example, the signals received by the monitor light receiving unit 461-1-2 of the monitor light receiving unit 460 are as follows.

  Since the crosstalk is expressed by an output difference between the main signal and the crosstalk signal, the signal reception result is processed by the signal processing device 501, and is input from the input path 2 optical path 1 and output to the output path 1 optical path 2. The crosstalk from each optical path to the main signal 1 is as shown in Table 3 below.

  Here, since the crosstalk amount from the input path 2 optical path 2 exceeds the threshold value of −20 dB, a control signal is output from the signal processing device 501 and the main signal 1 input from the input path 2 optical path 1 is output. The WSS inside the optical switch group 440 was controlled so that the output destination was changed from the output path 1 optical path 2 to the output path 1 optical path 1. Thereafter, when the crosstalk amount was observed again, the crosstalk amount from the input path 2 and the optical path 2 was -20.7 dB. Therefore, the optical path can be switched according to the crosstalk generated inside the node.

[Optional configuration]
In the above embodiment, the configuration of the optical path used for input and output is (1) one single mode fiber (SMF), (2) a plurality of SMFs, and (3) a multi-core fiber (MCF: Multi-core fiber). -core fiber), (4) a plurality of MCFs, (5) a plurality of SMFs and a single MCF, and any combination of the above configurations (1) to (4).

The number of input / output paths and the number of optical paths per path may be any numbers.
When the MCF is used, the one corresponding to the optical path is one core.
In the above-described embodiment, the wavelength band used may be other than the C band. The monitor light band may be other than the L band.
Further, in order to monitor the crosstalk (XT) of all optical paths, monitor light for all optical paths having different optical frequencies is required.
The monitor light transmitting section 420 and the monitor light providing section 430 and the monitor light extracting section 450 and the monitor light receiving section 460 may have the following configurations.

[Configuration of Monitor Light Transmitting Unit 420 and Monitor Light Giving Unit 430]
The configurations of the monitor light transmitting unit 420 and the monitor light giving unit 430 according to the present embodiment will be described with reference to FIGS. 5 to 10 show a configuration for monitoring all optical paths, and FIG. 11 shows a configuration for monitoring partial optical paths. 5 to 11, the related functional units are extracted and shown, and optical amplifiers and the like before and after the OXC are omitted. FIGS. 5 to 10 extract and show the configuration relating to the input path 1 having three optical paths.

FIG. 5 is a diagram illustrating a configuration example of the monitor light transmitting unit 420 and the monitor light providing unit 430 according to the present embodiment. In the figure, single wavelength light sources having different optical frequencies λ 1,..., Λ 3 are used as the monitor light sources 4211-1 to 4211-3 of the monitor light transmission unit 420, and WDM is used as the wavelength multiplexer 431 of the monitor light providing unit 430. The couplers 4311-1 to 4311-3 are used. In this configuration, the monitor light sources 4211-1 to 4211-3, which are single wavelength light sources, are arranged for each optical frequency of the monitor light, and the optical frequencies λ1,..., Λ3 output from the respective monitor light sources 4211-1 to 4211-3. Are input to the WDM couplers 4311-1 to 4311-3 via the monitor optical paths, and are input to the optical paths 1 to 3, respectively. In this configuration, monitoring is performed using the optical frequencies λ1 to λ3.
The monitor light transmitting section 420 and the monitor light giving section 430 may have the following configurations.

  FIG. 6 is a diagram illustrating a configuration example of the monitor light transmitting unit 420 and the monitor light providing unit 430 when a multi-wavelength light source is used as the monitor light source. In the figure, a multi-wavelength light source is used as the monitor light source 4221 of the monitor light transmission unit 420. Further, the monitor light transmitter 420 uses an arrayed waveguide diffraction grating (AWG) type wavelength multiplexer / demultiplexer 4222 as a wavelength demultiplexer. The monitor light of the optical frequencies λ1 to λ3 output from the monitor light source 4221 is input to the AWG 4222, and the monitor light having a different wavelength is output for each output port. , Λ3 output from the AWG 4222 are input to the WDM couplers 4311-1 to 4311-3 via the monitor optical paths, and are input to the respective optical paths. In this configuration, monitoring is performed using the optical frequencies λ1 to λ3.

  FIG. 7 is a diagram illustrating another configuration example of the monitor light transmitting unit 420 and the monitor light providing unit 430 when a multi-wavelength light source is used as the monitor light source. In the figure, a multi-wavelength light source is used as the monitor light source 4231 of the monitor light transmission unit 420. Further, the monitor light transmitting section 420 uses an optical coupler 4232 and wavelength filters 4233-1 to 4233-3 as wavelength demultiplexers. The monitor light of the optical frequencies λ1 to λ3 output from the monitor light source 4231 which is a multi-wavelength light source is branched by the optical coupler 4232 and output to the wavelength filters 4233-1 to 4233-3 arranged in each optical path. The wavelength filters 4233-1 to 4233-3 pass the optical frequencies λ1, λ2, and λ3, respectively. Thereby, monitor light of different optical frequencies λ1,..., Λ3 is input for each monitor optical path. , Λ3 are input to the WDM couplers 4311-1 to 4311-3 via the respective monitor optical paths, and are input to the respective optical paths. In this configuration, monitoring is performed using λ1 to λ3.

  FIG. 8 is a diagram illustrating a configuration example of the monitor light transmitting unit 420 and the monitor light providing unit 430 when monitoring is performed by the TDM (time division multiplexing) method. In the figure, a single wavelength light source is used as the monitor light source 4241 of the monitor light transmission unit 420. Further, the monitor light transmitting section 420 uses a TDM switch (SW) 4242 as an element for branching monitor light to each monitor light path.

  The monitor light of the optical frequency λ1 output from the monitor light source 4241 which is a single wavelength light source is input to the TDM switch 4242. In the TDM switch 4242, the output destination port switches every unit time. Each output port is connected to each monitor light path, and the monitor light path through which the monitor light passes differs every unit time. The monitor light input to each monitor optical path is input to the WDM couplers 4311-1 to 4311-3 via the monitor optical path, and is input to each optical path.

  For example, the TDM switch 4242 connected to three monitor optical paths uses a counter having a period of 3T. The TDM switch 4242 determines the monitor optical paths 1 to 3 according to whether the remainder obtained by dividing the counter value by 3T is 0 or more and less than T, T or more and less than 2T, and 2T or more and less than 3T. In this configuration, monitoring is performed using one optical frequency λ1.

  FIG. 9 is a diagram illustrating another configuration example of the monitor light transmitting unit 420 and the monitor light giving unit 430 when monitoring is performed by the TDM method. In the figure, a single wavelength light source is used as the monitor light source 4251 of the monitor light transmission unit 420. Further, the monitor light transmitting section 420 uses an optical coupler 4252 as an element that branches to each monitor light path. The monitor light of the optical frequency λ1 output from the monitor light source 4251 which is a single wavelength light source is branched by the optical coupler 4252 and input to each monitor optical path. In each monitor optical path, there are shutters 4253-1 to 4253-3 that are opened and closed every unit time. The time control element 4254 controls the opening / closing timing of the shutters 4253-1 to 4253-3, so that the monitor light path through which the monitor light passes is different for each unit time. The monitor light input to the monitor optical path is input to the WDM couplers 4311-1 to 4311-3 through each monitor optical path, and is input to each optical path. In this configuration, monitoring is performed using one optical frequency λ1.

  FIG. 10 is a diagram illustrating a configuration example of the monitor light transmitting unit 420 and the monitor light providing unit 430 when monitoring is performed using monitor light with a superimposed tone. In the figure, a single wavelength light source is used as the monitor light source 4261 of the monitor light transmission unit 420. Further, the monitor light transmission section 420 uses an optical coupler 4262 as an element that branches to each monitor light path. The monitor light of the optical frequency λ1 output from the monitor light source 4261 which is a single wavelength light source is branched by the optical coupler 4262 and input to each monitor optical path. Each monitor optical path has a modulator 4263-1 to 4263-3. Each of the modulators 4263-1 to 4263-3 of each optical path superimposes a different tone signal for each optical path generated by the signal generator 4264. The monitor lights on which the tone signals are superimposed by the modulators 4263-1 to 4263-3 are input to the WDM couplers 4311-1 to 4311-3 through the respective monitor optical paths, and are input to the respective optical paths. In this case, monitoring is performed using only one optical frequency λ1.

  FIG. 11 is a diagram illustrating a configuration example of the monitor light transmitting unit 420 and the monitor light providing unit 430 when the monitor light is input only to a part of the optical path. In this configuration, in the configurations of FIGS. 5 to 10, the input optical path for multiplexing the monitor light is not an entire optical path but a partial optical path. Also, the number of optical paths in each path may be an arbitrary number. For example, a configuration in which the number of optical paths per path is three and the number of optical paths for multiplexing the monitor light is one, or the number of optical paths per path is five and the optical path for multiplexing the monitor light is , The number of optical paths per path is two, and the number of optical paths for multiplexing the monitor light is two. The monitor light providing section 430 includes a WDM coupler 4311 on an optical path for multiplexing the monitor light. The monitor light source 4271 outputs monitor light according to any of the configurations shown in FIGS. 5 to 10, and the WDM coupler 4311 inputs the monitor light output from the monitor light source 4271 to the optical path.

