JP2002051009A - Optical 1+1 changeover device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To be able to monitor signal quality or the like with respect to a standby system even when an active system is in operation. SOLUTION: Upon the receipt of a check request signal 300 from a management system 250, a controller 230 transmits a switching request 310 to an optical switch drive circuit 164 that throws an optical switch 160 to take a position from a 1st transmission line 120 to a 2nd transmission line 130. A received signal performance monitor 190 gives a detection result 330 from the 2nd transmission line 130 to the controller 230 that throws the optical switch 160 to take a position from the 2nd transmission line 130 to the 1st transmission line 120. The controller 230 stores the detection result to a memory 240 according to a detection result storage instruction 360 on the basis of information from a 1st transmission line optical detector 210 and a 2nd transmission line optical detector 220. The management system 250 stores a result report 400 from the controller 230 to a storage device.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical 1 + 1 switching device for switching between an active system and a non-operating system in an optical transmission device, and more particularly, to an optical 1 + 1 switching device capable of monitoring an inactive device. .

[0002]

2. Description of the Related Art First, a conventional switching configuration for realizing a 1 + 1 switching function will be described. (JP-A-6-244
No. 796, Tong-Ho Wu, "Fiber Network Service Suvi
vability ", Artech House (1992), PP.88-93).

FIG. 11 shows a configuration diagram of a conventional electric 1 + 1 switching configuration. In the electric 1 + 1 switching configuration, an electric signal splitter 901, a working system (synonymous with the operation system, the same applies hereinafter), an optical transmitter 903, a protection system (synonymous with the non-operation system, the same applies hereinafter), an optical transmitter 905, and a working system light Fiber 90
7, a protection system fiber 909, a working system optical receiver 911, a protection system optical receiver 913, a working system performance monitor 915, a protection system performance monitor 917, and an electric switch 919. On the sending side,
The transmission data is split by the electrical signal splitter 901 and output to the working optical fiber 907 and the protection fiber 909 by the working optical transmitter 903 and the protection optical transmitter 905. On the receiving side, an optical signal is received by the working optical receiver 911 and the protection optical receiver 913. The received signal is converted into an electrical signal, and the working system performance monitor 915 and the protection system performance monitor 9 are respectively converted.
At 17, performance monitoring shown in FIG. 13 is performed, and the monitoring information (optical signal deterioration / disconnection, frame shift,
A normal signal is selected by the electric switch 919 based on AIS (Alarm Indication Signal).

FIG. 12 shows a configuration diagram of a conventional optical 1 + 1 switching configuration. In the optical 1 + 1 switching configuration, the optical transmitter 1001,
Optical splitter 1002, working optical fiber 1003,
Protection system fiber 1004, optical switch 100
5, light receiver 1006, light detectors 1007 and 100
8, an optical switch control unit 1009 is provided. On the sending side,
The optical signal output from the optical transmitter 1001 is
02, a working optical fiber 1003
And output to the protection system fiber 1004.
On the receiving side, one of the working optical fiber 1003 and the protection optical fiber 1004 is selected by the optical switch 1005, and the optical receiver 1006 receives the optical signal. Here, photodetectors 1007 and 1008
Monitors the optical intensity of the optical signal shown in FIG.
The optical switch control unit 1009 controls the optical switch 1005 to select a normal signal based on the monitoring information (light intensity decrease).

[0005]

In the conventional electric 1 + 1 switching configuration, the cost is generally increased because all the devices are duplicated. In addition, in the conventional optical 1 + 1 switching method, it is not necessary to duplicate the transmitter and the receiver and the cost is low. However, since switching was performed based only on the light intensity information, sufficient switching performance could not be obtained. Here, the switching performance refers to the case where a failure occurs in the operating system device.
This means that transmission signal quality is maintained by switching, such as quick switching to a non-working system or normal operation after switching.

In view of the above, the present invention makes it possible to obtain information from both a photodetector capable of monitoring a decrease in the intensity of an optical reception signal and a reception signal performance monitor capable of monitoring the performance of the optical reception signal. And to obtain sufficient switching performance.

[0007]

According to the solution of the present invention, in order to achieve the above object, an optical 1 + 1 switching device includes first and second photodetectors respectively provided on first and second transmission lines. An optical switch for selecting any one of the signals of the respective transmission paths by a controller, and a performance monitor for the signal selected by the optical switch.

In order to ensure the signal conduction after the switching, the controller sends a switching request and a switchback request to the optical switch in advance, and operates the optical switch for a predetermined time before switching. Monitor the system.

Further, it is also checked whether or not the transmission line which has become inactive after the switching can be normally operated by recovery or the like. That is, the optical switch switches to a non-operational system based on a request from the control controller when an abnormality occurs. After a lapse of a predetermined time, the controller sends a switching request to the optical switch so as to monitor the newly non-operating transmission line, and after monitoring, switches back the transmission line. Thus, after switching between the active system and the protection system, the protection system is monitored for a predetermined time.

According to another solution of the invention, the light 1 + 1
The switching device, the first and second transmission line output device for monitoring the performance of the optical signal provided in each of the first and second transmission lines,
An optical switch for selecting any of the signals of the respective transmission paths by a control controller. Here, first and second photodetectors for separately monitoring the optical signals transmitted to the first and second transmission lines are separately provided, and the first and second transmission line output devices and the first and second transmission lines are provided. Switching can also be performed based on information from the photodetector.

