JP2003124896A - Optical transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To stop transmission of a multiplexed optical signal on the occurrence of the break of optical fiber cable or the like without the need for additional hardware so as to prevent a strong optical signal from being emitted from a cut-face of the broken optical fiber cable and to detect the completion of the repair of the broken optical fiber cable to restart transmission of the multiplexed optical signal when the repair is confirmed. SOLUTION: An optical transmission system allows each re-transponder section 7 of each of wavelength division multiplex transmitters 2a, 2b to monitor whether the multiplexed optical signal is supplied through each of optical fiber cables 3a, 3b. The presence/absence of the broken cable in each of the optical fiber cables 3a, 3b and the presence/absence of the restoration are judged on the basis of the monitor result, thereby controlling output stop/output restart of the multiplexed optical signal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical transmission system for wavelength-multiplexing and transmitting a plurality of optical signals by using an optical wavelength multiplexing transmission device.

[0002]

2. Description of the Related Art In an optical transmission system in which a plurality of optical signals are wavelength-multiplexed and transmitted and received, as shown in FIG. 10, a plurality of wavelength optical signals having different wavelengths are multiplexed and transmitted and received. Transmission device (WDM device) 102a,
102b and these optical wavelength division multiplexing transmission devices 102a, 1
And a plurality of optical fiber cables 103a and 103b which serve as transmission lines (optical transmission lines) for optical signals transmitted and received between the optical transmission lines 02b and 02b, and each of the wavelength multiplexing transmission devices 102a and 102b, for example, the optical wavelength multiplexing transmission device. When a plurality of electric signals to be transmitted are input to 102a, the electric signals are converted into optical signals (wavelength optical signals) of corresponding wavelengths and multiplexed, and then one optical wavelength division multiplexing transmission The device 102a → one optical fiber cable 103a → the optical wavelength multiplex transmission device 102b is transmitted to the other optical wavelength multiplex transmission device 102b, and the optical signal is separated for each wavelength to be returned to each electrical signal. Each of these electrical signals is output.

Optical wavelength division multiplexing transmission equipment 102a, 102b
Is a plurality of transponder units (TRP-TP) 1 for converting the input electric signals into optical signals of a preset wavelength λi (where i is one of 1, ..., N).
04, and a plurality of optical signals (wavelength optical signals) output from the transponder units 104 and having different wavelengths from each other are wavelength-multiplexed, and the optical fiber cables 103 a, 10
Wavelength multiplex unit (MUX) 10 to be incident on any of 3b
5, and a demultiplexing unit (DEMUX) that separates the wavelength-multiplexed optical signal emitted from any one of the optical fiber cables 103a and 103b into each of the wavelengths to form a plurality of optical signals (wavelength optical signals) 106, and a plurality of retransponder units for converting each wavelength optical signal of wavelength λi (where i is 1, ..., N) emitted from the demultiplexing unit 106 into an electrical signal and outputting the electrical signal. (TRP-RP) 1
07, and when a plurality of electric signals are input, each of these electric signals is converted into an optical signal of a corresponding wavelength and multiplexed, and then each optical fiber cable 103
a, 103b, and when a wavelength-multiplexed optical signal is emitted from any of the optical fiber cables 103a and 103b, the optical signal is separated for each wavelength to obtain a plurality of wavelengths. After being converted into an optical signal (optical signal of wavelength), it is converted into an electrical signal and output.

[0004]

By the way, in the conventional optical transmission system 101 using such optical wavelength multiplex transmission apparatuses 102a and 102b, each optical wavelength multiplex transmission apparatus 1 is used.
Even when the intensity (optical power) of each wavelength optical signal generated by 02a and 102b is such that it does not adversely affect the human eye, each optical wavelength multiplex transmission device 10
Since the optical signals obtained by multiplexing the optical signals of a plurality of wavelengths are emitted from the optical fibers 2a and 102b, the optical fiber cable 103
When a and 103b are broken, a strong optical signal is emitted from the fracture surface, which may adversely affect human eyes.

Therefore, as a method for solving such a problem, in each of the optical WDM transmission devices 102a and 102b,
A supervisory information optical signal generator (not shown) that generates a supervisory information optical signal (OSC), a supervisory information optical signal output from the supervisory information optical signal generator, and a multiplex output from the wavelength multiplexer 105. A multiplexing unit (not shown) that multiplexes the converted optical signal and sends the multiplexed optical signal to each of the optical fiber cables 103a and 103b, and the optical fiber cables 103a and 103b. A separation unit (not shown) that separates the optical signal into a plurality of wavelength optical signals and a monitoring information optical signal, and detects the presence or absence of the monitoring information optical signal that is separated from each other optical signal by this separation unit. A monitoring information optical signal detector (not shown) is provided,
While operating the monitoring information optical signal generation unit and the multiplexing unit of each optical wavelength division multiplexing transmission device 102a, 102b to send the monitoring information optical signal to either of the optical fiber cables 103a, 103b, the demultiplexing unit, the monitoring information The optical signal detector is operated to check whether or not the monitoring information optical signal is multiplexed with the optical signal supplied via any of the optical fiber cables 103a and 103b, and when this is not detected, A number of methods have been proposed in which it is determined that the optical fiber cable 103a or the optical fiber cable 103b is broken, and the optical wavelength multiplexing transmission devices 102a and 102b stop outputting optical signals.

