JP3967198B2 - Transmission apparatus, transmission system, transmission method, transmission program, and computer-readable recording medium recording the transmission program - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
An object of the present invention is to provide a stable single fiber bidirectional optical wavelength division multiplexing transmission.
[0002]
[Prior art]
A conventional single fiber bidirectional optical wavelength division multiplexing transmission system will be described.
FIG. 11 is a block diagram of a general single fiber bidirectional optical wavelength division multiplexing transmission system.
1a is an upstream wavelength multiplexed signal and 1b is a downstream wavelength multiplexed signal.
Reference numerals 10a and 10b are wavelength multiplexing terminals, and 20a is a relay station. The relay station 20a may not be provided, and a plurality of stations may be installed.
Reference numerals 30 and 31 denote single-core optical transmission lines connecting the wavelength division multiplexing terminal station 10a, the wavelength division multiplexing terminal station 10b, and the relay station 20a.
Reference numerals 40a and 40b denote optical amplifiers installed at the wavelength multiplexing terminal station 10a and the wavelength multiplexing terminal station 10b, for amplifying the upstream wavelength multiplexing signal 1a.
41a and 41b are optical amplifiers installed at the wavelength multiplexing terminal station 10a and the wavelength multiplexing terminal station 10b for amplifying the downstream wavelength multiplexing signal 1b.
Similarly, 42 and 43 are optical amplifiers installed in the relay station 20a, and optically amplify the upstream wavelength multiplexed signal 1a and downstream wavelength multiplexed signal 1b, respectively. The optical amplifier 40a, the optical amplifier 40b, the optical amplifier 41a, and the optical amplifier 41b may not be installed depending on the system.
Reference numerals 50a and 50b denote directional couplers installed in the wavelength multiplexing terminal station 10a and the wavelength multiplexing terminal station 10b, for coupling the upstream wavelength multiplexed signal 1a and the downstream wavelength multiplexed signal 1b to one optical fiber. .
Similarly, 51 and 52 are directional couplers installed in the relay station 20a.
Reference numerals 60a and 60b are optical transmitters, and reference numerals 61a and 61b are optical receivers.
Reference numerals 70a and 70b denote multiplexers, which combine wavelengths from a plurality of optical transmitters 60a and 60b to form wavelength multiplexed signals.
Reference numerals 71a and 71b denote demultiplexers, which demultiplex wavelength-multiplexed signals into wavelengths and transmit signals to the optical receiver 61a and the optical receiver 61b.
[0003]
Next, the operation will be described.
In the wavelength multiplexing terminal station 10a, the optical signal output from the optical transmitter 60a is multiplexed by the multiplexer 70a.
The multiplexed upstream wavelength multiplexed signal 1a is amplified as upstream wavelength multiplexed signal light by the optical amplifier 40a, transmitted to the transmission line 30 by the directional coupler 50a, and input to the relay station 20a.
The input upstream wavelength multiplexed signal 1a is transmitted to the optical amplifier 42 by the directional coupler 51 of the relay station 20a, optically amplified, and then transmitted to the transmission line 31 by the directional coupler 52 as well. Input to the station 10b.
In the wavelength multiplexing terminal station 10b, the signal is transmitted to the optical amplifier 40b by the directional coupler 50b, amplified by the optical amplifier 40b, wavelength-separated by the demultiplexer 71b, and received by the optical receiver 61b.
The downstream wavelength multiplexed signal 1b is also transmitted from the wavelength multiplexed terminal station 10b to the wavelength multiplexed terminal station 10a in the same procedure as the upstream wavelength multiplexed signal 1a.
[0004]
In such a single-fiber bidirectional optical wavelength division multiplexing transmission system, one of the effects of signal wraparound in reflection at the transmission path or connector end is that light breakage detection cannot be performed. In other words, if there is a reflection end due to the transmission line being cut off at the near end of the directional coupler, the wavelength multiplexed signal reflected there leaks to the opposite side opposite to the transmission direction. In spite of the fact that the signal was input, the light break detection could not be performed.
For example, when disconnection occurs in the transmission line 31, due to Fresnel reflection at the disconnection portion, the upstream wavelength multiplexed signal 1a is transmitted to the optical amplifier 43 instead of the downstream wavelength multiplexed signal 1b, and the upstream wavelength multiplexed signal 1a is transmitted to the optical amplifier 40b. Instead, the downstream wavelength multiplexed signal 1b is reflected, and there is a problem in that an alarm for a light interruption signal cannot be issued.
[0005]
As an example of a solution to this problem, FIG. 12 shows a single-core bidirectional optical wavelength division multiplexing transmission system proposed in Japanese Patent Laid-Open No. 2-127929.
In FIG. 12, 1a is an upstream wavelength multiplexed signal and 1b is a downstream wavelength multiplexed signal.
The optical transmission circuit 60c superimposes the optical interruption detection signal of frequency f1 on the transmission signal by the optical interruption detection signal (f1) superimposing circuit 72, and transmits the signal as the upstream wavelength multiplexed signal 1a.
The optical transmission circuit 60d superimposes the optical interruption detection signal of the frequency f2 on the transmission signal by the optical interruption detection signal (f2) superposition circuit 75, and transmits the signal as the downstream wavelength multiplexed signal 1b.
The optical receiving circuit 61d receives the upstream wavelength multiplexed signal 1a, and the optical break detection signal (f1) detecting circuit 74 detects the presence / absence of the frequency f1 in the upstream wavelength multiplexed signal 1a received by the optical receiving circuit 61d.