According to another solution of the invention, the light 1
+1 switching device, the performance monitoring of the optical signal transmitted to each of the first and second transmission path, and the first to monitor the intensity,
The second transmission path output device, and the first and second photodetectors, a blocking device that blocks the optical signal output from both the transmission path output devices, and either the first or second transmission path by the controller. An optical switch for selecting a signal; interrupting an optical signal output based on performance monitoring results of both transmission line output devices; and performing switching based on information from the first and second photodetectors.

According to still another solution of the present invention, the optical 1 + 1 switching apparatus performs first and second transmissions for monitoring the performance and intensity of the optical signals transmitted to the first and second transmission lines, respectively. A road output device, and first and second photodetectors,
An interrupter for interrupting the output of the optical signal from the transmission line output device by the controller, and an optical multiplexer for multiplexing the optical signal, the optical signal based on the performance monitoring results of the transmission line output device, Cut off the output and combine with an optical multiplexer.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a basic configuration diagram of an optical 1 + 1 switching system. In the optical 1 + 1 switching method, the transmitting side is optically branched by a coupler (eg, 3 dB), and a received signal is selected by an optical switch (eg, 2 × 1).

The optical signal transmitter 100 generates a transmission signal by including the transmission data electric signal 105 in a transmission frame, performs E / O conversion, and transmits the signal. The optical splitter 110 splits the input optical signal (for example, 50 to 50) and outputs the split signal to the first and second transmission paths 120 and 130. Optical branch 14
0 and 150 are the first and second transmission paths 120 and 130
The optical signals transmitted through
%). The photodetectors 210 and 220 monitor the intensity of the optical signals transmitted through the first and second optical transmission lines 120 and 130, and monitor the light intensity monitoring information 2 that is the monitoring information of the light intensity.
15, 225 are output.

The optical switch 160 is a switch for selectively outputting either the optical signal of the first transmission line 120 or the optical signal of the second transmission line 130. For example, a 2 × 1 switch can be used. The optical switch driving circuit 165 drives switching of the optical switch 160. Optical signal receiver 180
Receives an optical signal, performs O / E conversion, and
5 is output.

The received signal performance monitor 190 monitors the performance of the received electric signal 185, outputs the performance monitoring result as the signal performance monitoring information 205, and outputs the received data electric signal 195. The signal performance monitoring information 205 includes, for example, LOS (signal loss), LOF (out of frame),
This is monitoring information of AIS (alarm notification signal) and BER (bit error). On the other hand, the received data electric signal 195 is supplied to the optical signal transmitter 200. The optical signal transmitter 200
For example, in order to transmit a signal to a client or another device, a transmission signal is created by being included in a transmission frame, and E
The optical signal is transmitted after the I / O conversion.

The controller 230 mainly exists inside the apparatus, and receives the input light intensity monitoring information 215, 225,
Based on the signal performance monitoring information 205, monitoring and control of the device are performed. The controller 230 gives the optical switch drive circuit 165 a drive request 175 for switching the optical switch 160. The memory 240 includes the controller 2
30 and temporarily stores monitoring results, control results, and the like. The control controller 230 communicates with the management system 250 external to the device directly or via a higher-level in-device controller (not shown).
And send and receive monitoring and control information between them. The management system 250 is mainly outside the device, performs management communication 255 with the device, monitors performance / alarms, controls the device, and the like.

FIG. 2 is a check sequence diagram for monitoring before switching in switching between the active system and the non-active system. Here, the management system 250, the controller 230, the memory 240, the optical switch driving circuit 165, the optical switch 160, and the received signal performance monitor 19 shown in FIG.
0, first transmission line light monitor 210, second transmission line light detector 2
Numeral 20 corresponds to that shown in the basic configuration of FIG. In this check sequence, a check request command is issued before switching to the non-working system due to failure or maintenance. As a result, the protection system can be monitored for a certain period of time before switching, and maintenance performance can be improved.

First, the first and second transmission lines 120 and 13
The case where both 0 are normal will be described as an example. In this case, the first and second transmission path optical detectors 210 and 220 detect that each transmission path is normal. The optical switch 160 is the first transmission line 1
20 has been selected. The received signal performance monitor 190 monitors the performance of the received electric signal 185 from the first transmission line 120.

The management system 250 sends a check request 300 to the controller 230. The transmission timing of the check request 300 from the management system 250
For example, the period and time can be set in advance, or when a failure of another device or the like or a power failure occurs, and the like, can be appropriately determined.

Upon receiving the check request 300, the controller 230 transmits a switching request 310 to the optical switch driving circuit 165. Optical switch drive circuit 165
Receives the switching request 310, the optical switch 160
, The drive signal 320 is transmitted. The optical switch 160
The first transmission path 120 is switched to the second transmission path 130 based on the drive signal 320. As a result, the received signal performance monitor 190 switches from monitoring the performance of the first transmission line 120 to monitoring the performance of the second transmission line 130. Second transmission path 130
For example, when data is not transmitted to the first transmission line 120, the time for checking the normality / abnormality may be set to a slight time that does not affect the transmission or has little effect. it can.