However, in such a method, it is necessary to provide a supervisory information optical signal generator, a multiplexer, a demultiplexer, and a supervisory information optical signal detector in each of the optical wavelength division multiplexing transmission devices 102a and 102b. However, there is a problem that not only the size of each of the optical WDM transmission devices 102a and 102b is increased, but also the cost is increased.

The present invention has been made in view of the above, and an optical fiber can be used without using hardware such as a monitor information optical signal generator, a multiplexer, a demultiplexer, and a monitor information optical signal detector. When the cable breaks, the transmission of the multiplexed optical signal can be stopped to prevent a strong optical signal from being emitted from the cross section of the broken optical fiber cable, and the repair of the broken optical fiber cable is completed. When this is detected, it is possible to restart the transmission of the multiplexed optical signal when the repair is confirmed, and this ensures high safety while restoring the optical fiber cable and communicating. It is an object of the present invention to provide an optical transmission system capable of restarting.

The present invention also provides a monitoring information optical signal generator,
When the optical fiber cable is broken without using the hardware such as the multiplexing unit, the demultiplexing unit, and the monitoring information optical signal detection unit, the transmission of the multiplexed optical signal is stopped,
It is possible to prevent a strong optical signal from being emitted from the cross section of the broken optical fiber cable, and when the repair of the broken optical fiber cable is completed, this is detected and the transmission of the multiplexed optical signal is restarted. Therefore, it is an object of the present invention to provide an optical transmission system capable of restarting communication when the optical fiber cable is restored while ensuring high safety.

The present invention also provides a monitoring information optical signal generator,
When the optical fiber cable is broken without using the hardware such as the multiplexing unit, the demultiplexing unit, and the monitoring information optical signal detection unit, the transmission of the multiplexed optical signal is stopped,
It is possible to prevent a strong optical signal from being emitted from the cross section of the broken optical fiber cable, and to restore the disconnection of the optical fiber cable while preventing the emission of the multiplexed wavelength optical signal from the cross section of the broken optical fiber cable. Is checked, and when the repair of the broken optical fiber cable is completed, the transmission of the multiplexed optical signal can be restarted, thereby ensuring high safety and It is an object of the present invention to provide an optical transmission system capable of restarting communication with restoration.

The present invention also provides a monitoring information optical signal generator,
When the optical fiber cable is broken without using hardware such as a multiplexing unit, a demultiplexing unit, and a monitoring information optical signal detection unit, each wavelength optical signal output from the transmission device is captured, multiplexed, and processed. It is possible to stop the emission process for the fiber cable, and when the repair of the broken optical fiber cable is completed, detect this and take in each wavelength optical signal emitted from the transmission device, multiplexing process, It is an object of the present invention to provide an optical transmission system capable of resuming the emission processing for an optical fiber cable.

[0011]

In order to achieve the above object, the present invention (Claim 1) multiplexes optical signals of respective wavelengths by one of the optical wavelength division multiplex transmission equipments to provide an optical fiber cable. In the optical transmission system in which the multiplexed optical signal emitted from the other end of the optical fiber cable by the other optical wavelength division multiplexing transmission device while being incident on one end is taken in and separated into each wavelength optical signal, When the optical signal of each wavelength is no longer emitted from the optical fiber cable, it is determined that the optical fiber cable is broken, and the optical signal of each wavelength is output for each predetermined period (T1) for each predetermined time in each wavelength unit. Check whether each wavelength optical signal is emitted from the other end of the optical fiber cable within the monitoring time (T2) while being incident on one end of the optical fiber cable. Then, when each wavelength optical signal is emitted from the other end of the optical fiber cable for a predetermined time (T3), it is determined that the disconnection recovery of the optical fiber cable is completed, and each wavelength optical signal is determined. It is characterized by restarting the communication process using.

According to the present invention, one optical wavelength division multiplexing transmission equipment multiplexes the optical signals of respective wavelengths and makes them enter one end of the optical fiber cable, while the other optical wavelength division multiplexing transmission equipment makes the optical fiber. In an optical transmission system that captures a multiplexed optical signal emitted from the other end of the cable and separates it into optical signals of respective wavelengths, when the optical signal of each wavelength is no longer emitted from the optical fiber cable, the optical fiber It is judged that the cable has been broken, and each wavelength unit is made to enter the one end of the optical fiber cable for each predetermined period (T1) for a predetermined time, and within the monitoring time (T2), It is checked whether each wavelength optical signal is emitted from the other end of the optical fiber cable, and the optical fiber cable is kept for a predetermined time (T3). When the optical signal of each wavelength is emitted from the other end of the optical fiber cable, it is determined that the recovery of the disconnection of the optical fiber cable is completed, and the communication process using the optical signal of each wavelength is restarted, thereby monitoring information. Optical signal generator,
When the optical fiber cable is broken without using the hardware such as the multiplexing unit, the demultiplexing unit, and the monitoring information optical signal detection unit, the transmission of the multiplexed optical signal is stopped,
In addition to preventing a strong optical signal from being emitted from the cross section of the broken optical fiber cable, when the repair of the broken optical fiber cable is completed, this is detected, and when the repair is confirmed, the multiplexed optical signal is detected. While restarting the signal transmission to ensure high safety,
Communication is restarted when the optical fiber cable is restored.