The optical receiving circuit 61c receives the downstream wavelength multiplexed signal 1b, and the optical break detection signal (f2) detecting circuit 73 detects the presence or absence of the frequency f2 in the downstream wavelength multiplexed signal 1b received by the optical receiving circuit 61c.
In addition, 30 is a transmission line, 50c and 50d are directional couplers.
[0006]
As described above, conventionally, a method as shown in FIG. 12 has been considered as a method for solving the problem concerning the signal wraparound in the reflection of the transmission line or the connector end. That is, in the technique of FIG. 12, the light interruption detection signal (f1) superimposing circuit 72 and the light interruption detecting signal (f2) superposition circuit 75 are used to generate a frequency f1 specific to the upstream wavelength multiplexed signal 1a and a frequency inherent to the downstream wavelength multiplexed signal 1b. The frequency f2 is superimposed on each other, and the light reception circuit 61d and the light reception circuit 61c monitor the frequency f1 and the frequency f2 with the light interruption detection signal (f2) detection circuit 74 and the light interruption detection signal (f1) detection circuit 73, respectively. As a result, the light break signal is detected.
By this method, even when there is reflected light due to the reflection as described above, it is possible to detect light breakage because the frequency of the received signal is different.
[0007]
[Problems to be solved by the invention]
As described above, the conventional single-core bidirectional optical wavelength division multiplexing transmission system having the above-described configuration has a problem that the light break cannot be detected due to the influence of the reflected light from the reflection point and the reflection end.
Therefore, as in the example shown in FIG. 12, the upstream wavelength multiplexed signal 1a and the downstream wavelength multiplexed signal 1b are superimposed with their own frequencies (f1, f2), and the respective frequencies are detected on the receiving side. The problem was avoided by detecting disconnection.
[0008]
However, in practice, there is a problem due to reflected light in addition to the problem of light break detection. For example, when there is a reflection point on the transmission path, the influence of the reflected light always occurs, so that the signal output from the own station always returns to the own station as reflected light. This reflected light becomes a factor that degrades transmission quality as noise, and cannot be solved by the conventional method as shown in FIG.
Further, as the number of wavelength multiplexing increases, the output of the optical amplifier also increases by the number of wavelength multiplexing. Therefore, the reflected light level is relatively increased. For example, if the reflection point in the transmission line 31 is in the vicinity of the relay station 20a, there is almost no influence of the transmission line loss of the reflected light. The input may exceed the saturation level of the optical amplifier. In that case, the gain deviation of the optical amplifier becomes large, and there is an influence such as S / N (SIGNAL / NOISE) degradation. These adverse effects could not be solved by the conventional method.
Further, when the reflected light from the reflection point exists in both the transmission path 30 and the transmission path 31, for example, the upstream wavelength multiplexed signal 1a passes through the directional coupler 52 due to the reflection on the transmission path 31. The upstream wavelength multiplexed signal 1a of the reflected light that has been input to the amplifier 43 and optically amplified by the optical amplifier 43 is now returned by reflection on the transmission path 30, and is input to the optical amplifier 42 by the directional coupler 51, and the optical Multiple reflections through the optical amplifier, which are optically amplified by the amplifier 42 and then transmitted to the transmission line 31, occur. This phenomenon greatly affects the deterioration of transmission quality, but cannot be solved by the conventional method as shown in FIG.
In addition, the conventional technique shown in FIG. 12 requires a light break detection superposition circuit and a light break detection signal detection circuit, and when there are a plurality of transmitters and receivers as in wavelength multiplexing communication, the number of them is as follows: Since a light interruption detection superimposing circuit and a light interruption detection signal detection circuit are required, there are problems that the cost is increased and the circuit scale is increased.
[0009]
Next, the case where a Raman amplifier is introduced into a single fiber bidirectional optical wavelength division multiplexing transmission system will be described.
FIG. 13 is a configuration diagram of a one-fiber bidirectional optical wavelength division multiplexing transmission system using a Raman amplifier.
In this case, the optical amplifier 40a, the optical amplifier 40b, the optical amplifier 41a, and the optical amplifier 41b shown in FIG. 11 are not used.
When performing Raman amplification by a Raman amplifier, a Raman amplifier 44a having a high-power 1.48 μm band Raman amplification pumping light source generates 1.48 μm band pumping light 1f and generates a high output 1.48 μm band light. The Raman amplifier 44b having a Raman amplification pumping light source needs to generate 1.48 μm band pumping light 1e and input the generated pumping light 1f and pumping light 1e to the transmission line 30. Reference numerals 87a and 87b denote WDM couplers for combining the pumping light 1e and pumping light 1f for Raman amplification and the respective optical wavelength multiplexed signals.
Even in this case, the reflected light of the 1.48 μm band pumping light 1e or 1.48 μm band pumping light 1f is transmitted to the opposite side by the directional coupler 50a and the directional coupler 50b because of the influence of the reflection of the transmission path. It leaks. For example, when there is a reflection end in the transmission line 30, the excitation light 1e leaks to the opposite side by the directional coupler 50b and is received by the optical receiver 61b.
This has been a factor that degrades transmission quality as noise.
[0010]
As described above, there are various problems in the conventional single-fiber bidirectional optical wavelength division multiplexing communication system, and the conventional methods described above cannot solve all of them.