[Configuration of Monitor Light Extractor 450 and Monitor Light Receiver 460]
The configurations of the monitor light extraction unit 450 and the monitor light reception unit 460 according to the present embodiment will be described with reference to FIGS. FIGS. 12 to 15 show a configuration for monitoring all optical paths. 12 to 15, the relevant functional units are extracted and shown, and optical amplifiers and the like before and after the OXC are omitted. 12 to 15, the configuration relating to the output path 1 having three optical paths is extracted and shown.

FIG. 12 is a diagram illustrating a configuration example of the monitor light extraction unit 450 and the monitor light reception unit 460 according to the present embodiment. FIG. 7 shows an example in which the number of monitor lights to be monitored is three, and WDM couplers 4511-1 to 4511-3 are used as the wavelength demultiplexers 451 on each optical path of the output path 1. The monitor light receiving units 4611-1 to 4611-3 of the monitor light receiving unit 460 use AWG as the monitor light splitter 4612, and use PDs (photodiodes) as the light receiving units 4613-1 to 4613-3. Monitor lights of the optical frequencies λ1 to λ3 extracted from the respective optical paths using the WDM couplers 4511-1 to 4511-3 are input to monitor light receiving units 4611-1 to 4611-3, respectively. In each of the monitor light receiving units 4611-1 to 4611-3, by using the monitor light demultiplexer 4612, monitor light is supplied to the light receiving units 4613-1 to 4613-3 for each wavelength of the optical frequencies λ1,. Will be entered. In this configuration, monitoring is performed using λ1 to λ3.
Note that the monitor light extraction unit 450 and the monitor light reception unit 460 may have the following configurations.

  FIG. 13 is a diagram illustrating a configuration example of the monitor light extraction unit 450 and the monitor light reception unit 460 when the monitor light is split by the optical coupler and the wavelength filter. FIG. 3 shows an example in which the number of monitor lights to be monitored is three. The monitor light receiving units 4621-1 to 4621-3 of the monitor light receiving unit 460 use the optical coupler 4622 and the wavelength filters 4623-1 to 4623-3 as the monitor light splitter 462, and the monitor light shown in FIG. This is a configuration for realizing the function of the AWG as the duplexer 4612. Monitor lights of the optical frequencies λ1 to λ3 extracted from the respective optical paths using the WDM couplers 4511-1 to 4511-3 are input to monitor light receiving units 4621-1 to 4621-3. In each of the monitor light receiving units 4621-1 to 4621-3, the monitor light is branched into three by the optical coupler 4622 and then input to the wavelength filters 4623-1 to 4623-3. The wavelength filters 4623-1 to 4623-3 pass monitor light of the optical frequencies λ1,..., Λ3, respectively. As a result, the monitor light is input to the light receiving units 4624-1 to 4624-3 for the wavelengths of the optical frequencies λ1,..., Λ3. In this configuration, monitoring is performed using λ1 to λ3.

  FIG. 14 is a diagram illustrating a configuration example of the monitor light extraction unit 450 and the monitor light reception unit 460 when the monitor light is split by the wavelength variable filter. The monitor light receiving section 460 shown in the figure is an example in which there are three monitor lights to be monitored, and has a configuration in which wavelength tunable filters 4631-1 to 4631-3 are used as the monitor light splitter 462. Arbitrary monitor lights of the optical frequencies λ1 to λ3 extracted from the respective optical paths using the WDM couplers 4511-1 to 4511-3 are input to the wavelength tunable filters 4631-1 to 4631-3, respectively. At this time, the wavelength tunable filters 4631-1 to 4631-3 are controlled by the time control element 4632, so that monitor lights of different optical frequencies λ 1,... Is input to Since only one monitor light is always input to any of the light receiving units 4633-1 to 4633-3, the monitor light M11 of the optical frequency λ1 is applied to all the light receiving units 4633-1 to 4633-3 in a certain period 0 to T. The monitor light M12 of the optical frequency λ2 is measured by all the light receiving units 4633-1 to 4633-3 in the next fixed period T to 2T, and the monitor light M13 of the optical frequency λ3 is measured in the next fixed period 2T to 3T. Can be measured by all the light receiving units 4633-1 to 4633-3. In this configuration, monitoring is performed using λ1 to λ3.

  FIG. 15 is a diagram illustrating a configuration example of the monitor light extraction unit 450 and the monitor light reception unit 460 when the monitor light is split by the TDM switch. In the figure, a TDM switch (SW) 4641 is used as the monitor light splitter 462 of the monitor light receiving unit 460. All monitor lights of the optical frequency λ1 extracted from each optical path using the WDM couplers 4511-1 to 4511-3 are input to the TDM switch 4641. By the TDM switch 4641, monitor light of the optical frequency λ1 from different monitor optical paths is input to the light receiving unit 4642 for each unit time. For this reason, the amount of crosstalk is determined using the operation method as shown in FIG.

  FIG. 16 is a diagram showing a monitor time chart. The switching period is T, and the monitoring targets are the monitor optical paths 1 to 3. The monitor optical paths 1 to 3 are monitor optical paths from which the WDM couplers 4511-1 to 4511-3 output monitor light, respectively. The monitor light transmitting unit 420 and the monitor light giving unit 430 input the monitor light to the optical path 1 until 3T elapses from a certain time t1, and then input the monitor light to the optical path 2 until 3T elapses from the time t1 + 3T. I do. On the other hand, the monitor light receiving unit 460 switches the optical path for extracting the monitor light to the optical paths 1, 2, and 3 every time T elapses from time t1.

  FIG. 17 is a diagram illustrating a configuration example of the monitor light extraction unit 450 and the monitor light reception unit 460 when receiving monitor light using an optical spectrum analyzer (OSA). This figure shows an example in which the number of monitor lights to be monitored is three, in which OSA 4653-1, 4653-2, and 4653-3 are used as the monitor light receiving unit 460. Arbitrary monitor lights of the optical frequencies λ1 to λ3 extracted from the respective optical paths using the WDM couplers 4511-1 to 4511-3 are input to the OSAs 4653-1 to 4653-3, respectively. The OSA 4653-1 to 4653-3 each determine the amount of crosstalk by measuring the output peak value of each optical frequency.

(Second embodiment)
[Overall structure explanation]
FIG. 18 is a configuration diagram of the large-capacity optical transmission system 12 according to the present embodiment, in which only components related to the present embodiment are extracted and shown. In the figure, the same parts as those of the large-capacity optical transmission system 11 according to the first embodiment shown in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. The large-capacity optical transmission system 12 includes a transmitting device 102, an optical node 402a, an optical node 402b, a receiving device 300, and optical transmission lines 211 to 217. The transmission device 102 and the optical node 402a are connected by the optical transmission line 211. The optical node 402a and the optical node 402b are connected by an optical transmission line 213. The optical node 402b and the receiving device 300 are connected by an optical transmission line 216. The other optical transmission lines 212, 214, 215, and 217 connected to the optical nodes 402a and 402b are connected to other optical nodes.

The transmission device 102 includes a signal generation unit 110 and a monitor light giving unit 130. The monitor light is provided to the optical multiplexed signal generated by the signal generator 110 in the monitor light providing unit 130, and is output to the optical transmission line 211.
The receiving device 300 includes a signal receiving unit 310. The optical multiplex signal transmitted by the optical transmission line 216 is received by the signal receiving unit 310.

  The optical node 402a and the optical node 402b have the same configuration. When the optical node 402a and the optical node 402b are not distinguished, they are described as an optical node 402. The optical node 402 includes an optical switch group 440 and a monitor light extraction unit 450. In the present embodiment, the optical switch group 440 and the monitor light extraction unit 450 are collectively referred to as an optical cross connect (OXC) switch. In the OXC switch, the optical switch group 440 and the monitor light extraction unit 450 are connected. In the OXC switch, the input path is connected to the optical switch group 440, and the output path is connected to the monitor light extraction unit 450.

[Detailed explanation of each part]
The components of the main part in the configuration of the large-capacity optical transmission system 12 shown in FIG. 18 will be described.

  FIG. 19 is a diagram illustrating a device configuration near the optical node 402 and the transmission device 102. In FIG. 2, only the configuration related to the present embodiment is extracted and shown, and the amplification function and the like before and after the optical cross connect (OXC) switch are omitted. In the same figure, the same parts as those of the optical node 401 according to the first embodiment shown in FIG. 4 are denoted by the same reference numerals, and description thereof will be omitted.

  There are two or more optical transmission paths to and from the optical node 402, and each path includes one or more optical paths. Further, the inside of the optical node 402 does not include the monitor light transmitting unit 420 and the monitor light giving unit 430 of the optical node 401 in the first embodiment, and the configuration and function of other units of the optical node 402 are the first. This is the same as the optical node 401 of the embodiment. In the present embodiment, each wavelength demultiplexer 451 is configured such that the monitor light is output to both the monitor light optical path and the output optical path. Specifically, each optical node 402 may extract a different monitor light, or each optical node 402 may extract a part of a common monitor light.