The received signal performance monitor 190 transmits the detection result 330 from the second transmission line 130 to the control controller 23.
Send to 0. The controller 230 detects the detection result 3
Upon receiving the “30”, a switchback request 340 is transmitted to the optical switch drive circuit 165. Optical switch drive circuit 165
Receives the switchback request 340,
Then, the drive signal 350 is transmitted. The optical switch 160
The second transmission path 130 is switched to the first transmission path 120 based on the drive signal 350. As a result, the received signal performance monitor 190 switches from monitoring the performance of the second transmission path 130 to monitoring the performance of the first transmission path 120.

The controller 230 stores information in the memory 240 based on information from the received signal performance monitor 190, the first transmission path photodetector 210, and the second transmission path photodetector 220.
The detection result storage 360 is performed. Further, the management system 25
0 transmits a confirmation request 370 to the controller 230. When receiving the confirmation request 370, the controller 230 transmits a read request 380 to the memory 240. The controller 230 reads 390 the detection result from the memory 240 and transmits the result report 400 to the management system 250. The management system 250 stores the result report 400 in an appropriate storage device. Note that the memory 2
The detection result storage 360 to the management system 250 and the result report 400 to the management system 250 are executed at an appropriate timing and an appropriate number of times.

According to the above-described checking operation, when a failure occurs in the first transmission line 120 as the active system and the second transmission line 130 is switched to the active system, the result of the control controller 230 checking the second transmission line 130 is as follows. When it is determined that the transmission is normal, the optical switch 160 is switched so that the second transmission line 130 is used as the active system, and the transmission can be reliably maintained.

On the other hand, when the controller 230 receives the detection result 330 that the second transmission line 130 is not normal, the optical switch 160 can display an alarm or the like without selecting the second transmission line 130.

FIG. 3 is a check sequence diagram for monitoring after switching in switching between the active system and the non-active system. In this check sequence, a check request command is issued after switching between the active system and the non-active system. As a result, the protection system can be monitored for a certain period of time after the switching, and the maintenance performance can be improved.

Here, the operation when a failure occurs in the first transmission line 120 will be described as an example. When the first transmission path 120 fails, the first transmission path photodetector 210 detects an abnormality. The optical switch 160 selects the first transmission line 120. The received signal performance monitor 190 is the first transmission path 120
Performance monitoring. The received signal performance monitor 190 and the first transmission path photodetector 210
Then, the abnormality alerts 410 and 420 are transmitted to 0, respectively. The control controller 230 outputs the abnormality alarm 410 or 420
Is received, the switching request 430 is transmitted to the optical switch driving circuit 165. When receiving the switching request 430, the optical switch drive circuit 165 transmits a drive signal 440 to the optical switch 160. The optical switch 160 controls the drive signal 4
Based on 40, the first transmission path 120 is switched to the second transmission path 130, and data transmission is maintained using the second transmission path 130 as an active system. Thereby, received signal performance monitor 190
From the performance monitoring of the first transmission line 120
Switch to performance monitoring.

The management system 250 transmits a check request 300 to the controller 230 at a predetermined timing. Here, the predetermined timing is, for example, a timing corresponding to a required number of times after a lapse of a predetermined time from the time when the optical switch 160 is switched, at a predetermined cycle, or the like. When receiving the check request 300, the controller 230 transmits a switching request 310 to the optical switch driving circuit 165. Upon receiving the switching request 310, the optical switch drive circuit 165 transmits a drive signal 320 to the optical switch 160. The optical switch 160, based on the drive signal 320,
Switching from the second transmission path 130 to the first transmission path 120 is performed. As a result, the received signal performance monitor 190 switches from monitoring the performance of the second transmission path 130 to monitoring the performance of the first transmitter 120. Here, it is switched to the first transmission path 120,
The time for checking for normality / abnormality may be, for example, a short time when data is not transmitted to the second transmission path 130 and which has little or no effect on transmission.

The reception signal performance monitor 190 transmits the detection result 330 from the first transmission line 120 to the control controller 23.
Send to 0. This makes it possible to determine whether or not the first transmission line 120 in which the failure has occurred has been restored. The controller 230 receives the detection result 330 from the reception signal performance monitor 190 and
To the switchback request 340. When receiving the switchback request 340, the optical switch drive circuit 165 transmits a drive signal 350 to the optical switch 160. Optical switch 16
0 switches from the first transmission path 120 to the second transmission path 130 based on the drive signal 350. As a result, the received signal performance monitor 190 switches from monitoring the performance of the first transmission line 120 to monitoring the performance of the second transmission line 130.

The controller 230 stores the detection result 360 in the memory 240 based on the information from the received signal performance monitor 190, the first transmission path photodetector 210, and the second transmission path photodetector 220. Further, the management system 250
Sends a confirmation request 370 to the controller 230. When receiving the confirmation request 370, the controller 230 transmits a read request 380 to the memory 240. The controller 230 reads 390 the detection result from the memory 240 and transmits the result report 400 to the management system 250. The management system 250 reports the result report 4
00 in a storage device.

After the failure occurs in the first transmission line 120 which is the active system and the second transmission line 130 is switched to the active system by the above check operation, the controller 230 checks the first transmission line 120. If it is determined that the detection result 330 is not yet recovered, the second transmission path 130 is set to the active system. On the other hand, the controller 230 sends the received signal performance monitor 190
Detection result 33 that the first transmission line 120 has been normally restored
0, the first transmission path 1
20 can be returned to the selected state.