Further, according to the present invention (claim 2), the optical signals of the respective wavelengths are multiplexed by one of the optical wavelength division multiplex transmission devices and are made incident on one end of the optical fiber cable.
In the optical transmission system that captures the multiplexed optical signal emitted from the other end of the optical fiber cable by the other optical wavelength multiplex transmission device and separates it into each wavelength optical signal, each wavelength from the optical fiber cable When the optical signal is no longer emitted, it is judged that the optical fiber cable is broken, and each wavelength optical signal is applied to one end of the optical fiber cable for each predetermined period (T1) in each wavelength unit for a predetermined time. While being incident, it is checked whether each wavelength optical signal is emitted from the other end of the optical fiber cable within the monitoring time (T2), and each wavelength optical signal is emitted from the other end of the optical fiber cable. When the optical fiber cable is disconnected, it is determined that the disconnection recovery of the optical fiber cable is completed, and communication processing using each wavelength optical signal is restarted. To have.

According to the present invention, one of the optical wavelength division multiplex transmission equipment multiplexes each wavelength optical signal and makes it enter one end of the optical fiber cable, and the other optical wavelength division multiplex transmission equipment makes the optical fiber. In an optical transmission system that captures a multiplexed optical signal emitted from the other end of the cable and separates it into optical signals of respective wavelengths, when the optical signal of each wavelength is no longer emitted from the optical fiber cable, the optical fiber It is judged that the cable has been broken, and each wavelength unit is made to enter the one end of the optical fiber cable for each predetermined period (T1) for a predetermined time, and within the monitoring time (T2), It is checked whether each wavelength optical signal is emitted from the other end of the optical fiber cable, and each wavelength optical signal is emitted from the other end of the optical fiber cable. When is being emitted, by determining the disconnection restoration of the optical fiber cable is terminated,
By restarting the communication process using each wavelength optical signal, the optical fiber cable is disconnected without using the hardware such as the monitoring information optical signal generation unit, the multiplexing unit, the demultiplexing unit, and the monitoring information optical signal detection unit. In this case, the transmission of the multiplexed optical signal is stopped so that a strong optical signal is not emitted from the cross section of the broken optical fiber cable, and this is detected when the repair of the broken optical fiber cable is completed. Then, the transmission of the multiplexed optical signal is restarted, thereby ensuring high safety and restarting the communication when the optical fiber cable is restored.

Further, the present invention (claim 3) is characterized in that the predetermined period (T1) is adjusted for each wavelength optical signal and the emission timing of each wavelength optical signal is shifted.

According to the present invention, the predetermined period (T1) is adjusted for each wavelength optical signal, and the emission timing of each wavelength optical signal is shifted, whereby the monitoring information optical signal generator and the multiplexer are provided. When the optical fiber cable is broken without using the hardware such as the separation unit and the monitoring information optical signal detection unit, the transmission of the multiplexed optical signal is stopped and the cross section of the broken optical fiber cable is strong. While preventing the optical signal from being emitted and preventing the multiplexed wavelength optical signal from being emitted from the cross section of the broken optical fiber cable, it is checked whether the restoration of the broken optical fiber cable has been completed, and the broken optical signal is checked. When the repair of the fiber cable is completed, the transmission of the multiplexed optical signal is restarted, thereby ensuring high safety and Along with the recovery of Buru, to resume the communication.

Further, according to the present invention (claim 4), each of the optical wavelength division multiplexing transmission devices multiplexes each wavelength optical signal emitted from the optical transmission device and makes the optical signal enter one end of the optical fiber cable. Alternatively, it is characterized in that a multiplexed optical signal emitted from the other end of the optical fiber cable is taken in, separated into optical signals of respective wavelengths, and made to enter an optical receiving device.

According to the present invention, each optical wavelength division multiplexing transmission device multiplexes each wavelength optical signal emitted from the optical transmission device and makes it enter one end of the optical fiber cable, or the optical fiber cable. By taking in the multiplexed optical signal emitted from the other end of the optical signal, separating it into optical signals of respective wavelengths, and making them incident on the optical receiving device, the monitoring information optical signal generating section, multiplexing section, demultiplexing section, monitoring When the optical fiber cable is broken without using hardware such as the information optical signal detection unit, the processing of capturing the optical signals of each wavelength emitted from the transmitter, the multiplexing processing, and the processing of emitting the optical fiber cable are stopped. At the same time, when the repair of the broken optical fiber cable is completed, this is detected and the process of capturing the optical signal of each wavelength emitted from the transmitter is performed. , Multiplexing process, resuming the like emission process for optical fiber cables.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of an optical transmission system according to the present invention will be described in detail below with reference to the accompanying drawings.

(Embodiment 1) FIG. 1 shows Embodiment 1 of the optical transmission system according to the present invention, which corresponds to claim 1.
It is a block diagram showing.

The optical transmission system 1 shown in this figure includes a plurality of optical wavelength division multiplexing transmission devices (WDM devices) 2a and 2b for transmitting and receiving a plurality of optical signals having different wavelengths, and these optical wavelength division multiplexing transmission devices 2a and 2b. A plurality of optical fiber cables 3 serving as transmission lines (optical transmission lines) for optical signals transmitted and received between
a and 3b, each of the wavelength division multiplexing transmission devices 2a, 2
b, for example, when a plurality of electrical signals to be transmitted are input to the optical wavelength multiplexing transmission device 2a, the electrical signals are generated into optical signals (wavelength optical signals) of the corresponding wavelengths and multiplexed. Then, the optical signal is transmitted to the other optical wavelength division multiplex transmission apparatus 2b through the route of the one optical wavelength division multiplex transmission apparatus 2a → the one optical fiber cable 3a → the optical wavelength division multiplex transmission apparatus 2b, and each optical signal is transmitted by wavelength. Separated into
The electric signals are returned to each other and the electric signals are output. Further, in parallel with these operations, it is made to monitor whether or not the multiplexed optical signal is supplied to each wavelength division multiplexing transmission device 2a, 2b, and based on the monitoring result, the presence or absence of disconnection of each optical fiber cable 3a, 3b. By controlling the presence / absence of restoration, it is possible to control the stop and restart of the output of the multiplexed optical signal.