  The transmitting device 102 includes a signal generating unit 110, a monitor light transmitting unit 120, and a monitor light giving unit 130. The signal generator 110 has a plurality of transmitters 111. The transmitter 111 generates and outputs an optical multiplex signal. The monitor light transmitting section 120 has a plurality of monitor light sources 121, and the monitor light giving section 130 has a plurality of wavelength multiplexers 131. The configurations and functions of the monitor light transmitting unit 120 and the monitor light providing unit 130 are the same as those of the monitor light transmitting unit 420 and the monitor light providing unit 430 included in the optical node 401 according to the first embodiment. That is, the function of the monitor light source 121 is the same as that of the monitor light source 421 of the first embodiment, and the function of the wavelength multiplexer 131 is the same as that of the wavelength multiplexer 431 of the first embodiment.

  Hereinafter, the two transmitting devices 102 will be referred to as transmitting devices 102-1 and 102-2, respectively. The j-th transmitter 111 included in the transmission device 102-i is referred to as a transmitter 111-ij, and the j-th monitor light source 121 included in the transmission device 102-i is referred to as a monitor light source 121-ij. And the j-th wavelength multiplexer 131 included in the transmitting apparatus 102-i is described as a wavelength multiplexer 131-ij.

[Description of monitor method]
In the monitoring method according to the present embodiment, since the monitor light transmitting unit 120 and the monitor light giving unit 130 are not inside the optical node 402 but in the transmitting device 102, the transmitting device 102 gives the monitor light.

  The wavelength multiplexer 131-ij of the transmitting device 102-i applies the monitor light output from the monitor light source 121-ij to each of the optical multiplexed signals output from the transmitter 111-ij. That is, in the transmitting apparatus 102-1, the wavelength multiplexers 131-1-1 to 131-1-3 monitor the optical multiplexed signals output from the transmitters 111-1-1 to 111-1-3, respectively. Monitor light output from each of the light sources 121-1-1 to 121-1-3 is provided. Similarly, in the transmitting apparatus 102-2, the wavelength multiplexers 131-2-1 to 131-2-3 respectively apply the optical multiplexed signals output from the transmitters 111-2-1 to 111-2-3 to the optical multiplexed signals. The monitor light output from each of the monitor light sources 121-2-1 to 121-2-3 is provided. Thereby, the optical multiplexed signal to which the monitor light is added is input to the optical node 402. Specifically, the optical multiplexed signal from the transmitter 111-ij, to which the monitor light from the monitor light source 121-ij is added by the wavelength multiplexer 131-ij of the transmitter 102-i, The light is transmitted by the optical path j of the input path i and is input to the optical switch group 440 of the optical node 402. The monitor light receiving method by the monitor light extractor 450 and the monitor light receiver 460 is the same as in the first embodiment.

[Example 2]
In this embodiment, as shown in FIG. 19, the optical node 402 has two routes, and has a configuration using three SMFs per route. The cores of the three SMFs are C1, C2, and C3, respectively. The core C1 corresponds to the optical path 1, the core C2 corresponds to the optical path 2, and the core C3 corresponds to the optical path 3. Further, regarding the monitor light transmitting unit 120, the monitor light giving unit 130, the optical switch group 440, the monitor light extracting unit 450, and the monitor light receiving unit 460, the monitor light transmitting unit 420 and the monitor light transmitting unit 420 in Example 1 of the first embodiment are used. The configuration is the same as that of the light giving unit 430, the optical switch group 440, the monitor light extracting unit 450, and the monitor light receiving unit 460. Further, the optical frequency and output value of the optical multiplexed signal / monitor light to be used, and the threshold value of the crosstalk for switching the signal light path were the same as those in Example 1 of the first embodiment.

[Optional configuration]
In the above-described second embodiment, the configuration of the optical path used for input and output includes (1) one SMF, (2) a plurality of SMFs, (3) one MCF, (4) a plurality of MCFs, (5) Any combination of the configurations of (1) to (4), such as a plurality of SMFs and one MCF.
The number of input / output paths and the number of optical paths per path may be any numbers.
When the MCF is used, the one corresponding to the optical path is one core.
In the second embodiment, the wavelength band to be used may be other than the C band. Also, the monitor light band may be other than the L band.

The monitor light transmitting unit 120 and the monitor light providing unit 130, and the monitor light extracting unit 450 and the monitor light receiving unit 460 may have the following configurations.
That is, the monitor light transmitting unit 120 and the monitor light providing unit 130 may have the same configurations as the following (1) to (6) in the first embodiment.

(1) A configuration in which a multi-wavelength light source is used as a monitor light source and the wavelength is split by a wavelength splitter (FIG. 6).
(2) A configuration in which a multi-wavelength light source is used as a monitor light source and the light is split by an optical coupler and a wavelength filter (FIG. 7).
(3) A configuration in which monitoring is performed in a TDM system using a TDM switch (FIG. 8).
(4) A configuration in which monitoring is performed by a TDM method using a time control element (FIG. 9),
(5) Configuration for monitoring with monitor light on which a tone is superimposed (FIG. 10)
(6) A configuration in which monitor light is input only to a part of the optical path (FIG. 11).

  Further, the monitor light extraction unit 450 and the monitor light reception unit 460 may have the same configuration as the following (1) to (3) in the first embodiment.

(1) A configuration in which monitor light is split by a monitor light splitter (FIG. 12);
(2) A configuration in which monitor light is split by an optical coupler and a wavelength filter (FIG. 13).
(3) A configuration in which monitor light is split by a wavelength variable filter (FIG. 14).

(Third embodiment)
[Overall structure explanation]
FIG. 20 is a configuration diagram of the large-capacity optical transmission system 13 according to the present embodiment, and only components related to the present embodiment are extracted and shown. In the figure, the same parts as those of the large-capacity optical transmission system 11 according to the first embodiment shown in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. The large-capacity optical transmission system 13 includes the transmitting device 100, an optical node 403a, an optical node 403b, a receiving device 303, and optical transmission lines 211 to 217. The transmission device 100 and the optical node 403a are connected by the optical transmission line 211. The optical node 403a and the optical node 403b are connected by an optical transmission line 213. The optical node 403b and the receiving device 303 are connected by an optical transmission line 216. The optical node 403a and the optical node 403b have the same configuration. When the optical node 403a and the optical node 403b are not distinguished, they are described as an optical node 403. The large-capacity optical transmission system 13 has a configuration in which the monitor light extraction unit 450 in the optical node 401 of the first embodiment is eliminated, and the monitor light extraction unit 320 is added to the reception device 303. The configuration of each unit other than the above is the same as that of the first embodiment.

[Detailed explanation of each part]
The components of the main part in the configuration of the large capacity optical transmission system 13 shown in FIG. 20 will be described.

  FIG. 21 is a diagram illustrating the device configuration near the optical node 403 and the receiving device 303. In FIG. 2, only the configuration related to the present embodiment is extracted and shown, and the amplification function and the like before and after the optical cross connect (OXC) switch are omitted. In the same figure, the same parts as those of the optical node 401 according to the first embodiment shown in FIG. 4 are denoted by the same reference numerals, and description thereof will be omitted.

  There are two or more optical transmission paths to and from the optical node 403, and each path includes one or more optical paths. Further, the inside of the optical node 403 does not include the monitor light extraction unit 450 and the monitor light reception unit 460 of the optical node 401 in the first embodiment, and the configuration and function of each unit are the same as those of the optical node of the first embodiment. Same as 401. That is, the monitor light transmitting unit 420, the monitor light providing unit 430, and the optical switch group 440 of the optical node 403 are provided with the monitor light transmitting unit 420, the monitor light providing unit 430, and the optical switch group 440 of the optical node 401 shown in FIG. It has a similar configuration.

  The receiving device 303 includes a signal receiving unit 310, a monitor light extracting unit 320, and a monitor light receiving unit 330. The signal receiving section 310 has a plurality of receivers 311. The receiver 311 receives the transmitted optical multiplex signal. The monitor light extraction unit 320 has a plurality of wavelength demultiplexers 321. The configuration and function of the monitor light extraction unit 320 are the same as those of the monitor light extraction unit 450 of the first embodiment. That is, the function of the wavelength demultiplexer 321 is the same as that of the wavelength demultiplexer 451 in the first embodiment. The monitor light receiving section 330 has a plurality of monitor light receiving units 331. The monitor light receiving unit 331 has a monitor light splitter 332 that is a wavelength splitter, and a plurality of light receivers 333 that receive the monitor light split by the monitor light splitter 332. The configuration of the monitor light receiving unit 331 is the same as that of the monitor light receiving unit 461 in the first embodiment. The configuration and function of the monitor light receiving section 330 are the same as those of the monitor light receiving section 460 of the first embodiment. That is, the functions of the monitor light splitter 332 and the light receiver 333 are the same as those of the monitor light splitter 462 and the light receiver 463 of the first embodiment.