FIG. 4 is a check sequence diagram for period monitoring of the protection system. In this check sequence, a switching request command is issued periodically. As a result, the protection system can be monitored for a predetermined time, and the maintenance performance can be improved.

Here, the operation of the automatic check when the first and second transmission paths 120 and 130 are both normal will be described as an example. In this case, the first and second transmission path optical detectors 210 and 220 detect that each transmission path is normal.
The optical switch 160 selects the first transmission line 120.
The received signal performance monitor 190 monitors the performance of the received electric signal 195 from the first transmission line 120.

When it is time to check whether the second transmission line 130 is normal or abnormal, the controller 230
The switching request 310 is transmitted to the optical switch driving circuit 165. Upon receiving the switching request 310, the optical switch drive circuit 165 transmits a drive signal 320 to the optical switch 160. The optical switch 160, based on the drive signal 320,
The first transmission path 120 is switched to the second transmission path 130.
As a result, the received signal performance monitor 190 switches from monitoring the performance of the first transmission line 120 to monitoring the performance of the first transmission line 130.
The received signal performance monitor 190 transmits the detection result 330 from the second transmission path 130 to the controller 230.

The controller 230 determines the detection result 33
When 0 is received, a switchback request 340 is transmitted to the optical switch drive circuit 165. When receiving the switchback request 340, the optical switch drive circuit 165 transmits a drive signal 350 to the optical switch 160. The optical switch 160 is connected to the first transmission line 12 from the second transmission line 130 based on the drive signal 350.
Switch to 0. Thereby, the received signal performance monitor 19
0 indicates that the performance of the second transmission line 130 is
The performance monitoring switches to 0. Normal of the second transmission line 130
The time to check for an abnormality is, for example, the first transmission path 120
When no data is transmitted, the transmission time may be a short time that does not affect transmission or has little effect.

The controller 230 stores the detection result 360 in the memory 240 based on the information from the received signal performance monitor 190, the first transmission path photodetector 210, and the second transmission path photodetector 220. Also, the controller 23
0 sends a report 400 to the management system 250. The management system 250 stores the report 400 in a storage device.

When it is time to check whether the second transmission path 130 is normal or abnormal, the controller 23
0 transmits the switching request 310 to the optical switch driving circuit 165. Hereinafter, similarly, the processing for checking whether the second transmission path 130 is normal or abnormal as described above is executed. The check timing can be set as appropriate, for example, by setting a cycle and time in advance, or when a failure or power failure of another device or the like occurs. Note that the periodic check can be combined with the above-described check before and after switching.

FIG. 5 is a configuration diagram of a package having a monitor port (1).

The package 5001 includes optical splitters 520 and 525, photodetectors 530 and 535, and an optical switch 54.
0, 545, 550, first transmission path monitor port 560,
A second transmission line monitor port 570 and an operation system port 565 are provided. Note that the package 5001 may not include appropriate components among these components.

The first and second transmission lines 510 and 515, the optical splitters 520 and 525, the photodetectors 530 and 535,
The optical switch 550, the optical signal receiver 580, the received signal performance monitor 590, and the optical signal transmitter 600 are each shown in FIG.
The first and second transmission paths 120 and 1 in the basic configuration of
30, optical splitters 140 and 150, optical detectors 210 and 220, optical switch 160, optical signal receiver 180, received signal performance monitor 190, and optical signal transmitter 200, respectively.

The operation system port 565 is a port for outputting a signal used for the operation system. The first transmission path monitor port 560 outputs a signal of the first transmission path 510 by switching control of the optical switch 540 when the signal of the first transmission path 510 is not used for the operation system. The second transmission path monitor port 570 outputs a signal of the second transmission path by switching control of the optical switch 545 when the signal of the second transmission path 515 is not used for the operation system. Each of the optical switches 540 and 545 is provided with a drive circuit as needed, and is switched by the controller 230 having the above-described basic configuration.

In the configuration of the monitor port (1), ports are provided for the first and second transmission lines 510 and 515, which are capable of monitoring the output of the protection system after switching from the working system to the protection system. Thus, maintenance performance can be improved.

FIG. 6 is a configuration diagram of a package having a monitor port (2).

The package 5002 includes optical splitters 520 and 525, photodetectors 530 and 535, and an optical switch 54.
0, 550, a first transmission line monitor port 560, and an operation system port 565. The package 5002 includes
Appropriate ones of these components may not be included. Another configuration is the above-described monitor port (1).
Is the same as

In the configuration of the monitor port (2), after switching from the working system to the protection system, a port capable of outputting the protection system is provided only for the first transmission line 510, thereby improving the maintenance performance. Can be planned.

FIG. 7 is a configuration diagram of a package having a monitor port (3).

The package 5003 includes optical splitters 520 and 525, photodetectors 530 and 535, and an optical switch 61.
0, working port 620, non-working monitor port 630
Is provided. Note that the package 5003 may not include appropriate ones of these components. Other configurations are the same as those of the above-described monitor port (1).