Each of the optical wavelength division multiplex transmission devices 2a and 2b has a plurality of transponder units (TRP-T) for converting each input electric signal into an optical signal of each wavelength (wavelength optical signal).
P) 4 and each wavelength optical signal output from each transponder unit 4 are multiplexed, and each optical fiber cable 3
Wavelength multiplex unit (MUX) that is incident on either a or 3b
5 and an optical signal supplied via any one of the optical fiber cables 3a and 3b, an optical signal of each wavelength (wavelength optical signal)
And a demultiplexing unit (DEMUX) 6 for demultiplexing, and whether or not an optical signal (wavelength optical signal) of each wavelength is output from the demultiplexing unit 6 and the operation of each transponder unit 4 based on the monitoring result. And a plurality of retransponder units (TRP-RP) 7 for converting each wavelength optical signal output from the demultiplexing unit 6 into an electric signal while controlling the above.

Then, after converting a plurality of electric signals output from a transmitter (not shown) into optical signals of respective wavelengths (wavelength optical signals) and multiplexing them, the respective optical fiber cables 3a, A plurality of optical signals (wavelength optical signals) are obtained by demultiplexing the wavelength-multiplexed optical signal supplied via any one of the optical fiber cables 3a and 3b into each wavelength while being incident on any of the optical fibers 3b. After that, it is converted into an electric signal and output to a receiving device (not shown).

In parallel with each of these operations, when the wavelength-multiplexed optical signal is no longer supplied through any one of the optical fiber cables 3a and 3b, for example, the optical fiber cable 3a, the optical wavelength multiplex transmission is performed. The device 2b is caused to judge that one of the optical fiber cables 3a and 3b is broken, and stops the generation of each wavelength optical signal, and transmits the wavelength-multiplexed optical signal to the optical fiber cable 3b. The supply is stopped, and the optical wavelength multiplex transmission device 2a is caused to determine that one of the optical fiber cables 3a and 3b is broken, and the generation of each wavelength optical signal is stopped.

After that, each of the optical wavelength division multiplex transmission devices 2a and 2b.
Then, the recovery check operation of the optical fiber cables 3a and 3b is started, and each wavelength optical signal is generated for each wavelength at a predetermined cycle (T1) for a predetermined period. While injecting into the
During 2), it is checked whether or not the optical signals of the respective wavelengths are supplied via the respective optical fiber cables 3a and 3b, and by this check operation, all the optical signals of the respective wavelengths (wavelength optical signals) are supplied. This state is maintained for a predetermined period (T3)
Each optical fiber cable 3
It is judged that the restoration of a and 3b is completed, and the transmission / reception operation of the multiplexed optical signal is restarted.

The operation of the optical transmission system 1 will be described below with reference to the block diagram shown in FIG. 1, the operation table shown in FIG. 2 and the timing chart shown in FIG. First, when each of the optical fiber cables 3a and 3b is not broken, every time a plurality of electric signals are input from the transmitter to one of the wavelength multiplexing transmission devices 2a and 2b, for example, the optical wavelength multiplexing transmission device 2a, Each transponder unit 4 and wavelength multiplexing unit 5 convert these electrical signals into optical signals of corresponding wavelengths and multiplex them, and then one optical wavelength multiplexing transmission device 2a → optical fiber cable 3a → optical wavelength It is transmitted to the other optical wavelength multiplex transmission device 2b through the path of the multiplex transmission device 2b.

Then, the optical signal is demultiplexed into wavelengths by the demultiplexing unit 6 and each retransponder unit 7 of the optical wavelength division multiplexing transmission device 2b, and each optical signal is returned to the receiving device.

In parallel with each of these operations, it is checked whether or not the wavelength-multiplexed optical signals are supplied by the wavelength-multiplexing transmission devices 2a and 2b through the optical fiber cables 3a and 3b. When the wavelength-multiplexed optical signal is not supplied via any one of the optical fiber cables 3a and 3b, for example, the optical fiber cable 3a, and this state continues for a preset time or longer, As shown in operation table 8, wavelength division multiplexing transmission device 2
Each of the re-transponder units 7b of b determines that one of the optical fiber cables 3a and 3b is disconnected,
Each transponder unit 4 has a suspended mode (Suspen
ded Mood) and the electrical signal / optical signal conversion operation is stopped.

As a result, the wavelength-division-multiplexed optical signal is transmitted through the optical fiber cable 3b.
a is no longer supplied to the
When this state continues, each re-transponder unit 7 of the optical WDM transmission device 2a causes each optical fiber cable 3
When it is determined that any one of a and 3b is disconnected, each transponder unit 4 is set to the suspended mode and the electric signal / optical signal conversion operation is stopped.