[0011]
The present invention has a simple configuration and suppresses the influence of reflected light on the system, which is peculiar to single-fiber bidirectional optical wavelength division multiplexing transmission, in the transmission line or at the reflection of the connector end, and single-fiber bidirectional light with stable transmission quality. The object is to provide wavelength division multiplexing.
[0012]
[Means for Solving the Problems]
The transmission apparatus according to the present invention inputs the combined first optical signal and the second optical signal, and flows in a predetermined direction from the input first optical signal and second optical signal. A demultiplexer that demultiplexes and outputs,
An optical filter that transmits one of the first optical signal and the second optical signal from the optical signal output by the duplexer and blocks the other of the first optical signal and the second optical signal; It is characterized by providing.
[0013]
The transmission apparatus includes a first duplexer and a second duplexer as the duplexer,
The transmission apparatus includes a first optical filter and a second optical filter as the optical filter,
The first optical filter and the second optical filter are provided between the first duplexer and the second duplexer,
The first demultiplexer demultiplexes the optical signal flowing in the first direction from the combined first optical signal and second optical signal, and outputs the demultiplexed optical signal to the first optical filter,
The first optical filter transmits the first optical signal from the input optical signal and blocks the second optical signal to output the first optical signal to the second duplexer;
The second demultiplexer transmits the first optical signal output by the first optical filter, and in the first direction from the combined first optical signal and second optical signal. And demultiplexes the optical signal flowing in the opposite direction to the second optical filter,
The second optical filter transmits the second optical signal from the input optical signal and blocks the first optical signal to output the second optical signal to the first duplexer.
The first duplexer transmits the second optical signal output by the second optical filter.
[0014]
The transmission apparatus further includes:
A light break detector is provided that detects a light break by monitoring either one of the first light signal and the second light signal transmitted by the optical filter.
[0015]
The duplexer receives the combined first optical signal, the second optical signal, and the control signal, and determines a predetermined direction from the input first optical signal, second optical signal, and control signal. Demultiplexing and outputting the optical signal and control signal flowing through
The transmission apparatus further includes:
A control signal demultiplexer provided between the demultiplexer and the optical filter, which demultiplexes the optical signal from the optical signal output from the demultiplexer and the control signal, and outputs the demultiplexed optical signal to the optical filter. It is characterized by comprising a waver.
[0016]
The transmission apparatus further includes:
An optical amplifier that amplifies one of the first optical signal and the second optical signal transmitted by the optical filter is provided.
[0017]
The duplexer is any one of a directional coupler, an optical filter, and a coupler.
[0018]
The transmission apparatus further includes:
A first optical signal that is provided between the first optical filter and the second duplexer and is transmitted through the first optical filter is input, and a predetermined one of the input first optical signals is input. A first optical add / drop module for demultiplexing an optical signal having a wavelength of
The second optical signal is provided between the second optical filter and the first duplexer and is transmitted through the second optical filter. Among the input second optical signals, the second optical signal is input. A second optical add / drop module that demultiplexes an optical signal having a different wavelength from the optical signal having a predetermined wavelength demultiplexed by the first optical add / drop module and outputs the demultiplexed optical signal to the first branching device. It is characterized by providing.
[0019]
The transmission apparatus further includes:
A Raman amplifier that generates a pumping light signal and amplifies the generated pumping light signal;
A multiplexer for multiplexing the pumping optical signal amplified by the Raman amplifier into the first optical signal and the second optical signal;
The demultiplexer demultiplexes an optical signal flowing in a predetermined direction and an excitation light signal from the first optical signal, the second optical signal, and the excitation light signal multiplexed by the multiplexer. Output to the filter,
The optical filter transmits either one of the first optical signal and the second optical signal from the input optical signal and the excitation optical signal, and either the first optical signal or the second optical signal. It is characterized by blocking the excitation light signal.
[0020]
A transmission system according to the present invention is a transmission system comprising a plurality of transmission devices,
Each transmission device of the plurality of transmission devices includes a first duplexer, a second duplexer, a first optical filter, and a second optical filter,
The first optical filter and the second optical filter are provided between the first duplexer and the second duplexer,
The first duplexer inputs a first optical signal and a second optical signal multiplexed by another transmission device of the plurality of transmission devices, and inputs the input first optical signal and second optical signal. The optical signal flowing in the first direction from the optical signal is demultiplexed and output to the first optical filter,
The first optical filter transmits the first optical signal from the input optical signal and blocks the second optical signal to output the first optical signal to the second duplexer;
The second duplexer transmits the first optical signal output from the first optical filter to another transmission device of the plurality of transmission devices, and the other transmission device of the plurality of transmission devices. The first optical signal and the second optical signal combined by the optical signal are input, and an optical signal flowing in a direction opposite to the first direction is input from the input first optical signal and second optical signal. Demultiplexed and output to the second optical filter,
The second optical filter transmits the second optical signal from the input optical signal and blocks the first optical signal to output the second optical signal to the first duplexer.
The first demultiplexer transmits the second optical signal output by the second optical filter to another transmission device of the plurality of transmission devices.
[0021]
In the transmission method according to the present invention, the combined first optical signal and second optical signal are input, and the optical signal flowing in a predetermined direction from the input first optical signal and second optical signal. Demultiplexed and output,
One of the first optical signal and the second optical signal is transmitted from the output optical signal, and the other of the first optical signal and the second optical signal is blocked.
