JP2003258739A - Wavelength multiplexed optical amplification relay transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wavelength multiplexed optical amplification relay transmission system in which a quantity of the change in a transmission quality caused by the relation of the operating point of an input light intensity to an optical submarine repeater on the basis of loss variation is guaranteed by a variable attenuator. <P>SOLUTION: A wavelength multiplexed optical signal transmitted from an optical transmitter 1 is demultiplexed and received by an optical receiver 2, a signal light power monitor 10 measures a receiving level for each wavelength, and abnormality in an optical transmission line 3 or in an optical amplification repeater 4 is detected. The inclination of each wavelength measured by the signal light power monitor 10 with respect to the wavelength of a signal light power is calculated, an inclination increment/decrement quantity as a compared value with the inclination of reference data measured in normal operation is found and when the inclination increment quantity exceeds a threshold, the variable attenuation quantity value of a variable optical attenuator 5 is equally distributed from the inclination increment/ decrement quantity and the characteristics of the optical amplification repeater 4 and simultaneously adjusted to all the variable optical attenuators 5. Afterwards, the spot of fault occurrence is specified and the attenuation quantity of the respective variable optical attenuators 5 is reset to be optimal conditions for all the variable optical attenuators 5. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to Wavelength Division Multiplexing (WDM) that multiplexes a plurality of optical signals having different wavelengths in one optical fiber for transmission.
ng) In the optical transmission system, the present invention relates to a wavelength division multiplexing optical amplification repeater transmission system used for an optical submarine cable system and the like in which optical amplifiers that collectively amplify each wavelength are connected in multiple stages as repeaters for long-distance transmission.

[0002]

2. Description of the Related Art In recent years, a WDM optical transmission system capable of dramatically increasing the transmission capacity of one optical fiber has been widely introduced in optical submarine cables connecting continents.

In the WDM optical transmission system, a plurality of optical carriers having different wavelengths coming from individual light sources are individually modulated,
All the modulated optical signals are multiplexed by an optical multiplexer. The multiplexed WDM optical signals are collectively amplified by the optical amplifier and sent to the optical transmission line. The WDM optical signal sent to the optical transmission line is collectively amplified again by the optical amplifiers arranged at predetermined intervals to compensate for the loss of the optical transmission line, and sent to the next optical transmission line. As described above, the WDM optical signal reaches the receiving end while being collectively amplified at a predetermined relay interval. At the receiving end, the received WDM optical signal is separated into individual optical signals by the optical demultiplexer, and the separated optical signals are regenerated into data by the optical receiver.

In the case of the WDM optical transmission system, since the WDM optical signal is collectively amplified by the optical amplifier, the signal level deviation of the optical signal caused by the wavelength dependence (gain profile) of the gain of the optical amplifier is caused by the optical amplifier. It increases as the number of relays increases. When the optical signal level becomes too high, waveform deterioration occurs due to the non-linear effect of the optical fiber that is the optical transmission line, and when the optical signal level becomes too low, the signal is buried in noise and the desired transmission distance cannot be transmitted. I will end up. In order to avoid such a phenomenon, it is necessary to minimize the gain deviation within the wavelength band of the optical signal when performing multi-stage relay using the optical amplifier. Therefore, the wavelength dependence of the transmittance that cancels the gain profile of the optical amplifier (equalization profile)
Gain equalizers with are widely used.

On the other hand, an erbium-doped optical fiber amplifier (EDFA: Er Dop
It is well known that the gain profile of an ed fiber amplifier) changes depending on the population inversion state determined by the input light intensity and the pump light intensity. In particular, in an optical submarine repeater that performs constant pump light intensity control, the gain profile changes as the input light intensity changes, so the span loss of the optical fiber and the gain of the optical amplifier repeater should be the same. The operating point of the strength is determined, and the design of the gain equalizer is made according to the state.

However, these gain equalizers are passive devices, and increase loss due to repair (interruption fiber insertion) after disconnection of the optical cable due to external factors such as fishing boats and earthquakes, optical fiber cable and optical submarine. The gain profile changes due to an increase in loss due to deterioration over time of constituent optical components of the repeater, which deteriorates the gain deviation.

In order to improve such a problem, it is effective to apply a device (variable gain equalizer) that guarantees the wavelength tilt characteristic of gain due to the change of the input light intensity to the optical amplifier. . A device that changes the linear loss wavelength slope using the magneto-optical effect, a device that configures a Mach-Zehnder interferometer with an optical waveguide to change the linear loss wavelength slope, or a variable optical attenuator and an optical amplifier. There has been proposed a method of controlling the input light intensity to the optical amplifier and changing the wavelength slope of gain or loss by combining and. As one of such conventional techniques, Japanese Patent Laid-Open No. 11-224967 discloses a method of suppressing a variation in equalization error due to a change in system state using a variable gain equalizer.