  Hereinafter, the two receiving devices 303 will be described as receiving devices 303-1 and 303-2, respectively. The j-th receiver 311 included in the receiving device 303-i is referred to as a receiver 311-ij, and the j-th wavelength demultiplexer 321 included in the receiving device 303-i is referred to as a wavelength demultiplexer 321. −ij, and the j-th monitor light receiving unit 331 included in the receiving device 303-i is referred to as a monitor light receiving unit 331-ij. The monitor light splitter 332 included in the monitor light receiving unit 331-ij is replaced with the monitor light splitter 332-ij, and the six light receivers 333 included in the monitor light receiving unit 331-ij are replaced with the light receiver 333. ij-1 to 333-ij-6.

[Description of monitor method]
In the monitoring method according to the present embodiment, since the monitor light extraction unit 320 and the monitor light reception unit 330 are not inside the optical node 402 but in the reception device 303, the reception device 303 extracts and receives the monitor light.

  The monitoring light transmitting unit 420 and the monitoring light giving unit 430 of the optical node 403 perform the same method as in the first embodiment. The monitor light and the optical multiplexed signal input to the receiving device 303 are split into the monitor light and the optical multiplexed signal by the wavelength demultiplexer 321. Subsequent monitor light reception methods in the monitor light extraction unit 320 and the monitor light reception unit 330 of the reception device 303 are the same as those in the first embodiment. That is, the optical multiplexed signal output from the optical switch group 440 of the optical node 403 to the output path i optical path j is split into the monitor light and the optical multiplexed signal by the wavelength demultiplexer 321-ij of the receiving device 303-i. You. The monitor light branched from the wavelength demultiplexer 321-ij is input to the monitor light receiving unit 331-ij, and the optical multiplex signal is input to the receiver 311-ij. The monitor light demultiplexer 332-ij of the receiver 311-ij divides the input monitor light for each optical frequency and receives the photodetectors 333-ij-1 to 333-ij-6. To enter. The light receivers 333-ij-1 to 333-ij-6 convert the light intensity of the monitor light into a current value and transmit information on the current value to the signal processing device 501. The signal processing device 501 determines the amount of crosstalk from the difference in the intensity of each monitor light.

[Example 3]
In the present embodiment, as shown in FIG. 21, the optical node 403 has two routes, and has a configuration using three SMFs per route. The cores of the three SMFs are C1, C2, and C3, respectively. The core C1 corresponds to the optical path 1, the core C2 corresponds to the optical path 2, and the core C3 corresponds to the optical path 3. Further, regarding the monitor light transmitting unit 420, the monitor light giving unit 430, the optical switch group 440, the monitor light extracting unit 320, and the monitor light receiving unit 330, the monitor light transmitting unit 420 in Example 1 of the first embodiment, The configuration is the same as that of the monitor light giving section 430, the optical switch group 440, the monitor light extracting section 450, and the monitor light receiving section 460. Further, the optical frequency and output value of the optical multiplexed signal / monitor light to be used, and the threshold value of the crosstalk for switching the signal optical path were the same as those in Example 1 of the first embodiment.

[Optional configuration]
In the above-described third embodiment, the configuration of the optical path used for input and output includes (1) one SMF, (2) a plurality of SMFs, (3) one MCF, (4) a plurality of MCFs, (5) Any combination of the configurations (1) to (4), such as a plurality of SMFs and one MCF, may be used.
The number of input / output paths and the number of optical paths per path may be any numbers.
When the MCF is used, the one corresponding to the optical path is one core.
In the third embodiment, the wavelength band to be used may be other than the C band. Also, the monitor light band may be other than the L band.

The monitor light transmitting unit 420 and the monitor light providing unit 430, and the monitor light extracting unit 320 and the monitor light receiving unit 330 may have the following configurations.
That is, the monitor light transmitting unit 420 and the monitor light giving unit 430 may have the same configuration as the following (1) to (6) in the first embodiment.

(1) A configuration in which a multi-wavelength light source is used as a monitor light source and the wavelength is split by a wavelength splitter (FIG. 6).
(2) A configuration in which a multi-wavelength light source is used as a monitor light source and the light is split by an optical coupler and a wavelength filter (FIG. 7).
(3) A configuration in which monitoring is performed in a TDM system using a TDM switch (FIG. 8).
(4) A configuration in which monitoring is performed by a TDM method using a time control element (FIG. 9),
(5) Configuration for monitoring with monitor light on which a tone is superimposed (FIG. 10)
(6) A configuration in which monitor light is input only to a part of the optical path (FIG. 11).

  Further, the monitor light extraction unit 320 and the monitor light reception unit 330 may have the same configuration as the following (1) to (3) in the first embodiment.

(1) A configuration in which monitor light is split by a monitor light splitter (FIG. 12);
(2) A configuration in which monitor light is split by an optical coupler and a wavelength filter (FIG. 13).
(3) A configuration in which monitor light is split by a wavelength variable filter (FIG. 14).

(Fourth embodiment)
[Overall structure explanation]
In the present embodiment, two wavelengths of monitor light are used for one optical path.
The network configuration of the optical cross-connect system of the present embodiment is the same as that of the large-capacity optical transmission system 11 of the first embodiment. However, the optical node 404 shown in FIGS. 22 and 23 is used instead of the optical nodes 401a and 401b. In the optical node 404, a monitor light providing unit 435 and a monitor light extracting unit 455 are arranged at the input / output terminals of the optical switch group 440, instead of the monitor light providing unit 430 and the monitor light extracting unit 450 of the first embodiment. Configuration.

[Detailed explanation of each part]
The components of the main part in the optical connect system of the present embodiment will be described.
FIG. 22 and FIG. 23 are diagrams illustrating a device configuration near the optical node 404. In FIG. 2, only the configuration related to the present embodiment is extracted and shown, and the amplification function and the like before and after the optical cross connect (OXC) switch are omitted. In the figure, the same parts as those in the vicinity of the optical node 401 according to the first embodiment shown in FIG. The optical node 404 includes a monitor light transmission unit 425, a monitor light provision unit 435, an optical switch group 440, a monitor light extraction unit 455, and a monitor light reception unit 465. FIG. 22 shows a detailed configuration of the monitor light transmitting unit 425 and the monitor light giving unit 435 of the optical node 404. FIG. 23 shows a detailed configuration of the monitor light extractor 455 and the monitor light receiver 465 of the optical node 404. 1 shows the configuration.

  There are two or more optical transmission paths to and from the optical node 404, and one path includes one or more optical paths. The monitor light giving section 435 and the monitor light extraction section 455 each include two wavelength multiplexers 431 and two wavelength demultiplexers 451 for one optical path for short wavelength side monitor light and one for long wavelength side monitor light. Install them one by one. In the figure, since the number p1 of optical paths obtained by combining all the input paths is 6, the monitor light giving section 435 includes 2 × p1 = 12 wavelength multiplexers 431. A wavelength multiplexer 431-1-j for multiplexing a long wavelength monitor light on the optical path j of the input path 1 and a short wavelength monitor light on the optical path j of the input path 1 are multiplexed. The wavelength multiplexer 431 is a wavelength multiplexer 431-1- (j + 3), and the wavelength multiplexer 431 for multiplexing the short-wavelength monitor light on the optical path j of the input path 2 is a wavelength multiplexer 431-2-j. The wavelength multiplexer 431 for multiplexing the long wavelength monitor light into the optical path j of the input path 2 is referred to as a wavelength multiplexer 431-2- (j + 3). In addition, in the figure, since the number p2 of the optical paths including all the output paths is p2 = 6, the monitor light extracting unit 455 includes 2 × p2 = 12 wavelength demultiplexers 451. The wavelength demultiplexers 451 for demultiplexing the monitor light on the optical path j of the output path i are referred to as wavelength demultiplexers 451-ij and 451-i- (j + 3).

  The monitor light transmitter 425 installs two monitor light sources 421 serving as a short wavelength monitor light source and a long wavelength monitor light source for one optical path. That is, the monitor light transmission unit 425 installs 2 × the number of light paths p1 = 12 monitor light sources. A monitor light source 421 for supplying monitor light to each of the wavelength multiplexers 431-1-1 to 431-1-6 and 431-2-1 to 431-2-6 is provided with monitor light sources 421-1-1 to 421-1. 1-6, 421-2-1 to 421-2-6. The monitor light sources 421-1-1 to 421-1-3 and 421-2-1 to 421-2-3 are a long wavelength side monitor light source group for supplying a long wavelength monitor light, and the monitor light sources 421-1-4. Reference numerals 421-1-6 and 421-2-4 to 421-2-6 denote short-wavelength-side monitor light source groups for supplying short-wavelength monitor light.