[0022]
The transmission program according to the present invention inputs a combined first optical signal and a second optical signal, and an optical signal that flows in a predetermined direction from the input first optical signal and second optical signal Processing to demultiplex and output,
Causes the computer to execute a process of transmitting either the first optical signal or the second optical signal from the output optical signal and blocking the other of the first optical signal and the second optical signal. It is characterized by that.
[0023]
A computer-readable recording medium on which a transmission program according to the present invention is recorded inputs a combined first optical signal and a second optical signal, and inputs the input first optical signal and second optical signal. The optical signal flowing in a predetermined direction from the first optical signal, and outputting the first optical signal and the second optical signal from the output optical signal, It is a computer-readable recording medium recording a transmission program for causing a computer to execute a process of blocking either one of the second optical signals.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
The first embodiment will be described with reference to FIG.
FIG. 1 is a configuration diagram illustrating a single-fiber bidirectional optical wavelength division multiplex transmission system according to a first embodiment.
In FIG. 1, 10a and 10b are wavelength multiplexing terminal stations, 20a is a relay station, and the wavelength multiplexing terminal station 10a, the wavelength multiplexing terminal station 10b, and the relay station 20a are examples of transmission apparatuses that transmit optical signals.
Reference numerals 80a, 80b, 82, and 83 denote optical filters that transmit the band of the upstream wavelength multiplexed signal 1a and cut the band of the downstream wavelength multiplexed signal 1b.
Reference numerals 81a, 81b, 84, and 85 denote optical filters that transmit the band of the downstream wavelength multiplexed signal 1b and cut the upstream wavelength multiplexed signal 1a.
The wavelength bands of the upstream wavelength multiplexed signal 1a and the downstream wavelength multiplexed signal 1b include, for example, the C band and L band in the 1.5 μm band, the BLUE band and RED band in the C band, the BLUE band and RED band in the L band, and the like. Can be mentioned.
The upstream wavelength multiplexed signal 1a and the downstream wavelength multiplexed signal 1b cut the bandwidth of the upstream wavelength multiplexed signal 1a, the optical filter 80a, the optical filter 80b, the optical filter 82, and the optical filter 83 that cut the bandwidth of the downstream wavelength multiplexed signal 1b. Using the optical filter 81a, the optical filter 81b, the optical filter 84, and the optical filter 85, they are separated by cutting each other's band. The wavelength bands of the upstream wavelength multiplexed signal 1a and the downstream wavelength multiplexed signal 1b are such that isolation of, for example, 17 dB or more can be obtained.
Reference numerals 90a, 90b, 91, and 92 denote a directional coupler 50a, a directional coupler 50b, a directional coupler 51, and a directional coupler 52, respectively, from an optical amplifier 41a, an optical amplifier 40b, an optical amplifier 42, and an optical amplifier. This is a light break detector that monitors the light level input to 43 and detects light break.
Other configurations are the same as those of the conventional example shown in FIG.
Further, a plurality of relay stations 20a may or may not be arranged on a transmission line connecting between the wavelength multiplexing terminal station 10a and the wavelength multiplexing terminal station 10b.
[0025]
Next, the operation will be described.
The operation is basically the same as in the conventional example.
However, the optical filter 80a, the optical filter 80b, the optical filter 81a, the optical filter 81b, and the optical filter 82 to the optical filter 85 that transmit only a specific wavelength band are arranged at the positions shown in FIG. When there is a reflection point at 30, the influence of noise due to the reflected light can be suppressed. That is, when there is a reflection point on the transmission line 30, the upstream wavelength multiplexed signal 1a returns to the wavelength multiplexing terminal station 10a by reflection and is input to the optical amplifier 41a by the directional coupler 50a. At this time, the band of the upstream wavelength multiplexed signal 1a is cut by the optical filter 81a, and only the band of the downstream wavelength multiplexed signal 1b is transmitted. Therefore, the reflected light of the upstream wavelength multiplexed signal 1a is not input to the optical amplifier 41a. Further, since the downstream wavelength multiplexed signal 1b is transmitted through the optical filter 81a, it can be received by the optical receiver 61a after being input to the optical amplifier 41a and separated by the demultiplexer 71a.
[0026]
Further, when the transmission line is broken in the transmission line 30 or the connector is disconnected, reflection from the end face occurs, the downstream wavelength multiplexed signal 1b is cut off, and transmission to the optical amplifier 41a is stopped. It is done.
In this case, light break detection could not be performed conventionally, but in the wavelength multiplexing terminal station 10a in the present embodiment, the reflected light of the upstream wavelength multiplexed signal 1a is transmitted to the optical amplifier 41a by the directional coupler 50a. Sometimes, the optical filter 81a disposed between the optical amplifier 41a and the directional coupler 50a cuts the upstream wavelength multiplexed signal 1a, so that the optical break detector 90a can detect the light break.
[0027]
As described above, the transmission path 30 of the single optical fiber, the wavelength multiplexed signal light having different wavelength bands opposed to each other, and the directional coupler (50a or the like) for coupling the opposite wavelength multiplexed signal light to the optical fiber are transmitted. A single fiber bidirectional optical wavelength division multiplexing transmission system has been described that includes an optical filter (80a or the like) that transmits the wavelength multiplexed signal light band in the direction and cuts the opposite wavelength multiplexed signal light band.
