JP2016029783A - Optical wavelength multiplexing transmission system and control method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a system capable of minimizing an effect on a wavelength path when an optical signal is inserted and the modulation speed and the modulation format of an optical signal are switched.SOLUTION: A wavelength multiplexing transmission system includes: a plurality of optical transmitter for outputting optical signals with wavelengths different to each other; optical receivers for receiving the optical signals respectively; an optical fiber transmission path for multiplexing the output optical signals to be transmitted; and a network management unit connected to the optical transmitters and the optical receivers. The optical transmitters have a test state outputting an optical signal for a test, the network management unit controls the optical transmitters so that the optical transmitters are in the test state for a predetermined period, and the optical receivers notify the signal quality of received optical signals to the network management unit.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a wavelength division multiplexing transmission system and a control method thereof.

  A wavelength division multiplex transmission system that transmits a wavelength division multiplexing (WDM) signal obtained by multiplexing a plurality of optical signals having different wavelengths on a single optical fiber has an increased traffic capacity due to the plurality of optical signals and a small optical fiber. This technology is effective in reducing the cost by the number. In an optical network, a wavelength multiplexing transmission system using this wavelength multiplexing transmission system is widely used. One of the wavelength division multiplexing transmission systems is a wavelength division multiplexing transmission system called a ROADM (Reconfigurable Optical Add / Drop Multiplexer) system.

  In the ROADM system, a wavelength selective switch (WSS) or ROADM switch that can cut out an optical signal of an arbitrary wavelength from a WDM signal and insert an optical signal of an arbitrary wavelength into the WDM signal is provided at each node of the network. At each of the nodes, only a signal of an arbitrary wavelength is dropped (dropped) from the WDM signal, or the optical signal output from the optical transmitter is inserted (added) into the WDM signal. Can do. That is, a different path can be set / switched for each optical signal constituting the WDM signal. Therefore, the ROADM system can flexibly set the wavelength path according to the expansion of the optical network and the traffic volume in each region, and realizes a ring type or mesh type network with high fault tolerance and traffic accommodation efficiency. For the purpose of doing so, it is widely used in backbone networks between cities and cities.

  As a technique for improving the wavelength utilization efficiency of the ROADM system and the flexibility of network construction, a flexible grid and a flexible optical transceiver have been proposed. The flexible grid is described in Non-Patent Document 1, for example. This is a method of individually changing the wavelength bandwidth occupied for each optical signal constituting a WDM signal with higher resolution, and a WSS corresponding to this method has already been developed. With this method, it is possible to reduce the vacant wavelength band between optical signals having continuous wavelengths, and the wavelength utilization efficiency of the wavelength division multiplexing transmission system can be increased.

  Examples of flexible optical transceivers are described in Non-Patent Document 2. This is an optical transceiver that can change the modulation speed and modulation format of an optical signal. If a flexible optical transceiver is used, it is possible to increase or decrease the transmission capacity of each optical signal path (wavelength path) in accordance with a change in traffic volume. For example, in a ROADM system that transmits information using a 100 Gbit / s optical signal that uses quaternary phase shift keying (QPSK) as a modulation format, when the traffic volume of some wavelength paths is doubled, Although it was necessary to increase the number of optical transceivers, in the case of a flexible optical transceiver, the transmission capacity of the wavelength path is 200 Gbit / s only by changing the modulation format to 16-value quadrature amplitude modulation (QAM). Therefore, cost and power consumption can be reduced. As another example, in a ROADM system that employs optical path protection that shares a protection path with a plurality of wavelength paths, if a flexible optical transceiver is used for the protection path, the number of wavelength paths in which a failure has occurred is determined. It is possible to increase or decrease the transmission capacity of the backup path.

"Benefits and Requirements of Flexible-Grid ROADMs and Networks", Journal of Optical Communications and Networking, Vol. 5, No. 10, October 2013, pp.19-27. "Flexible Transceivers, ECOC 2012, We.3.A.3, 2012.

  In the wavelength division multiplexing transmission method, non-linear crosstalk that causes phase shift in other optical signals due to wavelength overlap and fiber nonlinearity occurs between optical signals propagating on the same optical fiber transmission line, resulting in signal quality. It is known to decline. Since the ROADM system can add and drop optical signals, it is necessary to confirm in advance that an optical signal can be transmitted with a new configuration to add.

  In addition, the size of the crosstalk depends not only on the size and wavelength arrangement of the optical signal, but also on the modulation speed and modulation format of the optical signal, but the wavelength occupied by the optical signal by the flexible grid or flexible optical transceiver. When the bandwidth, the modulation speed of the optical signal, and the modulation format become variable, the possible forms and specifications of the system increase explosively, and it is difficult to confirm that the optical signal can be transmitted in all configurations. For this reason, the worst condition is assumed for a configuration that is not confirmed in advance, and a limited configuration that can reliably transmit an optical signal even under the worst condition is unavoidable.

  As an influence of the signal quality degradation, in the ROADM system employing the optical path protection, when it is judged that the signal quality is degraded, the path is switched to the backup path. However, since the crosstalk occurs in the mutual optical signals, the signal quality is reduced. There is a possibility that the operation of switching the plurality of lowered wavelength paths to the backup path occurs at the same time and the system becomes unstable.

  The present invention has been made in view of the above problems, and can minimize the influence on the wavelength path when inserting an optical signal or switching the modulation speed or modulation format of an optical signal. The purpose is to provide a system.