Referring to FIG. 6, Japanese Patent Laid-Open No. 11-22496
The gain equalization method of the optical communication system shown in Japanese Patent No. 7 will be described. FIG. 6 shows a part of an optical transmission line of an optical communication system in which an optical transmission device and an optical reception device are connected by an optical transmission line of an optical fiber. The section 28 of the optical transmission line shown in FIG. 6 includes a plurality of optical repeaters 32, a fixed gain equalizer 34, and a variable gain equalization unit 36 in the middle of the optical transmission line 30 of the optical fiber. The optical repeater 32 includes an in-line type optical amplifier 38. Variable gain equalization unit 36
Includes a variable gain equalizer 40 having variable gain or loss wavelength characteristics.

In this optical communication system, the wavelength is in the band 15
The gain profile of the optical repeater 32 is preset to 40 nm to 1560 nm and represents the wavelength characteristic in which the gain on the long wavelength side is maximum and the gain on the short wavelength side is minimum with respect to the loss fluctuation of the optical transmission line 30. It is assumed that there is a change between g (λ) [dB] and f (λ) [dB] that represents the wavelength characteristic where the gain on the short wavelength side is maximum and the gain on the long wavelength side is minimum, and the fixed gain, etc. The loss wavelength characteristic L (λ) of the rectifier 34 is (g
When designed so as to satisfy the characteristic (where a and b are constants) expressed by the equation (λ) + f (λ)) / 2 + aλ + b, the gain profile associated with the loss variation of the optical transmission line 30 is Linear equalization error Δg (λ) with respect to λ
Alternatively, it has Δf (λ). However, Δg (λ) =
L (λ) -g (λ), Δf (λ) = L (λ) -f (λ)
Is. Therefore, in the variable gain equalization unit 36 of this conventional system, the variable gain equalizer 40 whose loss slope changes substantially linearly with wavelength is used as a component to compensate for the equalization error, and Variable gain equalization is performed in a system closed for each section shown in FIG. 6 so that the gain slope of the entire transmission line is always flat.

In order to perform variable gain equalization in the closed system for each section 28 shown in FIG. 6, it is necessary to identify the abnormal portion. Here, a description will be given of the abnormal point specifying processing when the general optical amplification repeater 4 using the EDFA as shown in FIG. 7 is used as the optical repeater 32 of the conventional system.

FIG. 7 is a block diagram showing the configuration of the optical amplification repeater 4 using the EDFA. The optical amplification repeater 4 includes an input optical monitor 101 for monitoring the input light intensity of the signal light input to the optical amplification repeater 4, and an erbium-doped optical fiber 102 (EDF: Er Doped Fiber) as an amplification medium.
r), and a WDM coupler 103 for supplying pumping light to the erbium-doped optical fiber 102 and extracting signal light,
An optical isolator 104 for preventing backflow of the light amplified by the erbium-doped optical fiber 102, a pumping light source 105 to the erbium-doped optical fiber 102, and an output light intensity of signal light output from the optical amplification repeater 4 are monitored. For this purpose, an output light monitor 106, a gain monitor 107 for calculating a gain from the output of the input light monitor 101 and the output of the output light monitor 106, and an excitation monitor 108 are provided.

As shown in FIG. 8, when there is an optical transmission line 3a having a loss change between the optical transmission line 3 and the optical amplification repeater 4, the optical amplification repeater 4 immediately after the optical transmission line 3a is present. The input signal of changes. As a result, the input optical monitor 101 of the optical amplification repeater 4 located immediately after the optical transmission line 3a detects an abnormality,
It is specified that the abnormal portion of the optical transmission line 3 is the optical transmission line 3a.

Next, detection when an abnormality occurs inside the optical amplification repeater 4 will be described. FIG. 9 shows a case where the excitation light source 105 has failed. When the pumping light source 105 fails, the amplification factor changes and the output of the output light monitor 106 that monitors the output light intensity changes. That is, since the gain changes, the gain monitor 107 can detect an abnormality. An abnormality is also detected in the excitation monitor 108 that monitors the operating current of the excitation light source 105 and the back light monitor current. This makes it possible to specify that the abnormal portion is the excitation light source 105.

FIG. 10 shows an erbium-doped optical fiber 10
The case where an abnormality occurs on the output side of the optical amplification repeater 4 rather than 2 is shown. In this case, since the output signal changes, an abnormality is detected by the output optical monitor 106 and the gain monitor 107, either the WDM coupler 103 or the optical isolator 104 fails, and the loss variation at the output side of the optical amplification repeater 4 occurs. Can be identified.