The monitor light receiving section 465 includes two monitor light receiving units 461 for one optical path. That is, the monitor light receiving unit 465 installs 2 × the number of optical paths p2 = 12 monitor light receiving units 461. The monitor light receiving units 461 to which the wavelength splitters 451-1-1 to 451-1-6 and 451-2-1 to 451-2-6 receive the respective separated monitor lights are respectively provided. -1-1 to 461-1-6 and 461-2-1 to 461-2-6. The wavelength demultiplexers 451-1-1 to 451-1-3 and 451-2-1 to 451-2-3 transmit monitor light having a long wavelength to the monitor light receiving units 461-1-1 to 461-1-3, Input to 461-2-1 to 461-2-3, wavelength demultiplexers 451-1-4 to 451-1-6 and 451-2-4 to 451-2-6 monitor short wavelength monitor light. The light is received by the light receiving units 461-1-4 to 461-1-6 and 461-2-4 to 461-2-6.
Other configurations of the optical node 403 are the same as those of the optical node 401 of the first embodiment.

[Description of monitor method]
In the monitor method according to the present embodiment, since the monitor light transmitting section 425 has monitor light outputs in the short wavelength side and the long wavelength side, the monitor light providing section 435 uses the short wavelength monitor light and the long wavelength monitor. Light is provided to each optical path by a different wavelength multiplexer 431. Similarly, the wavelength splitter 451 corresponding to the monitor light on the short wavelength side and the monitor light on the long wavelength side performs demultiplexing on the monitor light extraction unit 455.
The other monitor methods are the same as in the first embodiment. That is, the same operation as in the first embodiment is performed for each of the short wavelength side and the long wavelength side.

[Example 4 (specific numerical values, etc.)]
In this example, as in Example 1 of the first embodiment, an optical node configuration using 3 SMF fibers per path in two paths was adopted. The monitor light has a band of S band (195.95 GHz to 205.30 GHz) and an L band (184.50 GHz to 191.55 GHz). The optical frequency of the monitor light output from the monitor light transmitter 425 is as shown in the following table. 4

  Other monitor methods are the same as in the first embodiment.

[Optional configuration]
The monitor light providing unit 435 and the monitor light extraction unit 455 may have the following configurations. Hereinafter, a configuration relating to the input path 1 having three optical paths is extracted and shown.

[Configuration of Monitor Light Giving Unit 435]
FIG. 24 is a diagram illustrating a configuration example of the monitor light transmitting unit 425 and the monitor light providing unit 435 according to the present embodiment. In the figure, single wavelength light sources having different optical frequencies λ1,..., Λ6 are used as the monitor light sources 426-1 to 426-6 of the monitor light transmission unit 425. In addition, WDM (wavelength division multiplexing) couplers 436-1 to 436-6 are used as the wavelength multiplexer 431 of the monitor light providing unit 435. WDM couplers 436-i and 436- (i + 3) are installed in the optical path i. The monitor light sources 426-1 to 426-3 are a long wavelength side light source group that outputs a short wavelength monitor light, and the monitor light sources 426-4 to 426-6 are a short wavelength side light source group that outputs a long wavelength monitor light. is there.

Since the optical frequency of the monitor light is divided into a short wavelength side and a long wavelength side with respect to the wavelength band, a plurality of wavelength multiplexers are arranged per optical path in the configuration shown in FIG. In addition, monitor light sources 426-1 to 426-6, which are single wavelength light sources, are arranged for each optical frequency of the monitor light. The monitor lights output from the monitor light sources 426-1 to 426-6 are input to the WDM couplers 436-1 to 436-6 via the monitor optical paths, respectively, and are input to the respective optical paths.
Further, a configuration as shown in FIG. 25 may be adopted.

  FIG. 25 is a diagram illustrating a configuration example of the monitor light transmitting unit 425 and the monitor light providing unit 435 according to the present embodiment. In the figure, monitor light of another band is input to the optical path by one wavelength multiplexer. The monitor light transmitter 425 uses single-wavelength light sources having different optical frequencies λ1,..., Λ6 as the monitor light sources 426-1 to 426-6 as in FIG. The monitor light providing unit 435 uses the WDM couplers 437-1 to 437-3 as the wavelength multiplexer 431. Monitor light output from each of the monitor light sources 426-i and 426- (i + 3) is input to the WDM coupler 437-i. The WDM coupler 437-i inputs monitor light output from each of the monitor light sources 426-i and 426- (i + 3) to the optical path i.

  Other configurations have the same functions as the following different configurations in the first embodiment.

  The monitor light providing unit 435 and the monitor light providing unit 435 have the same configuration as the following (1) to (6) in the first embodiment.

(1) A configuration in which a multi-wavelength light source is used as a monitor light source and the wavelength is split by a wavelength splitter (FIG. 6).
(2) A configuration in which a multi-wavelength light source is used as a monitor light source and the light is split by an optical coupler and a wavelength filter (FIG. 7).
(3) A configuration in which monitoring is performed in a TDM system using a TDM switch (FIG. 8).
(4) A configuration in which monitoring is performed by a TDM method using a time control element (FIG. 9),
(5) Configuration for monitoring with monitor light on which a tone is superimposed (FIG. 10)
(6) A configuration in which monitor light is input only to a part of the optical path (FIG. 11).

  Further, the monitor light extracting unit 455 and the monitor light receiving unit 465 have the same configuration as the following (1) to (3) in the first embodiment.

(1) A configuration in which monitor light is split by a monitor light splitter (FIG. 12);
(2) A configuration in which monitor light is split by an optical coupler and a wavelength filter (FIG. 13).
(3) A configuration in which monitor light is split by a wavelength variable filter (FIG. 14).
The configuration is the same as described above.

(Fifth embodiment)
[Overall structure explanation]
In the present embodiment, the output of the monitor light output from the monitor light source is adjusted based on the light intensity of the optical multiplex signal on each optical path.
The network configuration of the optical cross-connect system of the present embodiment is the same as that of the large-capacity optical transmission system 11 of the first embodiment. However, an optical node 405 shown in FIG. 26 is used instead of the optical nodes 401a and 401b. The optical node 405 has a monitor light assigning unit 435 and a monitor light extracting unit 455 at input and output ends of the optical switch group 440, respectively, similarly to the optical node 404 shown in FIGS. This is a configuration in which a measuring instrument is installed. The configuration of the monitor light extractor 455 and the monitor light receiver 465 of the optical node 405 is the same as that of the monitor light extractor 455 and the monitor light receiver 465 of the optical node 404 shown in FIG. The detailed configuration is omitted.

[Detailed explanation of each part]
The components of the main part in the optical connect system of the present embodiment will be described.
FIG. 26 is a diagram illustrating a device configuration near the optical node 405. In FIG. 2, only the configuration related to the present embodiment is extracted and shown, and the amplification function and the like before and after the optical cross connect (OXC) switch are omitted. In the figure, the same parts as those of the optical node 404 according to the fourth embodiment shown in FIG. 22 are denoted by the same reference numerals, and description thereof will be omitted. The optical node 405 includes a monitor light transmitting unit 425, a monitor light giving unit 435, an optical switch group 440, a monitor light extracting unit 455, a monitor light receiving unit 465, an optical branching unit 470, and a light intensity measuring unit 480.

There are two or more optical transmission paths to and from the optical node 405, and one path includes one or more optical paths.
The optical splitter 470 has an optical splitter 471 that splits an optical multiplex signal on each optical path. The optical splitter 471 that splits the optical multiplexed signal on the optical path j of the input path i is referred to as an optical splitter 471-ij. The light intensity measuring device 480 is provided for each optical path. The light intensity measuring device 480 that measures the light intensity of the optical multiplexed signal branched from the optical node input terminal by the optical branching device 471-ij is referred to as a light intensity measuring device 480-ij.

[Description of monitor method]
In the monitor method according to the present embodiment, in addition to the monitor method according to the fourth embodiment, the signal processing device 505 adjusts the output of the monitor light for each optical path based on the measurement result of the light intensity by the light intensity measuring device 480. Has the ability to do. The signal processing device 505 adjusts the output of the monitor light output from the monitor light source 421 in accordance with the average value of the light intensity of the optical multiplexed signal of each optical path measured by the light intensity measuring device 480, so that the light intensity is adjusted. It is possible to accurately measure the amount of crosstalk even between optical multiplexed signals having different values.

  FIG. 27 is a diagram showing an outline of the monitor light output adjustment method of the present embodiment. In the figure, a monitor light source 421a is a monitor light source 421 of a long wavelength side monitor light source group, and a monitor light source 421b is a monitor light source 421 of a short wavelength side monitor light source group. The wavelength multiplexer 431a is a wavelength multiplexer 431 for multiplexing monitor light from the monitor light source 421a, and the wavelength multiplexer 431b is a wavelength multiplexer for multiplexing monitor light from the monitor light source 421b. 431. The wavelength demultiplexer 451a is a wavelength demultiplexer 451 for demultiplexing a long wavelength monitor light, and the wavelength demultiplexer 451b is a wavelength demultiplexer 451 for demultiplexing a short wavelength monitor light. The monitor light splitter 462a is a monitor light splitter 462 for inputting the monitor light split by the wavelength splitter 451a, and the monitor light splitter 462b is split by the wavelength splitter 451b. A monitor light splitter 462 for inputting monitor light. The optical characteristic information of the optical multiplex signal measured by the light intensity measuring device 480 is transmitted to the signal processing device 505. The signal processing device 505 transmits a monitor light output control signal to each monitor light source 421 to adjust the monitor light output.