  A typical optical wavelength division multiplexing transmission system according to the present invention includes a plurality of optical transmission devices that output optical signals of different wavelengths, an optical reception device that receives each of the optical signals, and a multiplexed output optical signal. And a network management device connected to the optical transmitter and the optical receiver, wherein the optical transmitter outputs an optical signal for testing. Having a test state, the network management device controlling the optical transmission device so as to be in a test state for a predetermined period, and the optical reception device notifying the network management device of the signal quality of the received optical signal It is characterized by.

  The present invention is also grasped as a method for controlling an optical wavelength division multiplexing transmission system.

  According to the present invention, when an optical signal is inserted or a modulation speed or modulation format of an optical signal is switched, the influence on the wavelength path can be suppressed. Thereby, the stability of the system can be improved.

It is a figure which shows the example of the optical network comprised by the ROADM system. It is a figure which shows the example of a structure of an optical wavelength multiplexing transmission system. It is a figure which shows the example of the time change of the optical signal power which an optical transmission device outputs in a test state. It is a figure which shows the example of the time change of the number of errors of the reception data acquired in a test state with an optical receiver. It is a figure which shows the example of a display of a display apparatus. It is a figure which shows the example of the time change of the optical signal power which switches a modulation speed / modulation format and which an optical transmission device outputs in a test state.

  FIG. 1 shows an example of an optical network configured with a ROADM system. Nodes 100-1 to 100-6 at remote locations are connected via an optical fiber transmission line. In this example, there are paths 101-1, 101-2, and 101-3 between the node 100-2 and the node 100-5, between the node 100-1 and the node 100-3, and between the node 100-4 and the node 100-6. The WDM signal is transmitted to each path, and the path 101-4 is set as the backup path (backup path) of the path 101-1.

  However, since the path 101-1 and the path 101-2 share the optical fiber transmission path from the nodes 100-2 to 100-3, different wavelengths are used for the WDM signals transmitted through the paths. Similarly, since the path 101-1 and the path 101-3 share the optical fiber transmission lines from the nodes 100-4 to 100-5, different wavelengths are used for the WDM signals transmitted through the respective paths. In transmission from the node 100-4 to the node 100-6, the node 100-4 adds a WDM signal, and the added WDM signal is transmitted to the node 100-5 and transmitted to the node 100-6. Since −6 drops only the WDM signal from the node 100-4, it is not transmitted to the node 100-2. In the following, it is assumed that the wavelength multiplexing transmission system includes the ROADM system.

  FIG. 2 is a diagram illustrating an example of the configuration of a wavelength division multiplexing transmission system. The optical node 110-1 includes an optical transmission device 201-1 that outputs an optical signal having a wavelength λ1, and an optical transmission device 201-2 that outputs an optical signal having a wavelength λ2. The optical signals of wavelengths λ1 and λ2 are multiplexed by the optical coupler 303, and a WDM signal in which the wavelengths λ1 and λ2 are wavelength-multiplexed is output to the optical fiber transmission line connecting the optical node 110-1 and the optical node 110-2. Is done. The optical node 110-2 includes an optical transmission device 201-3 that outputs an optical signal having a wavelength λ3 and a WSS 305-1. The WSS 305-1 inserts the optical signal having the wavelength λ3 output from the optical transmission device 201-3 into the WDM signal transmitted from the optical node 110-1, and connects the optical node 110-2 and the optical node 110-3. A WDM signal in which the wavelengths λ1, λ2, and λ3 are wavelength-multiplexed is output to the optical fiber transmission line.

  The optical node 110-3 includes a WSS 305-2. The WSS 305-2 cuts out the optical signals having the wavelengths λ1 and λ2 from the WDM signal transmitted from the optical node 110-2, and the wavelengths λ1 and λ2 are connected to the optical fiber transmission line connecting the optical node 110-3 and the optical node 110-4. Outputs a wavelength-multiplexed WDM signal. The WSS 305-2 outputs an optical signal having a wavelength λ3 to an optical fiber transmission line that connects the optical node 110-3 and the optical node 110-5. In the optical node 110-4, the optical signals of the wavelengths λ1 and λ2 transmitted from the optical node 110-3 are separated by the optical branching device 304 and received by the optical receiving devices 301-1 and 301-2, respectively. In the optical node 110-5, the optical signal with the wavelength λ3 transmitted from the optical node 110-4 is received by the optical receiving device 301-3.

  The network management apparatus 302 controls the optical transmission apparatuses 201-1 to 201-3 via the control signal lines 309-1 to 309-3, and the optical reception apparatus 301 via the monitoring signal lines 310-1 to 310-3. -1 to 301-3 are monitored. The control signal lines 309-1 to 309-3 may be physically multiplexed to form one control signal line, or the monitoring signal lines 310-1 to 310-3 may be multiplexed to physically be one. The monitoring signal line may be used. The network management apparatus 302 includes a database 306 that records the arrangement and state of the apparatus, and updates the database 306 as needed if there is a change in the arrangement or state of the apparatus. The monitoring results of the optical receivers 301-1 to 301-3 are also recorded in the database 306.

  A network management terminal 307 for an operator to access the network management apparatus 302 is connected to the network management apparatus 302. When the operator selects one of the three states (OFF state, test state, ON state) of the optical transmission device 201-1 and inputs it to the network management terminal 307, the network management device 302 controls the control signal line 309-1. The control signal 206 is sent to the optical transmission device 201-1 via the switch to switch the state of the optical transmission device 201-1. The operator may input a test period 401, a post-test period 402, a holding time 403, a monitoring period, a reference value, an allowable value, and the like, which will be described later, to the network management terminal 307 and set them in the network management apparatus 302.