After that, as shown in FIG. 3, the transponder units 4 of the optical wavelength division multiplexing transmission devices 2a and 2b are set to the restoration trial mode for each wavelength at a predetermined cycle (T1) to perform the optical wavelength division multiplexing transmission. An optical signal of a predetermined wavelength and a predetermined width (a single-wavelength optical signal) is sequentially output from each transponder unit 4 of the device 2a, and each transponder unit 4 → wavelength multiplex unit 5
→ The optical fiber cable 3a is incident on the optical fiber cable 3a and the optical wavelength multiplex transmission device 2
It is checked by each retransponder unit 7 of b that any one of the optical signals of each wavelength is supplied via the optical fiber cable 3a, and further, each transponder unit 4 of the optical wavelength multiplex transmission apparatus 2b has a predetermined wavelength and a predetermined wavelength. Width optical signals (single wavelength optical signals) are sequentially output, and each transponder unit 4 → wavelength multiplexing unit 5 → optical fiber cable 3
It is determined whether or not one of the optical signals of each wavelength is supplied via the optical fiber cable 3b by each retransponder unit 7 of the optical wavelength multiplex transmission device 2a while being incident on the optical fiber cable 3b through the route b. Checked.

Then, one of the transponder sections 4 provided in the optical wavelength division multiplexing transmission apparatus 2b, the wavelength division multiplexing section 5, causes the optical signal to be incident on the optical fiber cable 3b, and the preset monitoring time is set. Even when (T2) has passed, when the retransponder unit 7 does not detect the supply of the optical signal through the optical fiber cable 3a, it is determined that the disconnection recovery process of the optical fiber cables 3a and 3b has not been completed. The recovery trial mode described above is continued, and an optical signal of a predetermined wavelength and a predetermined width (a single-wavelength optical signal) is sequentially output from each transponder unit 4 at a predetermined cycle (T1) for each wavelength. The light is incident on the optical fiber cable 3b along the path of the transponder unit 4 → the wavelength multiplexing unit 5 → the optical fiber cable 3b, and each re-transmission of the optical wavelength multiplexing transmission device 2b. The Suponda unit 7, any of the wavelength optical signal through the optical fiber cable 3a is checked whether it is supplied.

In parallel with this operation, one of the transponder sections 4 provided in the optical wavelength division multiplexing transmission apparatus 2a, the wavelength division multiplexing section 5, causes the optical signal to enter the optical fiber cable 3a in advance. Even when the set monitoring time (T2) has passed, when the retransponder unit 7 does not detect the supply of the optical signal through the optical fiber cable 3b, the disconnection recovery of the optical fiber cables 3a and 3b is completed. It is determined that there is not, the above-described restoration trial mode is continued, and for each wavelength, at a predetermined cycle (T1),
An optical signal of a predetermined wavelength and a predetermined width (optical signal of a single wavelength) is sequentially output from each transponder unit 4, and each transponder unit 4 → wavelength multiplexer 5 → optical fiber cable 3a is routed to the optical fiber cable 3a. Upon incidence, each retransponder unit 7 of the optical wavelength division multiplexing transmission device 2a
Checks whether a single-wavelength optical signal is being supplied via the optical fiber cable 3b.

After this, the recovery processing of the broken optical fiber cable 3a is completed, and each optical wavelength multiplex transmission device 2
a or 2b, for example, the optical wavelength division multiplexing transmission device 2b
Each of the transponder units 7 within a preset monitoring time (T2) from when the optical signal is made incident on the optical fiber cable 3b by the wavelength multiplexing unit 5 which is one of the transponder units 4 provided in When the supply of the wavelength optical signal is detected via any one of the optical fiber cables 3a, it is determined that the disconnection of the optical fiber cables 3a and 3b may have been recovered, and the preset recovery is performed. When the confirmation time (T3) has elapsed, each retransponder unit 7 checks whether or not the supply of the wavelength optical signal is continuously detected.

Then, when the supply of the wavelength optical signal is continuously detected by any of the retransponders 7 of the optical wavelength division multiplexer 2b, it is determined that the disconnection of the optical fiber cable 3a has been completely restored. Then, the mode is returned to the normal mode, and the transponder unit 4 and the wavelength multiplexing unit 5 provided in the optical wavelength division multiplexing transmission device 2b convert a plurality of electric signals output from the transmission device into optical signals of corresponding wavelengths. After being multiplexed, they are transmitted to the other optical wavelength division multiplex transmission apparatus 2a through a route of one optical wavelength division multiplex transmission apparatus 2b → optical fiber cable 3b → optical wavelength multiplex transmission apparatus 2a.

After this, from the time when the optical signal is made incident on the optical fiber cable 3a by the transponder unit 4 and the wavelength multiplexing unit 5 provided in the optical wavelength multiplexing transmission device 2a,
When the supply of the optical signal is detected through the optical fiber cable 3b by any of the retransponder units 7 within the preset monitoring time (T2), the disconnection of the optical fiber cables 3a and 3b is restored. When it is determined that there is a possibility that the supply of the optical signal is continuously detected by each retransponder unit 7, when the preset restoration confirmation time (T3) has elapsed. .

When the supply of the wavelength optical signal is continuously detected by any one of the retransponders 7 of the optical wavelength multiplexing transmission device 2a, the disconnection of the optical fiber cables 3a and 3b is completely restored. It is determined that the optical signal of each wavelength is returned to the normal mode, and the transponder unit 4 and the wavelength multiplexing unit 5 provided in the optical wavelength division multiplexing transmission device 2a correspond to the plurality of electric signals output from the transmission device. After being converted into a multiplex signal and multiplexed, one optical wavelength multiplex transmission device 2a → optical fiber cable 3b → optical wavelength multiplex transmission device 2b is routed through the other optical wavelength multiplex transmission device 2b.
Be transmitted to.