[0028]
As described above, in the single-core bidirectional optical wavelength division multiplexing transmission system of this embodiment, the signal of the reflection end in the transmission line or the noise due to the reflected light at the connector end, which is peculiar to the single-fiber bidirectional optical wavelength division multiplexing transmission system. Various adverse effects of reflection on the system can be suppressed, and stable single fiber bidirectional optical wavelength division multiplexing transmission can be provided.
That is, the optical filter 80a, the optical filter 80b, the optical filter 81a, the optical filter 81b, the optical filter 82 to the optical filter 85 that separate the wavelength bands of the upstream wavelength multiplexed signal 1a and the downstream wavelength multiplexed signal 1b and transmit only the wavelength band. Is added to the directional coupler 50a, the directional coupler 50b, the directional coupler 51, and the directional coupler 52, the influence of reflected light can be suppressed. Therefore, the input level can be collectively monitored by the light break detector 90a, the light break detector 90b, the light break detector 91, and the light break detector 92 regardless of the number of wavelengths.
[0029]
Embodiment 2. FIG.
FIG. 2 is a diagram showing a configuration of a single-fiber bidirectional optical wavelength division multiplexing transmission system according to the second embodiment, which is characterized in that supervisory control light, which is a control signal, is wavelength multiplexed with a main signal and transmitted. The upstream monitoring control signal 1c is combined with the upstream wavelength multiplexed signal 1a by the WDM coupler 93a and transmitted to the next station. The upstream monitoring control signal 1c is a wavelength in a wavelength band that is transmitted by the optical filter 80a and cut by the optical filter 81a. Similarly, the downlink supervisory control signal 1d is combined with the downlink wavelength multiplexed signal 1b by the WDM coupler 94b and transmitted to the next station. The downlink monitoring control signal 1d is a wavelength in a wavelength band that is transmitted by the optical filter 81b and cut by the optical filter 80b. The supervisory control signal combined with the main signal is demultiplexed from the main signal by the WDM coupler 95, WDM coupler 93b, WDM coupler 98, and WDM coupler 94a of the next station. Other configurations are the same as those in the first embodiment.
The WDM coupler 95, the WDM coupler 93b, the WDM coupler 98, and the WDM coupler 94a are examples of control signal demultiplexers. The monitoring control signal 1c and the monitoring control signal 1d are examples of control signals.
[0030]
In the second embodiment, the information of the wavelength multiplexing terminal station 10a, the wavelength multiplexing terminal station 10b, and the relay station 20a is raised to the upper level, or conversely, supervisory control light for performing control from the higher level to each station is transmitted. Shows about. The influence of the reflection point in the transmission path is the same as that of the main signal in the supervisory control light, and the same effect as in the first embodiment can be obtained.
[0031]
Embodiment 3 FIG.
FIG. 3 is a diagram showing a configuration of a single-fiber bidirectional optical wavelength division multiplexing system according to the third embodiment.
This embodiment is characterized in that no optical amplifier exists in the wavelength division multiplexing terminal station 10a and the wavelength division multiplexing terminal station 10b.
Other configurations are the same as those in the first embodiment. Further, there may or may not be a plurality of relay stations 20a in the transmission line 30.
In the third embodiment, the operation is the same as that in the first embodiment.
[0032]
Therefore, even in such a system configuration in which no optical amplifier exists, the same effect as in the first embodiment can be obtained.
[0033]
Embodiment 4 FIG.
FIG. 4 is a diagram showing a configuration of a single fiber bidirectional optical wavelength division multiplexing system according to the fourth embodiment.
In the present embodiment, there are a monitoring control signal 1c for the upstream signal wavelength band and a monitoring control signal 1d for the downstream signal wavelength band, and there are a WDM coupler 93a, a WDM coupler 93b, a WDM coupler 94a, and a WDM coupler 94b. An optical amplifier is not present in the wavelength division multiplexing terminal station 10b. The monitoring control signal 1c and the monitoring control signal 1d are examples of control signals.
Other configurations are the same as those in the second embodiment. There may or may not be a plurality of relay stations 20a in the transmission line 30.
In the fourth embodiment, the operation is basically the same as that in the second embodiment.
However, an operation is added to multiplex the supervisory control signal 1c and the upstream wavelength multiplexed signal 1a by the WDM coupler 93a and demultiplex the supervisory control signal 1c and the upstream wavelength multiplexed signal 1a by the WDM coupler 93b. In addition, an operation of adding the monitoring control signal 1d and the downstream wavelength multiplexed signal 1b by the WDM coupler 94b and demultiplexing the monitoring control signal 1d and the downstream wavelength multiplexed signal 1b by the WDM coupler 94a is added.
Therefore, the directional coupler 50 a receives the monitoring control signal 1 c multiplexed by the WDM coupler 93 a and the uplink wavelength multiplexed signal 1 a and outputs them to the transmission line 30.
The directional coupler 50b receives the supervisory control signal 1c and the upstream wavelength multiplexed signal 1a. If there is reflected light from the downstream wavelength multiplexed signal 1b, it also receives the downstream wavelength multiplexed signal 1b and transmits it in the upstream direction. Only the flowing optical signal is demultiplexed and output.
The output optical signal is demultiplexed into the supervisory control signal 1c and the upstream wavelength multiplexed signal 1a by the WDM coupler 93b, and further, the upstream wavelength multiplexed signal 1a is transmitted by the optical filter 80b and the downstream wavelength multiplexed signal 1b is cut off. .