  Further, the network management terminal 307 is provided with a display device 308, which displays operator operations and information in the database 306. The network management apparatus 302 may have a general computer structure, that is, a processor and a memory, and the processor may operate according to a program stored in advance in the memory to read / write data in the memory. The network management terminal 307 also has a general computer structure, and the network management device 302 may be connected to the network management terminal 307 via a network such as a LAN (Local Area Network). The network management apparatus 302 may be connected to the network management terminal 307 via a communication port or the like, such as a display or a keyboard.

  Further, the wavelength division multiplexing transmission system has a plurality of network management devices 302, for example, connected to the first network management device connected to the control signal lines 309-1 to 309-3 and the monitoring signal lines 310-1 to 310-3. The second network management device may be provided, and the network management devices may be connected to each other via a communication line such as a radio or the Internet.

  The optical transmitter 201-1 converts an input information signal 203 into an optical signal and outputs the optical signal to an optical fiber 204 and an optical transmitter 202 according to a control signal 206 input from the outside. A controller 205 for controlling the control. The optical transmitter 202 has three states. That is, an off state in which an optical signal is not output, an on state in which an optical signal is output, and a test state in which the optical signal is output after being output for a certain period of time.

  Here, the time during which the optical signal is output in the test state is referred to as a test period. FIG. 3 (1) shows an example of the time change of the optical signal power output from the optical transmitter 202 in this test state. An optical signal is output only during the test period 401 of 0 to 25 milliseconds, and no optical signal is output during the post-test period 402 after 25 milliseconds. The controller 201 switches between the three states of the optical transmitter 202 in accordance with a control signal 206 from the outside. Further, the controller 201 sets the optical power of the optical signal output during the ON state and the test state and the type of the optical signal in accordance with the control signal 206 from the outside. The type of optical signal is either one or both of a modulation format and a modulation speed. The optical transmission devices 201-2 and 201-3 may have the same configuration as the optical transmission device 201-1.

  Next, the operation of each apparatus when the optical transmission apparatus 201-1 is switched from the off state to the test state in the wavelength division multiplexing transmission system of FIG. 2 will be described. When the optical transmission device 201-1 is switched from the OFF state to the test state, the optical reception device 301-1 receives the optical signal only during the test period 401 in which the optical transmission device 201-1 outputs an optical signal. Assuming that the rise time is the time from when the optical receiving device 301-1 receives the optical signal until the optical signal can be demodulated into received data, the optical receiving device can be obtained by setting the test period 401 to be longer than this rise time. 301-1 can output the received data.

  Under this condition, if no reception data is output, it is found that the optical receiver 301-1 cannot demodulate the optical signal, and the optical signal having the wavelength λ1 is conducted in the section from the optical nodes 110-1 to 110-4. It can be judged that it is impossible. Even if received data is output, if the signal quality of the received data falls below a predetermined reference value, it can be determined that the optical signal having the wavelength λ1 cannot be conducted in the section from the optical nodes 110-1 to 110-4. The optical signal may include a general synchronization signal and information for demodulation in serial communication, and the rise time is a time generated by such synchronization.

  A decrease in signal quality can be determined, for example, when the number of errors exceeds a predetermined allowable value. If the prescribed data is inserted into the transmission information in the optical transmitters 201-1 to 201-3, the received data is determined by determining whether the optical receivers 301-1 to 201-3 are the prescribed data. The number of errors can be measured. Also, an error detection / correction code may be inserted, and the number of FEC (forward error correction) error corrections may be used as the number of received data errors.

  In this case, in addition to the rise time, the test period 401 is made longer than the output time including prescribed data and FEC. That is, the test period 401 is made longer than when the optical receiver 301-1 receives an optical signal that can measure the number of errors. By subtracting the number of errors outside the test period 401 from the number of errors measured in the period including the test period 401, the number of errors in the test period 401 can be calculated. Further, the targets monitored by the respective optical receivers 301-1 to 301-3 are not limited to the presence / absence of received data and the number of errors. In addition, a framer (frame processing) synchronization signal, the size of a clock signal extracted from the received signal, and the like can be used.

  The network monitoring apparatus 302 sets a monitoring period including the test period 401, and sends signal quality information including the presence / absence of received data of the optical receiving apparatus 301-1 and the signal quality of the received data in the monitoring period to the monitoring signal line 310-1. Is transmitted to the optical receiver 301-1. Then, based on the signal quality information transmitted from the optical receiver 301-1 through the monitoring signal line 310-1, it is determined whether or not the optical signal conduction of the wavelength λ1 in the section from the optical nodes 110-1 to 110-4 is possible. To do. When it is determined that the optical signal can be conducted, the control signal 206 is sent through the control signal line 309-1 to change the optical transmission device 201-1 to the on state. The control signal 206 includes an optical signal of the same type as the test state, that is, an optical signal having the same modulation format and modulation speed as the test state, an optical signal having the same modulation format as the test state, or light having the same modulation speed as the test state. An instruction to output one of the signals is included. The controller 205 of the optical transmission device 201-1 that has received the control signal 206 controls the optical transmitter (Tx) 202 to output the same type of optical signal as that in the test state, in accordance with an instruction included in the control signal. If the network monitoring apparatus 302 determines that the optical signal cannot be conducted, the network monitoring apparatus 302 does not change the optical transmission apparatus 201-1 to the on state.

  The signal quality report via the monitoring signal line 310-1 may include identification information indicating that the report source is the optical receiver 301-1, and includes the number of received data errors as the signal quality report. Alternatively, the signal quality report may include a comparison result between the number of received data errors and a predetermined allowable value. When the signal quality report includes the comparison result, for example, when the number of errors is less than a predetermined allowable value and the value 1 is reported, the network monitoring apparatus 302 determines whether the report is the value 1 and determines whether the report is the value 1 or not. 1 may be controlled.