[Examples (specific numerical values, etc.)]
In this example, the configuration shown in FIG. 26 was used.
The input path of the optical node 405 is a two-way path, and a configuration using one 3-core MCF per one path is adopted. The three cores of the MCF are C1, C2, and C3, and the core C1 corresponds to the optical path 1, the core C2 corresponds to the optical path 2, and the core C3 corresponds to the optical path 3. Other configurations were the same as those of Example 4 in the fourth embodiment. In addition, one light intensity measuring device 480 was installed for each optical path at the input end of the optical node 405, and the output of the monitor light was adjusted according to the light intensity of the optical multiplexed signal. Here, the light intensity of the optical multiplexed signal input from the input path 2 optical path 1 was +0 dBm, and the light intensity of the optical multiplexed signal input from the input path 2 optical path 2 was -5 dBm.

  At this time, assuming that the outputs of the monitor light M21 and the monitor light M22 are -10 dBm, in this embodiment, the crosstalk amount is detected by the monitor light. Can not. Therefore, the signal processing device 505 resets the light intensity of the monitor light M21 to -10 dBm and the light intensity of the monitor light M22 to -15 dBm according to the light intensity difference of the optical multiplex signal. As a result, the influence of the difference in light intensity of the optical multiplex signal on the amount of crosstalk was corrected.

[Optional configuration]
Other configurations have the same functions as the other configurations of the fourth embodiment and have the following functions.

  The monitor light providing unit 435 and the monitor light providing unit 435 have the same configuration as the following (1) to (6) in the first embodiment, or the same configuration as (7) in the fourth embodiment. .

(1) A configuration in which a multi-wavelength light source is used as a monitor light source and the wavelength is split by a wavelength splitter (FIG. 6).
(2) A configuration in which a multi-wavelength light source is used as a monitor light source and the light is split by an optical coupler and a wavelength filter (FIG. 7).
(3) A configuration in which monitoring is performed in a TDM system using a TDM switch (FIG. 8).
(4) A configuration in which monitoring is performed by a TDM method using a time control element (FIG. 9),
(5) Configuration for monitoring with monitor light on which a tone is superimposed (FIG. 10)
(6) Configuration in which monitor light is input only to a part of the optical path (FIG. 11)
(7) A configuration in which monitor light of another band is input by one wavelength multiplexer (FIG. 25).

  Further, the monitor light extracting unit 455 and the monitor light receiving unit 465 have the same configuration as the following (1) to (3) in the first embodiment.

(1) A configuration in which monitor light is split by a monitor light splitter (FIG. 12);
(2) A configuration in which monitor light is split by an optical coupler and a wavelength filter (FIG. 13).
(3) A configuration in which monitor light is split by a wavelength variable filter (FIG. 14).

  In the above-described crosstalk detection, the correction of the crosstalk amount due to the light intensity difference of the optical multiplex signal is performed by the monitor light source 421 based on the average value of the light intensity of the optical multiplex signal measured by the light intensity measuring device 480. This method adjusts the light intensity of each monitor light to be output. Alternatively, the following method shown in FIG. 28 may be used.

  FIG. 28 is a diagram showing an outline of another monitor light output adjustment method. In the figure, the signal processing device 505 corrects the value of the light intensity of the monitor light received by each monitor light receiving unit 460 based on the optical characteristic information transmitted from the light intensity measuring device 480. The signal processing device 505 corrects the signal as a signal process based on the average value of the light intensity of the optical multiplexed signal measured by the light intensity measuring device 480 and the light intensity of the monitor light received by each monitor light receiving unit 460, and performs cross processing. Determine the amount of talk. Therefore, it is not necessary to adjust the light intensity of the monitor light output from the monitor light source 421.

  According to the embodiment described above, for example, an optical transmission system (for example, a large-capacity optical transmission system 11, 12, 13, or the like) is connected to two or more input routes and two or more output routes. (For example, optical nodes 401, 402, 403, 404, and 405). The input paths connected to the optical node device each have one or more input optical paths to which the optical multiplexed signal is input, and the one or more input paths have two or more input optical paths. The output path connected to the optical node device has one or more output optical paths for outputting the optical multiplexed signal, and the one or more output paths have two or more output optical paths. The optical cross-connect switch of the optical node device outputs each optical signal multiplexed to the optical multiplexed signal input through the input optical path from an output optical path arbitrarily selected. The optical cross-connect switch multiplexes an optical multiplexed signal input from an input optical path with a monitor light providing unit that provides monitor light of a band different from the wavelength band of the optical multiplexed signal, and an optical signal output from an output optical path. At least one of a monitor light extraction unit that extracts monitor light of a band different from the wavelength band of the optical multiplex signal from the optical multiplex signal.

  When the optical cross-connect switch includes at least the monitor light extraction unit, the optical node device receives the monitor light extracted by the monitor light extraction unit and a monitor light received by the monitor light reception unit. A signal processing unit (for example, signal processing devices 501 and 505) for acquiring the measured optical characteristics may be further provided. The signal processing unit estimates the optical characteristics of the optical multiplexed signal based on the measured optical characteristics, and resets the optical path from the input path to the output path in the optical cross-connect switch based on the estimation result.

  Further, when the optical cross-connect switch includes at least the monitor light providing unit, the optical node device includes an optical branch unit that branches the optical multiplexed signal transmitted by the input optical path and an optical multiplexed signal that is branched by the optical branching unit. A light intensity measuring unit for measuring the light intensity of each included optical signal. The signal processing unit corrects the optical characteristics based on the light intensity measured by the light intensity measurement unit.

  When the optical cross-connect switch includes at least the monitor light providing unit, the optical node device includes an optical branch unit that branches the optical multiplexed signal in the input optical path, and an optical branching unit that is included in the optical multiplexed signal branched by the optical branching unit. A light intensity measuring unit for measuring the light intensity of the optical signal may be further provided. In the signal processing unit, the monitor light giving unit gives the monitor light whose light intensity is set according to the average value of the light intensity measured by the light intensity measurement unit.

  Further, the optical transmission system generates an optical multiplexed signal to be input to the input optical path, and applies a monitor light in a band different from the wavelength band of the optical multiplexed signal and transmits the multiplexed signal. At least one of a receiving device that receives the optical multiplexed signal output from the optical path and branches monitor light in a band different from the wavelength band of the optical multiplexed signal from the optical multiplexed signal may be provided.

  According to the above-described embodiment, crosstalk can be monitored in a spatial multiplexing node included in a large-capacity optical transmission system in order to solve a signal deterioration factor. This monitoring makes it possible to achieve both the maintenance of signal quality and the expansion of transmission capacity in a large-capacity optical transmission system.

  At least a part of the functions of the signal processing device in the above-described embodiment may be realized by a computer. In that case, a program for realizing this function may be recorded on a computer-readable recording medium, and the program recorded on this recording medium may be read and executed by a computer system. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, and a CD-ROM, and a storage device such as a hard disk built in a computer system. Further, a “computer-readable recording medium” refers to a communication line for transmitting a program via a network such as the Internet or a communication line such as a telephone line, which dynamically holds the program for a short time. Such a program may include a program that holds a program for a certain period of time, such as a volatile memory in a computer system serving as a server or a client in that case. Further, the above-mentioned program may be for realizing a part of the above-described functions, or may be for realizing the above-mentioned functions in combination with a program already recorded in a computer system.

  As described above, the embodiments of the present invention have been described in detail with reference to the drawings. However, the specific configuration is not limited to the embodiments, and includes a design and the like within a range not departing from the gist of the present invention.

  It can be used to monitor crosstalk in optical cross-connects in optical transmission systems.