[0034]
With the above operation, even in a system configuration in which the monitoring control signal 1c and the monitoring control signal 1d exist, the same effect as that of the first embodiment can be obtained.
[0035]
Embodiment 5 FIG.
FIG. 5 is a diagram showing a configuration of a single fiber bidirectional optical wavelength division multiplexing transmission system according to the fifth embodiment.
This embodiment is characterized in that a WDM coupler is used instead of the directional coupler.
Each WDM coupler has a function of multiplexing or demultiplexing the upstream wavelength multiplexed signal 1a and the downstream wavelength multiplexed signal 1b.
Other configurations are the same as those in the first embodiment.
There may or may not be a plurality of relay stations 20a in the transmission path 30 and the transmission path 31. Similarly to the third embodiment, the wavelength division multiplexing terminal station 10a and the wavelength division multiplexing terminal station 10b may or may not include an optical amplifier.
[0036]
In the fifth embodiment, the WDM coupler performs the same function as the directional coupler shown in the first embodiment. Therefore, the operation is the same as in the first embodiment.
Therefore, even in such a system configuration, the same effect as in the first embodiment can be obtained.
[0037]
Embodiment 6 FIG.
FIG. 6 is a diagram showing a configuration of a single fiber bidirectional optical wavelength division multiplexing system according to the sixth embodiment.
In the present embodiment, supervisory control light is transmitted in the same manner as the main signal as in the fourth embodiment, and a WDM coupler is used in the same manner as in the fifth embodiment in place of the directional coupler. It is characterized by.
Other configurations are the same as those in the second embodiment.
There may or may not be a plurality of relay stations 20a in the transmission path 30 and the transmission path 31.
[0038]
In the sixth embodiment, the operation is basically the same as that in the second embodiment.
Therefore, also in such a system configuration, as in the second embodiment, the information of the wavelength multiplexing terminal station 10a, the wavelength multiplexing terminal station 10b, and the relay station 20a is given to the upper level, or conversely, control from the higher level to each station, etc. The influence of the reflection point during transmission of the supervisory control light for performing the same is similar to that of the main signal in the supervisory control light, and therefore the same effect as in the first embodiment can be obtained.
[0039]
Embodiment 7 FIG.
FIG. 7 is a diagram showing a configuration of a single-fiber bidirectional optical wavelength division multiplexing transmission system according to the seventh embodiment.
The present embodiment is characterized in that the transmission path is a ring type.
In the ring type single fiber bidirectional optical wavelength division multiplexing transmission system, communication can be performed between nodes connected by the ring 32a to the ring 32c. 10c indicates a master node, and 21a, 21b, and 21c indicate slave nodes.
FIG. 8 shows an example of a configuration diagram of the slave node. The slave node is characterized in that an optical add / drop module capable of multiplexing / demultiplexing only a specific wavelength, such as 56a and 56b, is installed, and the others are the configurations shown in the relay station 20a of the second embodiment. It is the same.
There may be a plurality of optical add / drop modules. Further, the optical amplifier 42, the optical amplifier 43, the WDM coupler 95, the WDM coupler 96, the WDM coupler 97, and the WDM coupler 98 may be omitted. Further, instead of the directional coupler 51 and the directional coupler 52, a WDM coupler 54 and a WDM coupler 55 may be used.
Also in such a ring-type single-core bidirectional optical wavelength division multiplexing transmission system, the upstream wavelength multiplexed signal 1a and the downstream wavelength multiplexed signal 1b are assigned to the clockwise signal wavelength band and the counterclockwise signal wavelength band, respectively. Similarly, the clockwise monitoring control light and the counterclockwise monitoring control light are assigned the uplink monitoring control signal 1c and the downlink monitoring control signal 1d. Other configurations are the same as those in the first embodiment.
There may or may not be a plurality of slave nodes 21a, slave nodes 21b, and slave nodes 21c in the transmission path.
[0040]
In the seventh embodiment, the basic operation is the same as that in the second embodiment.
Therefore, even in such a ring type system configuration, the same effect as that of the first embodiment can be obtained.
[0041]
Embodiment 8 FIG.
FIG. 9 is a diagram showing a configuration of a single fiber bidirectional optical wavelength division multiplexing transmission system according to the eighth embodiment.
This embodiment is characterized by having a Raman amplifier.
Reference numeral 44b denotes a Raman amplifier including an excitation light source for Raman amplification, and a plurality of Raman amplifiers may be provided.
1e is pumping light (laser light) output from the Raman amplification pumping light source of the Raman amplifier 44b.
Reference numeral 87b denotes a WDM coupler that combines the Raman amplification pumping light (pumping light) and the upstream wavelength multiplexed signal 1a. The WDM coupler 87b is an example of a multiplexer.
80b is characterized by blocking the excitation light source for Raman amplification and has the same performance as the optical filter shown in the first embodiment (transmits the upstream wavelength multiplexed signal 1a and blocks the downstream wavelength multiplexed signal 1b). It is an optical filter.
The optical amplifier 40b and the optical amplifier 41b may be omitted. The directional coupler 50b may be a WDM coupler.
In this eighth embodiment, the operation is the same as in the second embodiment.
[0042]
The single fiber bidirectional optical wavelength division multiplexing transmission system including the Raman amplifier 44b and the optical filter 80b that cuts the wavelength band of the excitation light source used for Raman amplification has been described above.