  In addition, when the optical transmission device 201-1 is newly added, the optical transmission devices 201-2 and 201-3 are in the on state including the test period 401. Therefore, a test in which the optical transmission device 201-1 outputs an optical signal of the optical signals having the wavelengths λ2 and λ3 received by the optical receiving devices 301-2 and 301-3 due to the crosstalk with the optical signal having the wavelength λ1. The signal quality is deteriorated only during the period 401.

  FIG. 4 (1) shows an example of the change over time of the number of errors in the received data of the optical receiver 301-2 in the test state of the optical transmitter 201-1. The number of errors increases in the test period 404 of 0 to 25 milliseconds corresponding to the test period 401, and the number of errors returns to the original in the post-test period 405 after 25 milliseconds. Here, if the test period 404 is shortened, the time during which the signal quality of the wavelengths λ2 and λ3 deteriorates can be shortened. For example, in a system employing optical path protection, if the test period 404 is shorter than the protection time, the wavelength paths of wavelengths λ2 and λ3 are detoured to backup paths (backup wavelengths and backup paths) due to crosstalk with the optical signal of wavelength λ1. Can be prevented.

  Here, the protection time is a time until the system determines that the signal quality is degraded as a failure, and is a time set in advance in the system, for example, 50 milliseconds. The wavelength path is switched to the backup path only when the signal quality deterioration continues for the protection time or longer. For this reason, in this example, the test period 401 is half of the protection time, but the test period 401 may be less than 50 milliseconds.

  In the test state of the optical transmitter 201-1, the test period 404 in which the received data is not output by the optical receiver 301-2 or 301-3 during the monitoring period, or the test period 404 in which the number of errors in the received data exceeds the allowable value. Is observed, the signal conduction of the wavelength λ1 cannot be conducted in the section from the optical node 110-1 to the optical node 110-4 in order to maintain the signal conduction of the wavelength paths of the wavelengths λ2 and λ3. It should be noted that the influence of the wavelength λ1 on the wavelengths λ2 and λ3 can be determined by making the test period 401 longer than the time during which the optical receivers 301-2 and 301-3 can measure the number of errors.

  The network management apparatus 302 transmits the signal quality information including the presence / absence of received data and signal quality of the optical receivers 301-2 and 301-3 in the monitoring period including the test period 404 to the monitoring signal lines 310-2 and 310-3. Via the network management apparatus 302. Then, the signal quality information transmitted from the optical receiver 301-1 via the monitoring signal line 310-1 and the optical receivers 301-2 and 301-3 via the supervisory signal lines 310-2 and 310-3. Based on the signal quality information of the optical receivers 301-2 and 301-3 transmitted, it is determined whether or not the optical signal having the wavelength λ1 is conductive in the section from the optical nodes 110-1 to 110-4. The network management apparatus 302 is included in the signal quality information transmitted from the optical receiving apparatus 301-1 and the signal quality information of the optical receiving apparatuses 301-2 and 301-3 transmitted from the optical receiving apparatuses 301-2 and 301-3. If the presence / absence of received data for each wavelength is “Yes” and the signal quality of each wavelength meets the prescribed criteria, the continuity is determined to be “Yes”, otherwise the continuity is determined to be “No”. To do.

  When the network management apparatus 302 determines that the optical signal can be conducted, the network management apparatus 302 sends the control signal 206 via the control signal line 309-1 to change the optical transmission apparatus 201-1 to the ON state. The control signal 206 includes an optical signal of the same type as the test state, that is, an optical signal having the same modulation format and modulation speed as the test state, an optical signal having the same modulation format as the test state, or light having the same modulation speed as the test state. An instruction to output one of the signals is included. The controller 205 of the optical transmission device 201-1 that has received the control signal 206 controls the optical transmitter (Tx) 202 to output the same type of optical signal as that in the test state, in accordance with an instruction included in the control signal. When it is determined that the optical signal cannot be conducted, the optical transmission device 201-1 is not changed to the ON state.

  Not only signal quality information transmitted from the optical receiver 301-1, but also signal quality information transmitted from the optical receiver 301-1 and signal quality information transmitted from the optical receivers 301-2 and 301-3. Based on the determination of whether or not the optical signal with the wavelength λ1 is conductive, if the signal quality of the wavelengths λ2 and λ3 does not deteriorate due to the addition of the optical signal with the wavelength λ1, the same as the test state When the optical signal of the wavelength λ1 is controlled to be output, while the signal quality of the wavelengths λ2 and λ3 is deteriorated due to the crosstalk due to the addition of the optical signal of the wavelength λ1, the same as the test state It is possible to control so as not to turn on an optical signal of various types of wavelength λ1.

  Note that the transmission of the signal quality via the monitoring signal lines 310-2 and 310-3 may include identification information indicating that the transmission source is the optical receivers 301-2 and 301-3. The number of received data errors may be included, or the signal quality report may include a comparison result between the number of received data errors and a predetermined allowable value. Information such as the time when the data is received may also be included.

  At the moment when the power of the optical signal having the wavelength λ1 is switched in the test state of the optical transmitter 201-1, each of the optical receivers 301-1 to 301-3 cannot follow this change, and excessive signal degradation is temporarily caused. It can happen. Therefore, averaging or masking may be performed so as to ignore the moment when the signal quality of the received data changes rapidly.