The operation system port 620 is a port for outputting a signal used for the operation system. Protection port 630
Is a port for outputting a signal used for the protection system. The optical switch 610 is a switch that can select whether to output the signals of the first transmission line 510 and the second transmission line 515 to the working port 620 or the non-working port 630. The configuration is, for example, 2 × 2. Switches can be used. In the first state, the optical switch 610 transmits the optical signal passing through the first transmission line 510 to the active port 620 and the optical signal passing through the second transmission line 515 to the non-operation port 630, respectively. On the other hand, in the second state, on the contrary, the optical signal transmitted through the first transmission line 510 is sent to the protection port 630.
The optical signal passing through the second transmission path 515 is transmitted to the operation port 620.
To switch to each transmission. in this way,
The optical switch 610 includes the optical switch 16 having the above-described basic configuration.
It performs both the function of 0 and the monitor switching function. Optical switch 6
The drive circuit 10 is provided with a drive circuit as needed, and is switched by the controller 230 having the above-described basic configuration.

In the configuration of the monitor port (3), after switching from the working system to the working system, signals can be output from any of the first and second transmission paths 510 and 515, which are new working systems. By providing a non-operational monitor port 630, maintenance performance can be improved.

FIG. 8 is a configuration diagram of a modification of the monitor port (3).

In this embodiment, a monitoring optical signal receiver 660 and a monitoring received signal performance monitor 670 are additionally provided for the protection system monitor port 630. As a result, the quality of the protection signal can be monitored, and the maintenance performance can be improved. This additional portion may be used in common with the configuration of another optical 1 + 1 switching system.

The protection system monitoring optical signal receiver 660 receives the protection system optical signal, performs O / E conversion, converts it into an electrical signal, and outputs a protection system monitoring reception electrical signal 665.
The protection system monitoring received signal performance monitor 670 monitors the performance of the electric signal received in the protection system. For example, SON
For ET and SDH, the received signal performance monitor 19 of FIG.
Monitoring similar to 0 is possible.

FIG. 9 is a block diagram of an apparatus having a function of displaying a route selection state on the transmission side. Generally, when specifying and maintaining a fault location, a search may be made from the upstream of the transmitted signal. At that time, in order to maintain transmission, it is necessary to prevent the optical connector of the active system from being pulled out. Therefore, in this embodiment, by displaying the path selection state of the downstream optical switch on the upstream transmission side,
Since the maintenance person can know which operating system is the current operating system, it is possible to prevent a switch related to the device and transmission line of the operating system from being turned off and to prevent disconnection of a connector, thereby improving maintenance performance.

In this embodiment, in addition to the above basic configuration, the controller 230 transmits the optical switch path selection information 720 to the upstream transmitting side. According to the optical switch path selection information 720, the path selection state on the downstream side is transmitted from the downstream to the upstream. The transmission line is an overhead signal in the signal or a monitoring signal (Optical Supervised) in the WDM system.
Channel) can be used. The controller 730 on the transmission side receives the optical switch path selection information 720 sent from the downstream, and outputs a drive request 740. The LED drive circuit 750 operates either the first transmission path 120 or the second transmission path 130 by emitting either the first transmission path selection LED 770 or the second transmission path selection LED 780 based on the drive request 740. Displays the system. For example, first transmission path selection LED
770 indicates that the selected transmission path is the first transmission path 1 on the downstream side.
Lights up in case of 20. Also, the second transmission path selection LED 7
80 is the downstream, the selected transmission path is the second transmission path 13
Lights when 0.

FIG. 10 shows an example of a configuration diagram of a package front panel on the transmission side. On the package front panel on the transmission side, for example, a first transmission path selection LED 770,
Second transmission path selection LED 780, first transmission path optical connector 7
90, a second transmission path optical connector 795, and the like.

FIG. 14 is a configuration diagram of an optical 1 + 1 switching method for switching by obtaining performance monitoring information from a transmission line output device.
In the optical 1 + 1 switching method, the transmitting side is a coupler (eg, 3 dB)
And the received signal is selected by an optical switch (eg, 2 × 1).

The optical branch 110 receives the input optical signal 110
0 is branched (for example, 50 to 50) and input to the first and second transmission line input devices 1120 and 1130. The first and second transmission path input devices 1120 and 1130 receive the input signals at the optical receivers 1122 and 1132, monitor the performance of the optical signals at the monitoring and processing units 1124 and 1134, convert the format and the like, and transmit the optical signals. The devices 1126 and 1136 convert the wavelength of the signal and output the optical signal to the first and second transmission lines 120 and 130. The first and second transmission line output devices 1140 and 1150 are connected to the first and second transmission line 12
The optical signals transmitted through the optical receivers 114 and 0
2, 1152, and the monitoring and processing units 1144, 11
At 54, the performance of the optical signal is monitored, the format and the like are converted, and the optical transmitters 1146 and 1156 perform E / O conversion and output the optical signal. Monitoring and processing units 1144, 1154
Then, the performance of the received signal is monitored, and the performance monitoring result is output as signal performance monitoring information 1160, 1170. The signal performance monitoring information 1160, 1170 is, for example, monitoring information similar to the signal performance monitoring information 205 of FIG. The optical splitters 1200 and 1210 split the optical signals from the first and second transmission path output devices 1140 and 1150 in small amounts (for example, about 5%). Photodetector 1220, 1
230 is the first and second transmission line output devices 1140 and 1
It monitors the intensity of the optical signal output from 150, and outputs optical intensity monitoring information 1240, 1250, which is optical intensity monitoring information.

The optical switch 160 is a switch that can select any one of the optical signals output from the first and second transmission line output devices 1140 and 1150 and outputs the optical reception signal 1110. A × 1 switch can be used. The optical switch driving circuit 165 drives switching of the optical switch 160.