[0043]
According to the single fiber bidirectional optical wavelength division multiplexing transmission system of the present embodiment, in the single fiber bidirectional optical wavelength division multiplexing transmission system using the Raman amplifier 44b, the reflection of the pumping light 1e is leaked to the opposite side. By adopting the method of the eighth embodiment, noise can be suppressed and the same effect as in the first embodiment can be obtained.
That is, the reflected light from the reflection point of the excitation light in Raman amplification can be suppressed by inserting the optical filter 80b that cuts the wavelength band of the excitation light source. Therefore, even in the alarm monitoring of the light break detection, the light break detection superimposing circuit and the light break detection signal detection circuit required for each wavelength as shown in the conventional example are not required, and only the light break detector is used. , Light break detection can be performed.
[0044]
As described above, in all the embodiments, the directional coupler for coupling the wavelength multiplexed signal light that is opposed to the optical fiber can be replaced with a filter having the same effect.
[0045]
FIG. 10 is a computer basic configuration diagram of the transmission apparatus.
In FIG. 10, a CPU (Central Processing Unit) 40 for executing a program is connected to a monitor 41, a keyboard 45, a mouse 48, a communication board 44, a magnetic disk device 46, and the like via a bus 38.
The magnetic disk device 46 stores an operating system (OS) 47, a program group 49, and a file group 50. However, a form in which the program group 49 and the file group 50 are integrated to form the object-oriented program group 49 is also considered as one embodiment.
The program group 49 is executed by the CPU 40 and the OS 47.
In each of the above embodiments, communication is performed via an optical transmission line using the function of the communication board 44.
[0046]
In all the embodiments, each operation of each component is related to each other, and the operation of each component can be replaced as a series of operations in consideration of the relationship of the operations described above. And it can be set as embodiment of method invention by replacing in this way.
Further, by replacing the operation of each component described above with the process of each component, the program can be implemented.
Moreover, it can be set as embodiment of the computer-readable recording medium recorded on the program by memorize | storing the program in the computer-readable recording medium which recorded the program.
[0047]
The embodiment of the program and the embodiment of the computer-readable recording medium recorded in the program can be configured by a computer-operable program.
Each processing in the embodiment of the program and the embodiment of the computer-readable recording medium on which the program is recorded is executed by the program, and this program is recorded in the recording device, and the central processing device ( CPU) and each flowchart is executed by the central processing unit.
In addition, the software and program of each embodiment may be realized by firmware stored in a ROM (READ ONLY MEMORY). Or you may implement | achieve each function of the program mentioned above with the combination of software, firmware, and hardware.
[0048]
【The invention's effect】
By inserting an optical filter suitable for the wavelength band of the upstream wavelength division multiplexed optical signal and the downstream wavelength division multiplexed optical signal, the influence of the signal wraparound in the transmission path or the reflection at the connector end is inexpensive, In addition, light breakage detection can be realized by a transmission apparatus with a small circuit scale.
[0049]
In addition, by preventing the influence of multiple reflections and the influence of signal light leakage to the receiver, it is possible to reduce the noise applied to the receiver and realize wavelength multiplexing transmission with high transmission quality.
[0050]
Also, the optical signal can be demultiplexed by either a directional coupler, an optical filter, or a coupler.
[0051]
Further, by inserting an optical filter that cuts the wavelength band of the excitation light source used for Raman amplification, light breakage detection can be realized with a transmission apparatus that is inexpensive and has a small circuit scale.
[0052]
Also, by inserting an optical filter suitable for the wavelength band of the upstream wavelength-multiplexed optical signal and downstream wavelength-multiplexed optical signal, it is possible to construct a transmission system that is inexpensive and has a reduced circuit scale. .
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing a single-fiber bidirectional optical wavelength division multiplexing system according to Embodiment 1 of the present invention;
FIG. 2 is a block diagram showing a single fiber bidirectional optical wavelength division multiplexing transmission system according to Embodiment 2 of the present invention;
FIG. 3 is a block diagram showing a single-fiber bidirectional optical wavelength division multiplex transmission system according to Embodiment 3 of the present invention;
FIG. 4 is a block diagram showing a single-fiber bidirectional optical wavelength division multiplex transmission system according to Embodiment 4 of the present invention;
FIG. 5 is a block diagram showing a single-fiber bidirectional optical wavelength division multiplex transmission system according to Embodiment 5 of the present invention;
FIG. 6 is a block diagram showing a single-fiber bidirectional optical wavelength division multiplex transmission system according to Embodiment 6 of the present invention.
FIG. 7 is a block diagram showing a single fiber bidirectional optical wavelength division multiplexing system according to Embodiment 7 of the present invention;
FIG. 8 is a block diagram showing a single fiber bidirectional optical wavelength division multiplexing system according to Embodiment 7 of the present invention.
FIG. 9 is a block diagram showing a single fiber bidirectional optical wavelength division multiplexing system according to an eighth embodiment of the present invention.
FIG. 10 is a basic computer configuration diagram of a transmission apparatus.
FIG. 11 is a block diagram showing a conventional single fiber bidirectional optical wavelength division multiplexing transmission system.
FIG. 12 is a block diagram showing a conventional single fiber bidirectional optical wavelength division multiplexing transmission system.
FIG. 13 is a block diagram showing a conventional single fiber bidirectional optical wavelength division multiplexing transmission system.