  Next, the relationship between the test period 401 of the optical transmitter 201-1 and the test period 404 in which the influence appears in each of the optical receivers 301-1 to 301-3 will be described. Immediately after the network management apparatus 302 transmits the control signal 206 to the control signal line 309-1, the influence of the test period 401 of the optical transmission apparatus 201-1 on the reception data of each of the optical reception apparatuses 301-1 to 301-3 is still. It does not appear. The delay of the control signal line 309-1, the delay until the optical transmission apparatus 201-1 receives the control signal 206 and switching to the test state, and the optical transmission apparatus 201-1 to each optical reception apparatus 301-1 to 301- After a delay of up to 3 optical transmission lines, a test period 404 appears. The presence / absence of received data and signal quality monitored by each of the optical receiving apparatuses 301-1 to 301-3 are reported to the network management apparatus 302 after receiving the delay of the monitoring signal lines 310-1 to 310-3. The

  In view of the above, the monitoring period in which the network management apparatus 302 monitors the presence / absence of received data and signal quality reported from each of the optical receiving apparatuses 301-1 to 301-3 is the time obtained by adding these delays to the test period 401. Need to be set longer. The network management apparatus 302 records all the above delays for each of the optical receiving apparatuses 301-1 to 301-3 in advance, and the monitoring signal lines 310-1 to 310-1 are transmitted from the respective optical receiving apparatuses 301-1 to 301-3. The presence / absence of received data reported via 310-3 and the signal quality test period 404 may be specified.

  Further, the network management apparatus 302 delays the control signal line 309-1, the delay until the optical transmission apparatus 201-1 receives the control signal 206 and switches to the test state, and the optical reception apparatuses 301-1 to 301. -3 in advance, the respective test periods 404 of the optical receivers 301-1 to 301-3 are specified, and the optical receivers 301-1 to 301-3 receive data. The monitoring period for monitoring presence / absence and signal quality may be limited to the vicinity of the test period 404.

  If the network management apparatus 302 causes each of the optical transmission apparatuses 201-1 to 201-3 to return a signal via the control signal lines 309-1 to 309-3, the control signal lines 309-1 to 309-3 are reciprocated. The sum of the delay and the processing delay of each of the optical transmission devices 201-1 to 201-3 can be measured. Similarly, if signals are returned to the respective optical receivers 301-1 to 301-3 via the monitoring signal lines 310-1 to 310-3, the round trip delays of the monitoring signal lines 310-1 to 310-3 and the respective The sum of the processing delays of the optical receivers 301-1 to 301-3 can be measured.

  Further, the network management device 302 can distribute time information to each of the optical transmission devices 201-1 to 201-3 and each of the optical reception devices 301-1 to 301-3, and can synchronize the time of each device. Thereby, the delay time of the optical signal can be calculated from the transmission time of the optical signal of each of the optical transmission devices 201-1 to 201-3 and the reception time of each of the optical reception devices 301-1 to 301-3.

  When an optical node in which an optical signal with wavelength λ2 or λ3 received by the optical receiver 301-2 or 301-3 is multiplexed with an optical signal with wavelength λ1 output from the optical transmitter 201-1, the interference point is The sum of the propagation delay of the optical signal having the wavelength λ1 from the optical transmission device 201-1 to the interference point and the propagation delay of the optical signal having the wavelength λ2 or λ3 from the interference point to the optical reception device 301-2 or 301-3. The delay of the optical transmission path from the optical transmission device 201-1 to the optical reception device 301-2 or 301-3. The propagation delay of the optical signal having the wavelength λ1 from the optical transmission device 201-1 to the interference point and the propagation delay of the optical signal having the wavelength λ2 or λ3 from the interference point to the optical reception device 301-2 or 301-3 are determined in advance. It can be estimated from the measured distance of each optical fiber transmission line. However, the propagation delay of the optical transmission line is about 5 microseconds per kilometer, and may be ignored if it is sufficiently smaller than other delay times.

  The network management device 302 identifies a wavelength path that is significantly affected by the optical signal of the optical transmission device 201-1, and monitors the optical reception devices 301-1 to 301- when the optical transmission device 201-1 is in a test state. 3 may be limited. An optical receiver that receives at least a wavelength path that does not share an optical fiber transmission line with the wavelength path from the optical transmitter 201-1 to the optical receiver 301-1 can be excluded from monitoring targets. This wavelength path that is not monitored can be derived by referring to the wavelength path information recorded in the database 306. In addition, a criterion for narrowing down the wavelength paths to be monitored may be set in the network management apparatus 302.

  For example, the greater the number of spans in the shared optical fiber transmission line and the closer the wavelength, the greater the crosstalk between optical signals. Paths can be excluded from monitoring targets. Further, if there is a wavelength path whose signal quality has already deteriorated when the optical transmission apparatus 201-1 is in the off state, this may be included in the monitoring target. On the contrary, all usable wavelength paths may be tested and the wavelength path with the best signal quality may be used.

  In the wavelength division multiplexing transmission system, each optical node is provided with an optical transmitter / receiver for monitoring, and an optical signal called an optical supervisory channel (OSC) is inserted into the WDM signal to transmit information between the optical nodes. In the above description, the network management apparatus 302 performs the control of the optical transmission apparatuses 201-1 to 201-3, the monitoring of the optical reception apparatuses 301-1 to 301-3, and the processing of the monitoring information in an intensive manner. This function may be provided in the optical transmitter 201-1. For example, the optical transmission device 201-1 uses the OSC to notify the optical reception devices 301-1 to 301-3 of the test state, and then switches to the test state. In this case, each of the optical receivers 301-1 to 301-3 notifies the optical transmitter 201-1 of the presence / absence of received data and the signal quality in the test periods 401 and 404 via the OSC.