The controller 230 mainly exists inside the apparatus, and monitors and controls the apparatus based on the signal performance monitoring information 1160 and 1170. Further, the input light intensity monitoring information 1240, 1250 may be used. The controller 230 gives the optical switch drive circuit 165 a drive request 175 for switching the optical switch 160. The memory 240 is connected to the controller 230 and temporarily stores monitoring results, control results, and the like. The control controller 230 controls the management system 2 outside the device.
A management communication 255 is performed directly with or via a higher-level device controller, and monitoring and control information is exchanged between the two. The management system 250 is mainly located outside the device, performs management communication 255 with the device, and performs
It monitors alarms and controls devices. FIG. 15 is a basic configuration diagram of an optical 1 + 1 switching method of switching by interrupting an optical output signal of a transmission line output device. In FIG. 15, the signal performance monitoring information 1160, 11 for transferring the performance monitoring result described in FIG.
Do not use 70. Therefore, the first and second transmission line output devices 1140 and 1150 are provided with blocking devices 1148 and 1158 for blocking the optical output signal. That is, the monitoring and processing units 1144 and 1154 monitor the performance of the received signal, and transfer the performance monitoring results to the blocking devices 1148 and 1158. As the transfer method, the transmission path output device 11
For example, a separate line may be provided in each of the signal frames 40 and 1150, or an empty area in the signal frame may be used.
The cutoff devices 1148 and 1158 are respectively connected to the first and second transmission lines 120 and 13 based on the transferred monitoring result.
When the signal performance of 0 is deteriorated, the optical output signal is cut off.
The optical splitters 1200 and 1210 split the optical signals from the first and second transmission path output devices 1140 and 1150 in small amounts (for example, about 5%). Photodetector 122
0, 1230 are the first and second transmission line output devices 1140
, 1150, and monitor the intensity of the optical signal output from the optical signal.
Is output. As described above, the monitoring and processing units 1144, 1
As a result of the performance monitoring in 154, the signal on the transmission line determined to be a failure is blocked by the blocking devices 1148 and 1158, so that the photodetectors 1220 and 1230 are also determined to be a failure (low light intensity). Will be. The controller 230 mainly exists inside the apparatus, and monitors and monitors the apparatus based on the light intensity monitoring information 1240 and 1250.
Perform control. Except for the above, it is the same as FIG.

FIG. 16 shows the light 1+ without using the optical switch.
It is a basic block diagram of one switching system. In the optical 1 + 1 switching method, the transmitting side is optically branched by a coupler (eg, 3 dB), and the received signal is multiplexed by the coupler. In order to select a signal from two transmission paths as an optical reception signal, the optical multiplexing 1 is performed by blocking devices 1148 and 1158 provided in the first and second transmission path output devices 1140 and 1150 for blocking the optical output signals.
An optical signal to be input to 260 is selected.

The optical branch 110 receives the input optical signal 110
0 is branched (for example, 50 to 50) and input to the first and second transmission line input devices. The first and second transmission line input devices 1120 and 1130 transmit the input signal to the optical receiver 112.
2, 1132 and receive and monitor and process units 1124, 11
At 34, the performance of the optical signal is monitored, the format is converted, the wavelength of the signal is converted by the optical transmitters 1126, 1136, and the optical signal is output to the first and second transmission paths 120 and 130. The first and second transmission line output devices 1140 and 1150 receive the optical signals transmitted via the first and second transmission lines 120 and 130 by the optical receivers 1142 and 1152, and the monitoring and processing units 1144 and 1154 The optical transmitter 114 monitors the performance of the optical signal, converts the format, and the like.
6, 1156 to convert the signal wavelength and output an optical signal. The monitoring and processing units 1144 and 1154 monitor the performance of the received signal, and report the performance monitoring result to the signal performance monitoring information 1
160 and 1170. Signal performance monitoring information 1
160 and 1170 are monitoring information similar to the signal performance monitoring information 205 of FIG. 1, for example. The optical multiplexing device 1260 is an optical multiplexer that multiplexes optical signals output from the first and second transmission path output devices 1140 and 1150 and outputs an optical reception signal 1110. The configuration uses, for example, an optical coupler. Can be.

The controller 230 mainly exists inside the apparatus, and monitors and controls the apparatus based on the signal performance monitoring information 1160 and 1170. Control controller 230
Are the first and second transmission line output devices 1140 and 1150
Are given signal cutoff requests 1180 and 1190 for switching the input signal to the optical multiplexing 1260. Memory 240
Is connected to the controller 230 and temporarily stores monitoring results, control results, and the like. Control controller 230
Performs the management communication 255 directly with the management system 250 outside the apparatus or via a higher-level in-apparatus controller, and exchanges monitoring and control information between the two. The management system 250 is mainly outside the device, performs management communication 255 with the device, monitors performance / alarms, controls the device, and the like.

[0063]

As described above, according to the present invention, it is possible to monitor the signal quality and the like of the protection system even when the protection system is operating, and to maintain the protection system device.

[Brief description of the drawings]

FIG. 1 is a basic configuration diagram of an optical 1 + 1 switching system.

FIG. 2 is a check sequence diagram for monitoring before switching in switching between an active system and a non-active system.

FIG. 3 is a check sequence diagram for monitoring after switching in switching between an active system and a non-active system.

FIG. 4 is a check sequence diagram for period monitoring of a protection system.