11, 12, 13 ... Large-capacity optical transmission systems 100, 102, 102-1, 102-2 ... Transmission device 110 ... Signal generation units 111-1-1 to 111-1-3, 111-2-1 to 111- 2-3 Transmitter 120 Monitor light transmitting units 121-1-1 to 121-1-3, 121-2-1 to 121-2-3 Monitor light source 130 Monitor light giving units 131-1-1 to 131-1-1 131-1-3, 131-2-1 to 131-2-3 ... wavelength multiplexers 211, 212, 213, 214, 215, 216, 217 ... optical transmission lines 300, 303, 303-1 and 303-2 ... Receiving device 310 ... Signal receiving units 311-1-1 to 311-1-3, 311-2-1 to 311-2-3 ... Receiver 320 ... Monitor light extracting units 321-1-1 to 321-1 -... 3, 321-2-1 to 321-2-3 ... wavelength splitter 33 ... Monitor light receiving units 331-1-1 to 313-1-3, 331-2-1 to 331-2-3 ... Monitor light receiving units 332-1-1, 332-2-3 ... Monitor light demultiplexers 333-1-1-1 to 333-1-1-6, 333-2-3-1 to 333-2-3-6 ... receivers 401, 401a, 401b, 402, 402a, 402b, 403, 403a, 403b, 404, 405... Optical node 410... Optical cross-connect switch sections 420 and 425... Monitor light transmission sections 421-1-421-1-6, 421-1-421-2-6. -1 to 426-6 monitor light sources 430, 435 monitor light giving sections 431-1-1 to 431-1-6, 431-2-1 to 431-2-6 wavelength combiners 436-1 to 436 -6, 437-1 to 437-3 ... DM coupler 440 ... optical switch groups 443-1-1 to 443-1-3, 443-2-1 to 443-2-3 ... optical switches 445-1-1 to 445-1-3, 445-2-1 445-2-3 optical switches 450, 455 monitor light extraction units 451-1-1 to 451-1-6, 451-2-1 to 451-2-6 wavelength demultiplexers 460, 465 monitor .. Light receiving units 461-1-1 to 461-1-6, 461-2-1 to 461-2-6... Monitor light receiving units 462-1-1, 462-2-3. 1-1-1 to 463-1-1-6, 463-2-3-1 to 463-2-3-6, 463-1-4-1 to 463-1-4-6, 463-2- 6-1 to 463-2-6-6... Light receiver 470... Optical splitters 471-1-1 to 471-1-3, 471-2. -1 to 471-2-3 ... optical splitters 480-1-1 to 480-1-3 ... 480-2-1 to 480-2-3 ... light intensity measuring devices 501 and 505 ... signal processing devices 801 and 802 , 803, 804, 805, 806, 807 optical transmission lines 910, 950 transmitters 911, 951 optical multiplexed signal generators 920a, 920b optical nodes 921a, 921b, 961a, 961b optical cross connects 930, 970 ... Receiver 931: optical multiplexed signal receivers 960a and 960b spatial multiplexing node 971 optical multiplexed signal receivers 4211-1 to 4211-3 monitor light source 4221 monitor light source 4222 arrayed waveguide grating (AWG) type wavelength combining Demultiplexer 4231 monitor light source 4232 optical couplers 4233-1 to 4233-3 wavelength filter 4241 monitor light source 4242 T M switch 4251 monitor light source 4252 optical coupler 4253-1 to 4253-3 shutter 4254 time control element 4261 monitor light source 4262 optical coupler 4263-1 to 4263-3 modulator 4264 signal generator 4271 monitor Light sources 4311, 4311-1 to 4311-3 WDM couplers 4511-1 to 4511-3 WDM couplers 4611-1 to 4611-3 Monitor light receiving unit 4612 Monitor light splitters 4613-1 to 4613-3 Light receiving units 4621-1 to 4621-3 monitor light receiving unit 4622 optical couplers 4623-1 to 4623-3 wavelength filters 4624-1 to 4624-3 light receiving units 4631-1 to 4631-3 wavelength variable filters 4632 ... Time control elements 4633-1 to 4633-3 ... Light receiving section 4641 TDM switch 4642 ... the light-receiving part 4653-1～4653-3 ... optical spectrum analyzer

Claims (15)