  In addition, the network management apparatus 302 includes a controller 205 that controls the optical transmitter 202, and the network management apparatus 302 directly connects the optical transmission apparatuses 201-1 to 201-3 via the control signal lines 309-1 to 309-3. You may control. When the optical transmission apparatuses 201-1 to 201-3 include the controller 205, the network management apparatus 302 uses the control signal 206 to identify which of the optical transmission apparatuses 201-1 to 201-3 is to be controlled and the optical transmitter. Information for selecting the three states 202 may be included. On the other hand, when the network management device 302 includes the controller 205, the network management device 302 includes the control signal 206 including the control information of the optical signal power output from the optical transmitter 202, and the optical signal power of the network management device 302. You may implement | achieve three states by control of.

  The network management apparatus 302 may record the influence on each of the optical receiving apparatuses 301-1 to 301-3 in the test state of the optical transmitting apparatus 201-1 in the database 306 as a test result. Alternatively, the test results may be displayed on the display device 308 of the network management terminal 307 to notify the operator of the test results. An example of display is shown in FIG. In this example, “#” is the management number assigned to the wavelength path, “Path” is the optical node number through which the wavelength path passes, “Wavelength” is the wavelength of the optical signal, and “Signal quality” is the error in the received data. Rate, “warning” indicates an abnormality such as quality degradation, and “status” indicates the status of the optical transmission device 201-1 or the like. If there is a wavelength path in the test state, the wavelength path whose signal quality may be deteriorated due to the wavelength path is displayed as “Monitoring the influence” in “Status”, and the “Signal quality” and “Warning” are tested. Display information during the period.

  In addition, when the signal conduction of the wavelength λ1 in the section from the optical nodes 110-1 to 110-4 is not possible, it becomes an alternative based on the signal quality of each wavelength path, the amount of crosstalk with other wavelength paths, and the like. The obtained wavelength path (wavelength and path) may also be displayed on the display device 308. FIG. 5B shows an example of this display. The test result in the test state where “#” is 1 is displayed in “warning”, and candidate wavelength paths are displayed in the lower row. In this display example, a change in wavelength is proposed, but another change in path may be proposed. When proposing a route change, it is effective to estimate the section with the greatest degradation from the specifications of the optical fiber transmission path between each optical node and the setting information of the wavelength path, and to propose a path to avoid the section. Proposals can be made.

  Further, when the optical receiver 301-3 reports the signal quality determined that the optical signal cannot be conducted as a result of the test of the example illustrated in FIG. 2, the optical signal and the optical signal transmitted from the optical transmitter 201-1 are transmitted. Since the path overlaps only between the optical node 110-2 and the optical node 110-3 with the optical signal transmitted by the transmission apparatus 201-3, the network management apparatus 302 determines that a problem has occurred in this path portion. May be. When an alternative route exists in this route portion, the network management apparatus 302 may be controlled to automatically switch to the alternative route according to setting information input in advance. In addition, although there is no alternative route in the example shown in FIG. 2, the signal quality determined that the optical signal cannot be conducted between the route 101-1 and the route 101-2 shown in FIG. 1 was reported. In this case, since the routes overlap only between the node 100-2 and the node 100-3, it may be determined that a problem has occurred in this route portion, and the route 101-1 may be switched to the route 101-4. . After switching to the path 101-4, the test may be performed again.

  The network management apparatus 302 may determine the signal quality once for one test period 401 or may determine a plurality of times in one test period 401. For example, the optical receivers 301-1 to 301-3 accumulate the signal quality values and transmit the values to the network management device 302 via the monitoring signal lines 310-1 to 310-3 every second to reset the accumulation. In this case, the network management apparatus 302 determines the influence of the test period 401 from the difference between the accumulation of the signal quality value for 1 second including the test period 401 and the accumulation of the signal quality value for 1 second not including the test period 401. May be.

  In this example, since 1 second including the test period 401 and 1 second not including the test period 401 are generated, the test interval between the test period 401 and the next test period 401 may be 2 seconds or more. If the test interval is sufficiently large, it is not necessary to specify the exact time of the test period 401. However, when a plurality of test periods 401 are required, the entire test time becomes longer. The monitoring period in this case is a period obtained by multiplying the test interval by the number of tests.

  Further, for example, the optical receivers 301-1 to 301-3 send the signal quality value to the network management apparatus 302 via the monitoring signal lines 310-1 to 310-3 every 300 microseconds in one test period 401. In the case of transmission, the network management apparatus 302 may accumulate the signal quality values transmitted a plurality of times in the test period 401. In this example, since the network management apparatus 302 receives a large number of values, the load increases. However, the test interval can be shortened and the test time can be shortened.

  As described above, since the test can be performed without being detected in the protection time such as optical path protection, the influence on the system can be minimized. In addition, since the system is not made unstable by the test, it is always possible to test when changing the configuration, and it is not necessary to limit the configuration to the configuration that can reliably transmit the optical signal even under the worst conditions.

  The second embodiment is an example in which the optical transmitter 202 increases the output of the optical signal stepwise during the test state to change the state from the off state to the on state. FIGS. 3 (2) to 3 (4) are diagrams showing examples of optical signal output during a test state of the optical transmitter 202. FIG.

  In the example of FIG. 3 (2), the optical signal power is increased stepwise every predetermined holding time 403. The optical receiving devices 301-1 to 301-3 monitor the signal quality during the test period for each holding time 403 and notify the network monitoring device 302 of the signal quality. Here, the holding time 403 needs to be longer than the time until it can be confirmed that the signal quality is deteriorated in the optical receivers 301-1 to 301-3 during the test period of the optical transmitter 201-1. When the holding time 403 is sufficiently long, it may be notified by monitoring a plurality of times during the holding time 403. Further, as the number of steps until the transition from the off state to the on state is increased, the test state becomes longer, but the crosstalk to other wavelength paths can be reduced.