As described above, in the first embodiment, the multiplexed optical signals are supplied by the retransponder units 7 of the wavelength division multiplexing transmission devices 2a and 2b via the optical fiber cables 3a and 3b. To monitor whether there is
Based on this monitoring result, each optical fiber cable 3a, 3
Since the presence or absence of disconnection and the restoration of b are controlled to control the output stop and restart of the multiplexed optical signal, the monitoring information optical signal generation unit, the multiplexing unit, the demultiplexing unit, the monitoring information optical When the optical fiber cables 3a, 3b and the like are disconnected without using hardware such as a signal detection unit, the transmission of the multiplexed optical signal is stopped and the disconnected optical fiber cable, for example, the optical fiber cable 3a.
A strong optical signal can be prevented from being emitted from the cross section of the optical fiber cable, and when the repair of the broken optical fiber cable 3a is completed, this is detected, and when the repair is confirmed, the multiplexed optical signal is detected. Of the optical fiber cable 3a can be resumed, and communication can be resumed with the recovery of the optical fiber cable 3a while ensuring high safety (effect of claim 1).

(Second Embodiment) FIG. 4 shows a second embodiment of the optical transmission system according to the present invention, which corresponds to claim 2.
It is a block diagram showing. In this figure, the same parts as those in FIG. 1 are designated by the same reference numerals.

The optical transmission system 11 shown in this figure differs from the optical transmission system 1 shown in FIG. 1 in that it has a plurality of optical wavelength division multiplex transmission equipment (WDM equipment) having a normal mode, a suspended mode, a restoration trial mode, and a restoration confirmation mode. ) 2a, 2
Instead of b, as shown in the operation table 12 of FIG.
When a plurality of optical wavelength multiplex transmission devices (WDM devices) 2c and 2d having only the suspended mode and the recovery trial mode are used to omit the recovery confirmation operation and the recovery processing of the broken optical fiber cables 3a and 3b is completed. , Each retransponder unit 7 of each optical wavelength division multiplexing transmission device 2c, 2d
This is to detect this and immediately return to the normal mode.

As a result, each optical wavelength division multiplexing transmission device 2c,
If the intensity of the multiplexed optical signal incident on the optical fiber cables 3a and 3b from 2d is weak and the optical signal is emitted from the fracture surface of the optical fiber cables 3a and 3b for a short time, there is no problem. At this time, it is possible to shorten the time required to return from the restoration trial mode to the normal mode by using such optical wavelength division multiplexing transmission devices 2c and 2d, and simplify the control algorithm to reduce the entire system. The cost can be reduced.

As described above, in the second embodiment, the multiplexed optical signal is supplied via the optical fiber cables 3a and 3b by the retransponder units 7 of the wavelength division multiplexing transmission devices 2a and 2b. To monitor whether there is
Based on this monitoring result, each optical fiber cable 3a, 3
When the restoration processing is completed after the disconnection of any of the optical fiber cables 3a and 3b is judged by the presence / absence of disconnection of the optical fiber cable b and the presence / absence of the recovery of the optical fiber cable 3b, Since this is detected and the mode is immediately returned to the normal mode, it is possible to use an optical fiber without using hardware such as a supervisory information optical signal generator, a multiplexer, a demultiplexer, and a supervisory information optical signal detector. When the cables 3a, 3b and the like are broken, the transmission of the multiplexed optical signal can be stopped so that a strong optical signal is not emitted from the cross section of the broken optical fiber cable, for example, the optical fiber cable 3a. ,
When the repair of the broken optical fiber cable 3a is completed, this can be detected and the transmission of the multiplexed optical signal can be restarted, thereby ensuring high safety and restoring the optical fiber cable 3a. At the time
Communication can be resumed immediately (effect of claim 2).

(Third Embodiment) FIG. 6 shows a third embodiment of the optical transmission system according to the present invention, which corresponds to claim 3.
It is a block diagram showing. In this figure, the same parts as those in FIG. 1 are designated by the same reference numerals.

The optical transmission system 21 shown in this figure is different from the optical transmission system 1 shown in FIG. 1 in that a plurality of optical wavelength division multiplexing transmission equipment (WDM equipment) in which a predetermined period (T1) of each transponder section 4 is fixed. Instead of 2a and 2b, a plurality of optical wavelength division multiplex transmission devices (WDM devices) 2 each capable of adjusting a value of a predetermined period (T1) for each transponder unit 4
By using e and 2f, the operation tables 22 and 2 of FIGS.
As shown in FIG. 3, the optical signal output timing of each transponder unit 4 is adjusted by the recovery trial waiting mode provided between the normal mode, the suspended mode, the recovery trial mode, and the recovery confirmation mode. This is to prevent a plurality of wavelength optical signals from being output at the timing.

As described above, in the third embodiment, one of the optical fiber cables 3a and 3b is broken, and the transponder section 4 of each of the optical wavelength multiplex transmission devices 2e and 2f is broken.
When the wavelength optical signals are sequentially output from, the value of the predetermined period (T1) of each transponder unit 4 is adjusted so that the wavelength optical signals are not output from each transponder unit 4 at the same timing. When the optical fiber cables 3a, 3b, etc. are disconnected without using hardware such as a supervisory information optical signal generator, a multiplexer, a demultiplexer, and a supervisory information optical signal detector, the multiplexed optical signal is sent out. Can be stopped so that a strong optical signal is not emitted from the cross section of the broken optical fiber cable, and a multiplexed wavelength optical signal is emitted from the cross section of the broken optical fiber cable, for example, the optical fiber cable 3a. The optical fiber cable 3a is checked to see if the disconnection recovery has been completed. When Buru 3a of the repair has been completed,
It is possible to restart the transmission of the multiplexed optical signal, and thereby, while ensuring a high level of safety, it is possible to restart communication with the recovery of the optical fiber cable 3a (the effect of claim 3).