An optical transmission system having an optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
The optical node device,
Each optical signal multiplexed to the optical multiplexed signal input by the input optical path, an optical cross-connect switch unit that outputs from the output optical path arbitrarily selected,
The optical cross-connect switch section,
A monitor light providing unit for providing monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path, and an optical multiplex having the optical signal output from the output optical path multiplexed The signal comprises at least one of a monitor light extraction unit that extracts monitor light in a band different from the wavelength band of the optical multiplexed signal ,
The optical cross-connect switch unit includes at least the monitor light extraction unit,
The optical node device,
A monitor light receiver that receives the monitor light extracted by the monitor light extractor,
Further comprising a signal processing unit for acquiring the optical characteristics of the measured monitor light received by the monitor light receiving unit,
The signal processing unit estimates an optical characteristic of the optical multiplexed signal based on the optical characteristic, and resets an optical path from the input path to the output path in the optical cross-connect switch unit based on the estimation result. Do
An optical transmission system, characterized in that: An optical transmission system having an optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
The optical node device,
Each optical signal multiplexed to the optical multiplexed signal input by the input optical path, an optical cross-connect switch unit that outputs from the output optical path arbitrarily selected,
The optical cross-connect switch section,
A monitor light providing unit for providing monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path, and an optical multiplex having the optical signal output from the output optical path multiplexed A monitor light extracting unit that extracts monitor light of a band different from the wavelength band of the optical multiplex signal from the signal,
The optical node device,
A monitor light receiver that receives the monitor light extracted by the monitor light extractor,
A signal processing unit for acquiring an optical characteristic of the monitor light received by the monitor light receiving unit,
An optical branching unit that branches an optical multiplexed signal transmitted by the input optical path,
Further comprising a light intensity measuring unit for measuring the light intensity of each optical signal included in the optical multiplex signal branched by the optical branching section,
The signal processing unit corrects the optical characteristic based on the light intensity measured by the light intensity measurement unit,
The optical transmission system that is characterized in that. An optical transmission system having an optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
The optical node device,
Each optical signal multiplexed to the optical multiplexed signal input by the input optical path, an optical cross-connect switch unit that outputs from the output optical path arbitrarily selected,
The optical cross-connect switch section,
A monitor light providing unit for providing monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path, and an optical multiplex having the optical signal output from the output optical path multiplexed The signal comprises at least one of a monitor light extraction unit that extracts monitor light in a band different from the wavelength band of the optical multiplexed signal,
The optical cross-connect switch unit includes at least the monitor light providing unit,
The optical node device,
An optical branching unit that branches an optical multiplexed signal transmitted by the input optical path,
An optical intensity measurement unit that measures the optical intensity of each optical signal included in the optical multiplexed signal branched by the optical branching unit,
The monitor light providing unit provides monitor light whose light intensity is set according to an average value of the light intensity measured by the light intensity measurement unit,
The optical transmission system that is characterized in that. An optical transmission system having an optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
The optical node device,
Each optical signal multiplexed to the optical multiplexed signal input by the input optical path, an optical cross-connect switch unit that outputs from the output optical path arbitrarily selected,
The optical cross-connect switch section,
A monitor light providing unit for providing monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path, and an optical multiplex having the optical signal output from the output optical path multiplexed The signal comprises at least one of a monitor light extraction unit that extracts monitor light in a band different from the wavelength band of the optical multiplexed signal,
The optical transmission system,
A transmission device that generates an optical multiplexed signal to be input to the input optical path, and applies and transmits monitor light in a band different from the wavelength band of the optical multiplexed signal,
At least one of a receiving device to which a monitor light is added, the optical multiplexed signal output from the output optical path is received, and the monitor light in a band different from the wavelength band of the optical multiplexed signal is branched from the optical multiplexed signal. Comprising,
The optical transmission system that is characterized in that. An optical transmission system having an optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
The optical node device,
Each optical signal multiplexed to the optical multiplexed signal input by the input optical path, an optical cross-connect switch unit that outputs from the output optical path arbitrarily selected,
The optical cross-connect switch section,
A monitor light providing unit for providing monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path, and an optical multiplex having the optical signal output from the output optical path multiplexed The signal comprises at least one of a monitor light extraction unit that extracts monitor light in a band different from the wavelength band of the optical multiplexed signal,
The optical cross-connect switch unit includes at least the monitor light extraction unit,
The optical node device,
A monitor light receiver that receives the monitor light extracted by the monitor light extractor,
Further comprising: a signal processing unit that acquires the optical characteristics of the monitor light received by the monitor light receiving unit and obtains a crosstalk amount from each of the input optical paths based on the acquired optical characteristics.
An optical transmission system, characterized in that: An optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
Each optical signal multiplexed to the optical multiplexed signal input by the input optical path, an optical cross-connect switch unit that outputs from the output optical path arbitrarily selected,
The optical cross-connect switch section,
A monitor light providing unit for providing monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path, and an optical multiplex having the optical signal output from the output optical path multiplexed The signal comprises at least one of a monitor light extraction unit that extracts monitor light in a band different from the wavelength band of the optical multiplexed signal ,
The optical cross-connect switch unit includes at least the monitor light extraction unit,
The optical node device,
A monitor light receiver that receives the monitor light extracted by the monitor light extractor,
Further comprising a signal processing unit for acquiring the optical characteristics of the measured monitor light received by the monitor light receiving unit,
The signal processing unit estimates an optical characteristic of the optical multiplexed signal based on the optical characteristic, and resets an optical path from the input path to the output path in the optical cross-connect switch unit based on the estimation result. Do
An optical node device, comprising: An optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
Each optical signal multiplexed to the optical multiplexed signal input by the input optical path, an optical cross-connect switch unit that outputs from the output optical path arbitrarily selected,
The optical cross-connect switch section,
A monitor light providing unit for providing monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path, and an optical multiplex having the optical signal output from the output optical path multiplexed A monitor light extracting unit that extracts monitor light of a band different from the wavelength band of the optical multiplex signal from the signal,
The optical node device,
A monitor light receiver that receives the monitor light extracted by the monitor light extractor,
A signal processing unit for acquiring an optical characteristic of the monitor light received by the monitor light receiving unit,
An optical branching unit that branches an optical multiplexed signal transmitted by the input optical path,
Further comprising a light intensity measurement unit that measures the light intensity of each optical signal included in the optical multiplexed signal branched by the optical branching unit,
The signal processing unit corrects the optical characteristic based on the light intensity measured by the light intensity measurement unit,
An optical node device, comprising: An optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
Each optical signal multiplexed to the optical multiplexed signal input by the input optical path, an optical cross-connect switch unit that outputs from the output optical path arbitrarily selected,
The optical cross-connect switch section,
A monitor light providing unit for providing monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path, and an optical multiplex having the optical signal output from the output optical path multiplexed From the signal, at least one of a monitor light extraction unit that extracts monitor light in a band different from the wavelength band of the optical multiplexed signal,
The optical cross-connect switch unit includes at least the monitor light providing unit,
The optical node device,
An optical branching unit that branches an optical multiplexed signal transmitted by the input optical path,
An optical intensity measurement unit that measures the optical intensity of each optical signal included in the optical multiplexed signal branched by the optical branching unit,
The monitor light providing unit provides monitor light whose light intensity is set according to an average value of the light intensity measured by the light intensity measurement unit,
An optical node device, comprising: An optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
Each optical signal multiplexed to the optical multiplexed signal input by the input optical path, an optical cross-connect switch unit that outputs from the output optical path arbitrarily selected,
The optical cross-connect switch section,
A monitor light providing unit for providing monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path; and an optical multiplex having the optical signal output from the output optical path multiplexed. The signal comprises at least one of a monitor light extraction unit that extracts monitor light in a band different from the wavelength band of the optical multiplexed signal,
When the optical node device does not include the monitor light providing unit, the input optical path generates an optical multiplexed signal, and applies and transmits monitor light of a band different from the wavelength band of the optical multiplexed signal and transmits the optical multiplexed signal. Input the optical multiplexed signal from
When the optical node device does not include the monitor light extraction unit, the monitor light is provided by the monitor light providing unit, the optical multiplexed signal output from the output optical path receives the optical multiplexed signal, Output from the optical multiplexed signal to a receiving device that branches monitor light in a band different from the wavelength band of the optical multiplexed signal,
An optical node device, comprising: An optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
Each optical signal multiplexed to the optical multiplexed signal input by the input optical path, an optical cross-connect switch unit that outputs from the output optical path arbitrarily selected,
The optical cross-connect switch section,
A monitor light providing unit for providing monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path, and an optical multiplex having the optical signal output from the output optical path multiplexed The signal comprises at least one of a monitor light extraction unit that extracts monitor light in a band different from the wavelength band of the optical multiplexed signal,
The optical cross-connect switch unit includes at least the monitor light extraction unit,
The optical node device,
A monitor light receiver that receives the monitor light extracted by the monitor light extractor,
Further comprising: a signal processing unit that acquires the optical characteristics of the monitor light received by the monitor light receiving unit and obtains a crosstalk amount from each of the input optical paths based on the acquired optical characteristics.
An optical node device, comprising: An optical transmission method executed by an optical transmission system having an optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
The optical node device,
Each of the optical signals multiplexed to the optical multiplexed signal input by the input optical path, has an optical cross-connect switch unit to output from the output optical path arbitrarily selected,
A monitor light providing step of providing a monitor light providing unit provided in the optical cross-connect switch unit or the transmission device to apply monitor light of a band different from the wavelength band of the optical multiplexed signal to the optical multiplexed signal input from the input optical path. When,
The optical cross-connect switch unit, the optical multiplex signal which the optical signal is multiplexed output from said output optical path, and a monitor light extraction step of extracting the monitor light different band than the wavelength band of the optical multiplex signal,
The optical node device, a monitor light receiving step of receiving the monitor light extracted in the monitor light extraction step,
The optical node device, a signal processing step of obtaining the optical characteristics measured the monitor light received in the monitor light receiving step,
The optical node device estimates optical characteristics of the optical multiplexed signal based on the optical characteristics, and resets an optical path from the input route to the output route in the optical cross-connect switch unit based on the estimation result. Resetting process,
An optical transmission method comprising: An optical transmission method executed by an optical transmission system having an optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
The optical node device,
Each of the optical signals multiplexed to the optical multiplexed signal input by the input optical path has an optical cross-connect switch unit for outputting from the output optical path arbitrarily selected,
The optical cross-connect switch section, the optical multiplexed signal input from the input optical path, a monitor light providing step of providing monitor light of a band different from the wavelength band of the optical multiplexed signal,
A monitor light extracting step of extracting, from the optical multiplexed signal in which the optical signal output from the output optical path is multiplexed, the monitor light in a band different from the wavelength band of the optical multiplexed signal,
The optical node device, a monitor light receiving step of receiving the monitor light extracted in the monitor light extraction step,
The optical node device, a signal processing step of obtaining the optical characteristics measured the monitor light received in the monitor light receiving step,
An optical branching process in which the optical node device branches an optical multiplexed signal transmitted by the input optical path;
The optical node device, a light intensity measuring step of measuring the light intensity of each optical signal included in the optical multiplexed signal branched by the optical branching process,
The optical node device, a correction process of correcting the optical characteristics based on the light intensity measured in the light intensity measurement process,
An optical transmission method comprising: An optical transmission method executed by an optical transmission system having an optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
The optical node device,
Each of the optical signals multiplexed to the optical multiplexed signal input by the input optical path has an optical cross-connect switch unit for outputting from the output optical path arbitrarily selected,
The optical cross-connect switch section, the optical multiplexed signal input from the input optical path, a monitor light providing step of providing monitor light of a band different from the wavelength band of the optical multiplexed signal,
The optical cross-connect switch unit or the monitor light extraction unit included in the receiving device converts the optical multiplexed signal, in which the optical signal output from the output optical path is multiplexed, from the optical multiplexed signal to a monitor light in a band different from the wavelength band of the optical multiplexed signal A monitor light extraction process for extracting
An optical branching process in which the optical node device branches an optical multiplexed signal transmitted by the input optical path;
The optical node device has an optical intensity measuring step of measuring the optical intensity of each optical signal included in the optical multiplexed signal split by the optical splitting step,
In the monitor light providing step, providing monitor light whose light intensity is set according to an average value of the light intensity measured in the light intensity measuring step,
An optical transmission method, comprising: An optical transmission method executed by an optical transmission system having an optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
The optical node device,
Each of the optical signals multiplexed to the optical multiplexed signal input by the input optical path has an optical cross-connect switch unit for outputting from the output optical path arbitrarily selected,
A monitor light providing step of providing a monitor light providing unit provided in the optical cross-connect switch unit or the transmission device to apply monitor light of a band different from the wavelength band of the optical multiplexed signal to the optical multiplexed signal input from the input optical path. When,
The optical cross-connect switch unit or the monitor light extraction unit included in the receiving device converts the optical multiplexed signal in which the optical signal output from the output optical path is multiplexed into monitor light of a band different from the wavelength band of the optical multiplexed signal. A monitor light extraction process for extracting
A transmitting step of generating an optical multiplexed signal to be input to the input optical path, transmitting a transmission by applying and transmitting monitor light in a band different from the wavelength band of the optical multiplexed signal,
A receiving step of receiving the optical multiplex signal output from the output optical path, to which a monitor light is added, and branching the monitor light in a band different from the wavelength band of the optical multiplex signal from the optical multiplex signal; Further having at least one of
An optical transmission method, comprising: An optical transmission method executed by an optical transmission system having an optical node device connected to two or more input routes and two or more output routes,
Each of the input paths has one or more input optical paths to which an optical multiplexed signal is input, and one or more of the input paths has two or more of the input optical paths,
The output path has at least one output optical path from which an optical multiplexed signal is output, and at least one output path has at least two output optical paths,
The optical node device,
Each of the optical signals multiplexed to the optical multiplexed signal input by the input optical path, has an optical cross-connect switch unit to output from the output optical path arbitrarily selected,
A monitor light providing step in which the optical cross connect switch unit or the monitor light providing unit provided in the transmission device provides monitor light of a band different from the wavelength band of the optical multiplex signal to the optical multiplex signal input from the input optical path. When,
A monitor light extraction step of extracting, from the optical multiplexed signal in which the optical signal output from the output optical path is multiplexed, the monitor signal of a band different from the wavelength band of the optical multiplexed signal,
The optical node device, a monitor light receiving step of receiving the monitor light extracted in the monitor light extraction step,
The optical node device obtains an optical characteristic obtained by measuring the monitor light received in the monitor light receiving step, and a signal processing step of obtaining a crosstalk amount from each of the input optical paths based on the obtained optical characteristic,
An optical transmission method comprising:

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