  FIG. 4 (2) shows an example of the time variation of the number of errors during the test state of received data of other wavelength paths. The number of errors is suppressed in the initial stage of the test state. For this reason, by canceling the test state when the number of errors exceeds a predetermined reference value and stopping the test, the influence of the test can be minimized. The predetermined reference value is, for example, less than the number of errors at which the time measurement for determining whether the protection time has elapsed is started.

  In the example of FIG. 3 (3), the optical signal power is continuously increased. However, the amount of increase in the optical signal power per unit time is taken into consideration in consideration of the time until the signal quality degradation occurring in the optical receivers 301-1 to 301-3 can be confirmed during the test period of the optical transmitter 201-1. It is desirable to limit. FIG. 4 (3) shows an example of the change over time in the number of errors during the test state of received data of other wavelength paths. Even in this example, the number of errors can be suppressed in the initial stage of the test state.

  In the example of FIG. 3 (4), the optical signal power is increased stepwise at the same holding time 403 as in FIG. 3 (2). However, the time for outputting the optical signal within each holding time 403 is limited to the test period 401 shorter than the holding time 403. If the test period 401 is sufficiently longer than the rise time of the optical receiver 301-1 as in FIG. 3 (1), the optical receiver 301-1 outputs the received data only during the test period 401. be able to. Moreover, if the test period 401 is shortened, the time during which the signal quality of other wavelength paths deteriorates can be suppressed. FIG. 4 (4) shows an example of the time variation of the number of errors during the test state of received data of other wavelength paths. As in FIG. 4A, the time during which the number of errors continues to increase can be limited to the test period 404. In this example as well, the number of errors that occur in the initial stage of the test state can be suppressed.

  In the second embodiment, unlike the first embodiment, the presence / absence of received data and the number of errors reported from the optical receivers 301-1 to 301-3 change stepwise or continuously. Considering this, the network management apparatus 302 in the test state continuously monitors. As described above, the number of errors in the initial stage of the test state can be suppressed and the test state can be obtained.

  The first embodiment is an example in which an optical signal output from the optical transmission device 201-1 is newly inserted, whereas the optical signal output from the optical transmission device 201-1 is already inserted in the third embodiment. It is an example in the case of switching the modulation speed or / and modulation format of an optical signal in a state.

  The connection configuration of the wavelength division multiplexing transmission system in the third embodiment is as shown in FIG. 2, but the optical transmitter 201-1 is different from the first embodiment in three states in the optical transmitter 202, and the modulation speed of the optical signal. Or / and the original state in which the modulation format is not changed, the optical signal modulation speed or / and the changed state after the modulation format is changed, the optical signal modulation speed or / and the modulation format is changed for a predetermined time and then restored. State. The optical receiver 301-1 can receive the optical signals with the modulation speed and the modulation format before and after the switching output from the optical transmitter 201-1.

  Here, the time during which the modulation speed or / and modulation format of the optical signal is changed in the test state is referred to as a test period. FIG. 6A shows an example of the temporal change of the optical signal power output from the optical transmitter 202 in this test state. The modulation format of the optical signal is changed to quaternary intensity modulation only during the test period 401 of 0 to 25 milliseconds, and the post-test period 402 after 25 milliseconds is returned to the original modulation format (for example, phase modulation). . The monitoring operations in the optical receivers 301-1 to 301-3 and the network management device 302 are the same as those already described, and a description thereof will be omitted here.

  As described above, even when the modulation speed or / and modulation format of the optical signal is switched, the influence of the test state on the system can be minimized.

  The connection configuration of the wavelength division multiplex transmission system according to the fourth embodiment is as shown in FIG. 2, but the fourth embodiment operates in the test state among the three states of the optical transmitter 202 in the optical transmitter 201-1. This is an example different from the third embodiment. The optical transmitter 202 according to the fourth embodiment changes the modulation rate or / and the modulation format of the optical signal stepwise during the test state. FIGS. 6 (2) and 6 (3) show examples of optical signal output during the test state of the optical transmitter 202. FIG.

  In the example of FIG. 6B, the modulation speed or / and the modulation format are switched in order from the smallest to the largest degradation amount given to other wavelength paths every predetermined holding time 403. For example, it is known that the degradation given to other wavelength paths due to nonlinear crosstalk increases as the multi-value number of the intensity increases. FIG. 6B shows binary intensity modulation, ternary intensity modulation, and quaternary intensity. In this example, the modulation format is switched in the order of modulation. As a result, it is possible to prevent other wavelength paths from rapidly deteriorating, and to cancel the switching when it deteriorates beyond a predetermined reference value, thereby minimizing the influence of the switching.

  In the example of FIG. 6 (3), the signals are output at different modulation speeds and / or modulation formats every predetermined holding time 403. However, the test time 401 that is shorter than the holding time 403 is limited to the time at which the modulation speed or / and the modulation format at which the optical signal is switched within each holding time 403. After the test period 401 has elapsed, the state before switching to the modulation speed and modulation format is restored. Here, instead of returning to the state before switching the modulation speed and modulation format, the output of the optical signal may be cut off. By limiting to the test period 401, the degradation time given to other wavelength paths can be shortened. The monitoring operations in the optical receivers 301-1 to 301-3 and the network management apparatus 302 are the same as those already described, and the description is omitted here.

  As described above, even when the modulation speed and / or modulation format of the optical signal is switched, the number of errors in the initial stage of the test state can be suppressed to enter the test state.

  The connection configuration of the wavelength division multiplexing transmission system according to the fifth embodiment is as shown in FIG. 2, but the fifth embodiment operates in the test state among the three states in the optical transmitter 202 in the optical transmitter 201-1. This is an example different from the fourth embodiment. The optical transmitter 202 of the fifth embodiment increases the optical signal power stepwise after changing the modulation format of the optical signal during the test state. FIG. 6 (4) is a diagram illustrating an example of the output of the optical signal during the test state in the optical transmitter 202.