(Fourth Embodiment) FIG. 9 shows a fourth embodiment of the optical transmission system according to the present invention, which corresponds to claim 4.
It is a block diagram showing. In this figure, the same parts as those in FIG. 1 are designated by the same reference numerals.

The optical transmission system 31 shown in this figure differs from the optical transmission system 1 shown in FIG. 1 in that a plurality of optical wavelength division multiplex transmission equipment (WDM) from which a plurality of transponder units 4 and a plurality of retransponder units 7 are removed. Apparatus) 2g, 2h are used to output the wavelength λi (where i is 1, ..., And) from each optical transmitter 33 provided in one optical communication apparatus 32.
n wavelengths), the wavelength multiplexing signals are multiplexed by the wavelength multiplexing unit 5 provided in one optical wavelength multiplexing transmission device 2g, and then the wavelength multiplexing unit 5 of the optical wavelength multiplexing transmission device 2g → optical fiber cable. 3a to the demultiplexing unit 6 of the optical wavelength division multiplexing transmission device 2h, and sends it to the demultiplexing unit 6 of the other optical wavelength division multiplexing transmission device 2h to obtain the wavelength λi (where i is 1, ..., N).
(Any one of the above) is separated into optical signals of the respective wavelengths, and then the respective optical receivers 35 provided in the other optical communication device 34 respectively
The wavelength λi (where i is 1, is taken in and is output from each optical transmitter 36 provided in the optical communication device 34).
, N), each wavelength optical signal is multiplexed by the wavelength multiplexing unit 5 provided in the optical wavelength multiplexing transmission device 2h, and then the wavelength multiplexing unit 5 of the optical wavelength multiplexing transmission device 2h → optical fiber cable 3b to the demultiplexing unit 6 of the optical wavelength division multiplexing transmission device 2g, and sends it to the demultiplexing unit 6 of the optical wavelength division multiplexing transmission device 2g for each wavelength λi (where i is one of 1, ..., N). After being separated into the wavelength optical signals, the optical receivers 37 of the optical communication devices 32 are respectively loaded into the optical receivers 37 of the optical communication devices 32, and the optical receivers 35 of the optical communication devices 32 and 34,
37 is adapted to perform the disconnection detection operation of the optical fiber cables 3a and 3b and the disconnection recovery detection operation of the disconnected optical fiber cables 3a and 3b.

Thus, it is possible to support communication between a plurality of optical communication devices, such as an SDH device, which transmits and receives an optical signal of each wavelength of wavelength λi (where i is 1, ..., N). You can

As described above, in the fourth embodiment, each optical communication device 3 is controlled by each optical wavelength division multiplexing transmission device 2g, 2h.
Each optical communication device 3 while supporting the communication of 2, 34
By the respective optical receivers 35 and 37 provided in
Since the above-described disconnection detection operation of the optical fiber cables 3a and 3b and disconnection recovery detection operation of the disconnected optical fiber cables 3a and 3b are performed, the monitoring information optical signal generation unit, the multiplexing unit, the separation unit, the monitoring When the optical fiber cables 3a, 3b, etc. are disconnected without using hardware such as the information optical signal detector, the optical communication device 3
Capture processing of each wavelength optical signal emitted from 2, 34,
It is possible to stop the multiplexing process, the emission process for each optical fiber cable 3a, 3b, etc., and
When the repair of the broken optical fiber cable, for example, the optical fiber cable 3a is completed, this is detected, and the processing of capturing the optical signals of the respective wavelengths emitted from the respective optical communication devices 32, 34, the multiplexing processing, the optical fiber cable 3a, 3
It is possible to restart the emission processing for b and the like (effect of claim 4).

[0049]

As described above, according to the present invention, in the optical transmission system according to the present invention (Claim 1), the supervisory information optical signal generator, the multiplexer, the demultiplexer and the supervisory information optical signal detector are provided. When the optical fiber cable is broken without using such hardware, it is possible to stop the transmission of the multiplexed optical signal so that a strong optical signal is not emitted from the cross section of the broken optical fiber cable. At the same time, when the repair of the broken optical fiber cable is completed, this can be detected, and when the repair is confirmed, the transmission of the multiplexed optical signal can be restarted, which provides high safety. It is possible to resume communication with the recovery of the optical fiber cable while ensuring the security.

Further, in the optical transmission system according to the present invention (claim 2), the optical information is transmitted without using the hardware such as the supervisory information optical signal generator, the multiplexer, the demultiplexer and the supervisory information optical signal detector. When the fiber cable is broken, the transmission of the multiplexed optical signal can be stopped to prevent the strong optical signal from being emitted from the cross section of the broken optical fiber cable, and the broken optical fiber cable can be repaired. When it is finished, it can be detected and the transmission of the multiplexed optical signal can be restarted, thereby ensuring high safety and restarting the communication when the optical fiber cable is restored. it can.