FIG. 5 is a configuration diagram of a package including a monitor port (1).

FIG. 6 is a configuration diagram of a package having a monitor port (2).

FIG. 7 is a configuration diagram of a package including a monitor port (3).

FIG. 8 is a configuration diagram of a modification of the monitor port (3).

FIG. 9 is a configuration diagram of an apparatus having a function of displaying a route selection state on a transmission side.

FIG. 10 is a configuration diagram of a package front panel on a transmission side.

FIG. 11 is a configuration diagram of a conventional electric 1 + 1 switching configuration.

FIG. 12 is a configuration diagram of a conventional optical 1 + 1 switching configuration.

FIG. 13 is an explanatory diagram of monitoring contents of a photodetector and a performance monitor.

FIG. 14 is a configuration diagram of an optical 1 + 1 switching method for switching by obtaining performance monitoring information from a transmission line output device.

FIG. 15 is a basic configuration diagram of an optical 1 + 1 switching method without using an optical switch.

FIG. 16 is a diagram illustrating a basic configuration of an optical 1 + 1 switching method in which switching is performed by interrupting an optical output signal of a transmission line output device.

[Explanation of symbols]

 100, 200 optical signal transmitter 105 transmission data electric signal 110, 140, 150 optical branching 120 first transmission line 130 second transmission line 160 optical switch 165 optical switch driving circuit 170 driving signal 175 drive request 180 optical signal receiver 185 reception Electrical signal 190 Received signal performance monitor 195 Received data electrical signal 205 Signal performance monitoring information 210, 220 Photodetector 215 Light intensity monitoring information 225 Management communication 230 Controller 235 Write / read signal 240 Memory 250 Management system 1140, 1150 Transmission path Output device 1120, 1130 Photodetector 1260 Optical multiplexer

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Hideaki Tsushima 216 Totsuka-cho, Totsuka-ku, Yokohama-shi, Kanagawa Prefecture Inside the Communications Division, Hitachi, Ltd. (72) Inventor Masahiro Takatori 216 Totsuka-cho, Totsuka-ku, Yokohama-shi, Kanagawa Prefecture Hitachi, Ltd.Communications Division (72) Inventor Yukio Hayashi Kanagawa Prefecture, Yokohama City, Totsuka-ku 216 Totsuka-cho, Ltd. Hitachi, Ltd. Communications Division (72) Inventor Takashi Mori 216, Totsuka-cho, Totsuka-ku, Yokohama, Kanagawa, Japan (72) Inventor Shinichi Kuwano 180 Totsuka-cho, Totsuka-ku, Yokohama-shi, Kanagawa Prefecture F-term (reference) 5K002 BA06 EA05 EA33 5K014 AA01 CA06 FA01 FA11 GA01 5K021 AA08 BB01 CC13 DD02 EE06 EE07 FF07 FF11 5K042 AA08 CA07 CA10 CA11 CA12 DA16 DA27 FA03 FA25 HA13 JA04

Claims (17)