  In the example of FIG. 6 (4), the modulation format of the optical signal is completely switched during the test period, but initially the optical signal power is reduced. Thereafter, the optical signal power is increased every holding time 403. The monitoring operations in the optical receivers 301-1 to 301-3 and the network management apparatus 302 are the same as those already described, and the description is omitted here.

  As described above, the modulation format of the optical signal is switched, but even if it is not possible to switch in stages, the number of errors in the initial stage of the test state can be suppressed to enter the test state.

  Although specific description has been given based on each embodiment, the present invention is not limited to the above-described embodiment, and it is needless to say that various modifications can be made without departing from the scope of the invention.

110-1 to 110-5: Optical nodes 201-1 to 201-3: Optical transmitter 202: Optical transmitter 203: Information signal 204: Optical fiber 205: Controller 206: Control signals 301-1 to 301-3: Optical Receiving device 302: Network management device 303: Optical coupler 304: Optical splitters 305-1 to 305-2: WSS
306: Database 307: Network management terminal 308: Display devices 309-1 to 309-3: Control signal lines 310-1 to 310-3: Monitoring signal lines

Claims (15)

A plurality of optical transmitters for outputting optical signals of different wavelengths, an optical receiver for receiving the optical signals, an optical fiber transmission line for multiplexing and transmitting the output optical signals, the optical transmitter, and A wavelength multiplexing transmission system comprising a network management device connected to the optical receiving device,
The optical transmitter has a test state for outputting an optical signal for testing,
The network management device controls the optical transmission device so as to be in a test state for a predetermined period,
The wavelength division multiplex transmission system, wherein the optical receiving apparatus notifies the network management apparatus of the signal quality of the received optical signal.   2. The optical transmission device according to claim 1, wherein the network management device controls the optical transmission device so as to be in a test state only for the predetermined period shorter than a time until it is determined that a failure is bypassed to a protection path. Wavelength multiplex transmission system. The time until it is determined that the failure is bypassed to the backup path is 50 milliseconds,
3. The wavelength division multiplexing transmission system according to claim 2, wherein the network management apparatus controls the optical transmission apparatus to be in a test state for less than 50 milliseconds as the predetermined period. When the optical receiver receives an optical signal for a predetermined time or more, it can notify the signal quality of the received optical signal,
The wavelength division multiplexing transmission system according to claim 2, wherein the network management apparatus controls the optical transmission apparatus so as to be in a test state only for the predetermined period longer than the predetermined time.   3. The wavelength division multiplexing transmission system according to claim 2, wherein the optical transmission device outputs an optical signal whose output power or modulation speed and / or modulation format is switched for the test in the test state. The network management device includes:
6. The control according to claim 2, wherein the optical transmission device is controlled to output the same type of optical signal as that in the test state based on signal quality information notified from the optical transmission device in the test state. 2. A wavelength division multiplexing transmission system according to claim 1. The network management device includes:
Signal quality information notified by an optical receiver that receives another optical signal via an optical fiber transmission line shared with the optical signal for the test, and an optical receiver that receives the optical signal for the test The wavelength division multiplexing transmission system according to claim 6, wherein an optical signal output from the optical transmission device is controlled based on signal quality information notified.   The wavelength division multiplexing transmission system according to claim 1, wherein the network management apparatus controls the optical transmission apparatus to repeat the test state for a predetermined period.   9. The wavelength division multiplexing transmission system according to claim 8, wherein the optical transmission device changes the output power or modulation speed and / or modulation format of the optical signal in a pre-test state step by step.   The wavelength division multiplexing transmission system according to claim 9, wherein the network management device controls the transmission device to cancel the test state based on the notified signal quality. The monitoring period is longer than the sum of the operation delay of the optical transmitter, the propagation delay of the optical fiber transmission line, the operation delay of the optical receiver after the network management device starts controlling the optical transmitter,
The wavelength division multiplexing transmission system according to claim 1, wherein the network management apparatus receives a signal quality notification from the optical receiving apparatus during the monitoring period. A plurality of optical transmitters for outputting optical signals of different wavelengths, an optical receiver for receiving the optical signals, an optical fiber transmission line for multiplexing and transmitting the output optical signals, the optical transmitter, and A method for controlling a wavelength division multiplexing transmission system comprising a network management device connected to the optical receiving device,
A control step of controlling the optical transmission device so that the network management device is in a test state for a predetermined period;
The optical transmitter is in the test state and outputs an optical signal for testing; and
The optical receiving device notifying the network management device of the signal quality of the received optical signal;
A control method characterized by comprising:   In the control step, the network management device controls the optical transmission device so that the test state is set only for the predetermined period shorter than a time until it is determined that the failure is bypassed to the protection path in the output step. The control method according to claim 12, characterized in that: In the notification step, when the optical receiver receives an optical signal for a predetermined time or more, it can notify the signal quality of the received optical signal,
14. The control according to claim 13, wherein the network management apparatus controls the optical transmission apparatus in the control step so that the test state is maintained for the predetermined period longer than the predetermined time in the output step. Method. The signal quality information notified in the notification step includes signal quality information notified by an optical receiver that receives another optical signal via an optical fiber transmission line shared with the optical signal for the test, and the test quality information. Signal quality information notified by an optical receiver for receiving an optical signal for
15. The method according to claim 13, further comprising a step of controlling the optical transmission device to output an optical signal of the same type as the test state based on the signal quality information notified in the notification step. Control method.

Images