Further, in the optical transmission system according to the present invention (claim 3), the optical information is transmitted without using the hardware such as the supervisory information optical signal generator, the multiplexer, the demultiplexer and the supervisory information optical signal detector. When the fiber cable is broken, the transmission of the multiplexed optical signal can be stopped to prevent the strong optical signal from being emitted from the cross section of the broken optical fiber cable, and also from the cross section of the broken optical fiber cable. Checking whether the disconnection recovery of the optical fiber cable has been completed while preventing the output of the multiplexed wavelength optical signal, and sending out the multiplexed optical signal when the recovery of the disconnected optical fiber cable is completed. It is possible to restart the communication, which ensures communication with the recovery of the optical fiber cable while ensuring high safety. Can can.

Further, in the optical transmission system according to the present invention (Claim 4), the optical information is transmitted without using hardware such as the supervisory information optical signal generator, the multiplexer, the demultiplexer, and the supervisory information optical signal detector. When the fiber cable is broken, it is possible to stop the acquisition process, the multiplexing process, the emission process for the optical fiber cable of each wavelength optical signal emitted from the transmitter, and the repair of the broken optical fiber cable is completed. At this time, by detecting this, it is possible to restart the process of taking in each wavelength optical signal emitted from the transmitter, the multiplexing process, the emission process for the optical fiber cable, and the like.

[Brief description of drawings]

FIG. 1 is a block diagram of an optical transmission system according to the present invention.
3 is a block diagram showing Embodiment 1 corresponding to FIG.

FIG. 2 is a diagram showing an operation example of the optical transmission system shown in FIG.

FIG. 3 is a timing chart showing an operation timing example of each transponder unit and each retransponder unit of the optical transmission system shown in FIG.

FIG. 4 is a schematic diagram of an optical transmission system according to the present invention;
It is a block diagram showing Embodiment 2 corresponding to.

5 is a diagram showing an operation example of the optical transmission system shown in FIG.

FIG. 6 is a schematic diagram of an optical transmission system according to the present invention;
It is a block diagram which shows Embodiment 3 corresponding to.

7 is a diagram showing an operation example of the optical transmission system shown in FIG.

8 is a diagram showing an operation example of the optical transmission system shown in FIG.

FIG. 9 is a view showing an optical transmission system according to the present invention;
It is a block diagram which shows Embodiment 4 corresponding to.

FIG. 10 is a block diagram showing an example of a conventionally known optical transmission system.

[Explanation of symbols]

1 Optical transmission system 2a Optical wavelength division multiplexing transmission device 2b Optical WDM transmission device 2c Optical WDM transmission device 2d optical WDM transmission device 2e Optical wavelength division multiplexer 2f Optical WDM transmission device 2g Optical WDM transmission equipment 2h Optical wavelength division multiplexer 3a optical fiber cable 3b optical fiber cable 4 Transponder section 5 Wavelength multiplexer 6 demultiplexer 7 Retransponder part 8 operation table 11 Optical transmission system 12 operation table 21 Optical transmission system 22 Operation table 23 Operation table 31 Optical transmission system 32 Optical communication device (optical transmitter, optical receiver) 33 Optical transmitter 34 Optical communication device (optical transmitter, optical receiver) 35 Optical receiver 36 Optical transmitter 37 Optical receiver

Claims (4)

[Claims] 1. An optical wavelength division multiplex transmission apparatus multiplexes each wavelength optical signal and makes it enter one end of an optical fiber cable, and the other optical wavelength division multiplexing transmission apparatus separates it from the other end of the optical fiber cable. In an optical transmission system that captures a multiplexed optical signal to be emitted and separates it into optical signals of each wavelength, when the optical signal of each wavelength is no longer emitted from the optical fiber cable, the optical fiber cable is disconnected. The optical fiber cable is judged within the monitoring time (T2) while allowing each wavelength optical signal to enter one end of the optical fiber cable for each predetermined period (T1) in each wavelength unit for a predetermined time. It is checked whether each wavelength optical signal is emitted from the other end, and each wave is output from the other end of the optical fiber cable for a predetermined time (T3). When the optical signal is emitted, an optical transmission system, characterized in that the disconnection recovery by determined to be the end of the optical fiber cable, and resumes the communication process using the respective wavelength optical signals. 2. An optical wavelength multiplex transmission apparatus multiplexes each wavelength optical signal and makes it enter one end of the optical fiber cable, and the other optical wavelength multiplex transmission apparatus makes the optical fiber cable from the other end of the optical fiber cable. In an optical transmission system that captures a multiplexed optical signal to be emitted and separates it into optical signals of each wavelength, when the optical signal of each wavelength is no longer emitted from the optical fiber cable, the optical fiber cable is disconnected. The optical fiber cable is judged within the monitoring time (T2) while allowing each wavelength optical signal to enter one end of the optical fiber cable for each predetermined period (T1) in each wavelength unit for a predetermined time. It is checked whether each wavelength optical signal is emitted from the other end, and each wavelength optical signal is emitted from the other end of the optical fiber cable. Can, by determining the disconnection restoration of the optical fiber cable is terminated, the optical transmission system characterized by resuming the communication process using the respective wavelength optical signals. 3. The predetermined cycle (T) for each wavelength optical signal.
3. The optical transmission system according to claim 1, wherein 1) is adjusted to shift the emission timing of each wavelength optical signal. 4. Each optical wavelength division multiplexing transmission device multiplexes each wavelength optical signal emitted from an optical transmission device and makes it enter one end of the optical fiber cable, or the other end of the optical fiber cable. The optical transmission system according to any one of claims 1 to 3, wherein the multiplexed optical signal emitted from the optical fiber is taken in, separated into optical signals of respective wavelengths, and made to enter the optical receiving device. .