[Claims] 1. A first and second photodetector for monitoring an optical signal transmitted to each of a first and a second transmission line, and selecting one of an optical signal of a first transmission line and a second transmission line. An optical switch, a performance monitor for monitoring the performance of a signal received via the optical switch, and a controller for switching the optical switch, wherein the first and second photodetectors and the performance monitor 1 + 1 switching device for switching based on the information of 2. A first and a second photodetector for monitoring an optical signal transmitted to each of the first and second transmission paths, and selecting one of the first and second optical paths. An optical switch; a performance monitor for monitoring the performance of a signal received via the optical switch; and control for switching the optical switch based on information from the first and second photodetectors and the performance monitor. A controller for transmitting a drive signal of the optical switch for checking a second transmission line of a non-operating system, wherein the optical switch performs a first transmission in accordance with a drive signal of the control controller. From the path to the second transmission path, the performance monitor, the detection result for the second transmission path,
Transmitting to the control controller, the control controller, when receiving the detection result from the performance monitor, transmits a switchback request of the optical switch, the optical switch according to the switchback request by the control controller, the second An optical 1 + 1 switching device configured to monitor a protection system for a predetermined time before switching to a protection system by switching from a transmission path to a first transmission path. 3. A first and second photodetector for monitoring optical signals transmitted to the first and second transmission lines, respectively, and selecting one of the first transmission line and the second transmission line optical signal. An optical switch; a performance monitor for monitoring the performance of a signal received via the optical switch; and control for switching the optical switch based on information from the first and second photodetectors and the performance monitor. When a failure occurs in the first transmission line, the performance monitor or the first transmission line light detector transmits an abnormality alarm to the control controller, and the control controller receives the abnormality alarm Then, a switching request is transmitted, and the optical switch switches from the first transmission path to the second transmission path in accordance with the switching request by the control controller so that data transmission is maintained. Transmits a switching request to the optical switch after a predetermined time to check the protection first transmission line, and the optical switch transmits the first transmission line from the second transmission line according to the switching request by the controller. Switch to the transmission line, the performance monitor, the detection result for the first transmission line,
Transmitting to the controller, the controller receiving a detection result from the performance monitor, transmitting a switchback request of the optical switch, the optical switch according to a switchback request by the controller, An optical 1 + 1 switching device that switches from a transmission path to a second transmission path to monitor the protection system for a predetermined time after switching between the protection system and the protection system. 4. The control controller periodically transmits a signal for switching an optical switch to check a protection-system transmission line, thereby periodically checking a protection system for a predetermined time. The optical 1 + 1 switching device according to claim 1 or 3, wherein: 5. A check before switching to the protection system, a check after switching between the protection system and the protection system, or a periodic check for the protection system, so that the first or second transmission path to be switched to is normal. The optical 1 + 1 switching device according to claim 1, wherein when the control controller receives a detection result indicating that there is, the first or second transmission path of the protection system is switched to the working system. 6. The memory according to claim 1, further comprising a memory for storing a detection result by the controller based on information from the performance monitor, the first transmission path photodetector, or the second transmission path photodetector. 6. The optical 1 + 1 switching device according to any one of claims 1 to 5. 7. The management system sends a confirmation request to the controller, the controller sends a result report to the management system, and the management system stores the result report in a storage device. The light 1 according to any one of claims 1 to 6, wherein
+1 switching device. 8. A management system for performing management communication with the controller and monitoring performance / alarm or controlling the device, wherein the management system is provided for a predetermined time, a predetermined period from the time of switching the optical switch, 8. A check request is transmitted to the control controller at a predetermined timing such as a time and a cycle according to the number of requests, and the control controller controls the driving of the optical switch according to the check request.
The optical 1 + 1 switching device according to any one of the above. 9. A first and second transmission line monitor port for monitoring the first and second transmission lines, respectively, an operation port connected to an output of the optical switch, and a light from the first transmission line. A second optical switch for switching a signal to one of the first transmission line monitor port or the operation port; and an optical signal from a second transmission line to either the second transmission line monitor port or the operation port. A third optical switch for switching, the first transmission line monitor port, when the signal of the first transmission line is not used for the active system, by the switching control of the optical switch, the signal of the first transmission line On the other hand, when the signal of the second transmission line is not used for the operation system, the signal of the second transmission line is output to the second transmission line monitor port by the switching control of the optical switch. Features The optical 1 + 1 switching device according to claim 1. 10. A first transmission line monitor port for monitoring a first transmission line, an operation port connected to an output of the optical switch, and an optical signal from the first transmission line being transmitted to the first transmission line. A second optical switch for switching to either a monitor port or the working port, wherein the first transmission line monitor port is provided with the optical switch when a signal of the first transmission line is not used for the working system. 9. The optical 1 + 1 switching device according to claim 1, wherein a signal of the first transmission path is output by the switching control of (1). 11. An operation system port connected to a first output of the optical switch, and a protection system monitor port connected to a second output of the optical switch, wherein the optical switch has a first transmission line. 9. The optical 1 + 1 switching apparatus according to claim 1, wherein an optical signal of the first transmission path and the second transmission path are input, and any one of the working port and the protection port can be selected. . 12. The optical 1 + 1 switching apparatus according to claim 11, further comprising an optical signal receiver for monitoring the protection system and a performance monitor of the reception signal connected to the protection monitor port. . 13. The controller transmits optical switch path selection information to an upstream side, and operates either the first transmission path or the second transmission path based on the optical switch path selection information sent from the downstream. The optical 1 + 1 switching device according to claim 1, wherein whether the system is a system is displayed. 14. A first transmission line output device and a second transmission line output device for monitoring the performance of an optical signal transmitted to each of the first and second transmission lines, and a first transmission line or a second transmission line. An optical switch for selecting one of the optical signals; and a controller for switching the optical switch, and an optical 1 + 1 switching device for switching based on information from the first and second transmission path output devices. 15. A first transmission line output device and a second transmission line output device for monitoring the performance of an optical signal transmitted to each of the first and second transmission lines, and a first transmission line output device and a second transmission line output device. First and second photodetectors for monitoring the transmitted optical signal, an optical switch for selecting either the first transmission path or the second transmission path optical signal, and a controller for switching the optical switch And a light 1+ for switching based on information from the first and second transmission path output devices and the first and second photodetectors.
1 switching device 16. A method for monitoring the performance of an optical signal transmitted to each of a first transmission line and a second transmission line, the first transmission line output device and the second transmission line output device, and the first transmission line output device and the second transmission line. A blocking device for blocking the optical signal output from the road output device;
First and second photodetectors that monitor optical signals transmitted to the first and second transmission paths, respectively, and an optical switch that selects either the first transmission path or the second transmission path optical signal, A control controller for switching the optical switch, based on the performance monitoring results of the first and second transmission line output devices, the first transmission line output device and the second transmission line output device by the light blocking device Light 1 + 1 for interrupting the signal output and switching based on information from the first and second photodetectors
Switching device 17. A first transmission line output device and a second transmission line output device for monitoring the performance of optical signals transmitted to the first and second transmission lines, respectively, and the first transmission line output device and the second transmission line output device. A blocking device for blocking an optical signal output from the transmission line output device, first and second photodetectors for monitoring optical signals transmitted to the first and second transmission lines, respectively, a first transmission line or a second An optical multiplexer for multiplexing the optical signals of the two transmission paths, and a control controller for blocking the blocking device, based on a performance monitoring result of the first and second transmission path output devices, the control controller An optical 1 + 1 switching device that operates an interruption device of the first transmission line output device and the second transmission line output device to interrupt an optical signal output and to switch an optical signal to be multiplexed to the optical multiplexer.