[Explanation of symbols]
1a upstream wavelength multiplexed signal, 1b downstream wavelength multiplexed signal, 1c upstream supervisory control signal, 1d downstream supervisory control signal, 10a, 10b wavelength multiplexed terminal station, 10c master node, 20a relay station, 21a, 21b, 21c slave node, 30, 31 Transmission path, 40a, 40b, 41a, 41b, 42, 43 Optical amplifier, 44a, 44b Raman amplifier, 50a, 50b, 50c, 50d, 51, 52 Directional coupler, 53b, 54, 55 WDM coupler (upstream signal) Wavelength band / downlink signal wavelength band), 56a, 56b optical add / drop module, 60a, 60b optical transmitter, 60c, 60d optical transmitter circuit, 61a, 61b optical receiver, 61c, 61d optical receiver circuit, 70a, 70b Waver, 71a, 71b Wave splitter, 72, 75 Light break detection signal superposition circuit, 73, 74 Light break detection signal Signal detection circuit, 80a, 80b, 82, 83 optical filter (uplink wavelength multiplexed signal transmission optical filter), 81a, 81b, 84, 85 optical filter (downlink wavelength multiplexed signal transmission optical filter), 87a, 87b WDM coupler (Raman amplification) Pumping light), 90a, 90b, 91, 92 light break detector, 93a, 93b, 95, 96 WDM coupler (monitoring control light for upstream signal wavelength band), 94a, 94b, 97, 98 WDM coupler (downstream signal wavelength) Bandwidth supervisory control light).

Claims (8)

Receives the first optical signal and second optical signal and the control signal are multiplexed, a first optical signal and an optical signal flowing in a predetermined direction and a second optical signal and the control signal inputted to the control A demultiplexer that demultiplexes and outputs the signal ;
An optical filter that transmits one of the first optical signal and the second optical signal from the optical signal output by the duplexer and blocks the other of the first optical signal and the second optical signal; ,
A control signal demultiplexer provided between the demultiplexer and the optical filter, which demultiplexes the optical signal from the optical signal output from the demultiplexer and the control signal, and outputs the demultiplexed optical signal to the optical filter. transmission apparatus comprising: a <br/> the filter. The transmission apparatus includes a first duplexer and a second duplexer as the duplexer,
The transmission apparatus includes a first optical filter and a second optical filter as the optical filter,
The first optical filter and the second optical filter are provided between the first duplexer and the second duplexer,
The first demultiplexer demultiplexes the optical signal flowing in the first direction from the combined first optical signal and second optical signal, and outputs the demultiplexed optical signal to the first optical filter,
The first optical filter transmits the first optical signal from the input optical signal and blocks the second optical signal to output the first optical signal to the second duplexer;
The second demultiplexer transmits the first optical signal output by the first optical filter, and in the first direction from the combined first optical signal and second optical signal. And demultiplexes the optical signal flowing in the opposite direction to the second optical filter,
The second optical filter transmits the second optical signal from the input optical signal and blocks the first optical signal to output the second optical signal to the first duplexer.
The transmission apparatus according to claim 1, wherein the first duplexer transmits a second optical signal output by the second optical filter. The transmission apparatus further includes:
The light break detector which detects a light break detection by monitoring either one of the first light signal and the second light signal transmitted by the optical filter. Transmission equipment. The transmission apparatus further includes:
The transmission apparatus according to claim 1, further comprising: an optical amplifier that amplifies one of the first optical signal and the second optical signal transmitted by the optical filter.   The transmission apparatus according to claim 1, wherein the duplexer is any one of a directional coupler, an optical filter, and a coupler. The transmission apparatus further includes:
A first optical signal that is provided between the first optical filter and the second duplexer and is transmitted through the first optical filter is input, and a predetermined one of the input first optical signals is input. A first optical add / drop module for demultiplexing an optical signal having a wavelength of
The second optical signal is provided between the second optical filter and the first duplexer and is transmitted through the second optical filter. Among the input second optical signals, the second optical signal is input. A second optical add / drop for demultiplexing an optical signal having another wavelength different from the optical signal having a predetermined wavelength demultiplexed by the first optical add / drop module and outputting the demultiplexed optical signal to the first demultiplexer The transmission apparatus according to claim 2, further comprising a module. The transmission apparatus further includes:
A Raman amplifier Ru to generate excitation light signals,
A multiplexer for multiplexing the pumping optical signal generated by the Raman amplifier with the first optical signal and the second optical signal;
The demultiplexer demultiplexes an optical signal flowing in a predetermined direction and an excitation light signal from the first optical signal, the second optical signal, and the excitation light signal multiplexed by the multiplexer. Output to the filter,
The optical filter transmits either one of the first optical signal and the second optical signal from the input optical signal and the excitation optical signal, and either the first optical signal or the second optical signal. The transmission apparatus according to claim 1, wherein the transmission apparatus blocks an excitation light signal. Receives the first optical signal and second optical signal and the control signal are multiplexed, a first optical signal and an optical signal flowing in a predetermined direction and a second optical signal and the control signal inputted to the control outputs a signal demultiplexed by the demultiplexer,
The optical signal is demultiplexed by the control signal demultiplexer from the optical signal flowing in a predetermined direction and output by the demultiplexer and output in a predetermined direction, and the demultiplexed optical signal is output,
The optical signal demultiplexed by the control signal demultiplexer is input by an optical filter that transmits one of the first optical signal and the second optical signal, and transmission of the input optical signal is performed. A transmission method characterized in that blocking is performed .

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