FIG. 11 shows a case where an abnormality occurs on the input side of the optical amplification repeater 4. In this case, the gain monitor 1
Only 07 detects anomalies. Since the input light monitor 101 does not detect an abnormality, it can be specified that the abnormal portion is located on the input side of the erbium-doped optical fiber 102 from a portion subsequent to the input light monitor 101.

As described above, the input light monitor 101, the output light monitor 106, the gain monitor 107 in the optical amplification repeater 4,
From the four monitor functions of the excitation monitor 108, it is possible to detect the loss change and identify the abnormal portion.

[0017]

However, in the above-described conventional system, it is necessary to perform variable gain equalization in a closed system for each section of the optical transmission line shown in FIG. The variable gain equalizer in the section to be changed must be controlled by comprehensively judging the information of many monitor functions described above mounted on the optical repeater 32 (optical amplification repeater 4). There is a problem that an algorithm that goes through a complicated procedure is required and the processing time therefor becomes long.

Further, in order to grasp the accurate system state, it is necessary to improve the measurement accuracy of the monitor function. For that purpose, it is necessary to devise, for example, to average the measurement results of a plurality of times, There is also a problem that it takes a long time from the occurrence of an abnormality until the variable gain equalization is completed.

That is, according to the time chart shown in FIG.
Sea urchin at time t₁To the optical transmission line 3 or the optical amplification repeater 4.
If the error occurs, the transmission quality will gradually decrease and the transmission quality
At the time t when the value has dropped below a predetermined threshold value₂become
And the above-mentioned monitor function is the optical transmission line 3 or the optical amplification repeater.
Detect the abnormality of 4. This time t₂From each light increase
Variable gain, etc. in the section for collecting and changing the width repeater 4 information
Determine the carburetor and control it. Variable gain equalization is complete,
The optimum set time for recovering the lowered transmission quality is t ₃To
In the prior art, the abnormality detection time t₂Optimal settings from
Time t₃During this period, the transmission quality will continue to deteriorate.

The present invention has been made in view of the above,
In an ultra-wideband WDM optical transmission system, a variable attenuator guarantees the amount of change in transmission quality due to a change in the operating point of the input light intensity to the optical submarine repeater due to loss variation, and the optical signal power is always within the desired range. The objective is to obtain a wavelength-division-multiplexed optical amplification repeater transmission system that can be maintained.

[0021]

In order to achieve the above object, a wavelength-multiplexed optical amplifier repeater transmission system according to the present invention includes a repeater optical amplifier for collectively amplifying wavelength-multiplexed lights by a plurality of optical signals having different wavelengths. Which is applied to the WDM optical transmission system used as the optical transmission system, which transmits a plurality of optical signals having different wavelengths by wavelength multiplexing, and an optical transmission line of an optical fiber which transmits the wavelength multiplexed optical signal transmitted from the optical transmitting device. An optical receiver for separating the wavelength-multiplexed optical signal transmitted by the optical transmission line for each wavelength, a plurality of optical amplification repeaters for compensating for the loss of the optical transmission line, and the optical amplifier In a wavelength-multiplexed optical amplification repeater transmission system including a repeater and two or more variable optical attenuators for compensating for loss changes caused in the optical transmission line, the optical receiving device includes:
Detecting means for detecting the transmission quality of the received optical signal for each wavelength, and when an abnormality in the transmission quality is detected by the detecting means, a linear slope with respect to the wavelength in the variation of the transmission quality detected for each wavelength is used. And adjusting means for collectively adjusting the attenuation amounts of all the variable optical attenuators, and then adjusting and optimizing the attenuation amounts of the individual variable optical attenuators.

According to the present invention, the optical receiver separates the wavelength-multiplexed optical signal received by using the detecting means,
When the transmission quality is detected for each wavelength and an abnormality in the transmission quality is detected, the adjusting means uses the linear inclination with respect to the wavelength in the change amount of the transmission quality detected for each wavelength to adjust all variable optical attenuators. Of the variable optical attenuator is adjusted at the same time, and then the attenuation amount of each variable optical attenuator is adjusted to be optimized.

A wavelength division multiplexing optical amplifier repeater transmission system according to the next invention is the above invention, wherein the adjusting means is
Adjusting the attenuation amounts of all the variable optical attenuators at once in a uniform manner using a linear slope with respect to the wavelength in the variation amount of the transmission quality detected for each wavelength, and then analyzing the cause of the deterioration of the transmission quality. It is characterized in that the individual attenuation amounts of the variable optical attenuator are adjusted by and the settings are made again for optimization.

According to the present invention, the adjusting means uniformly and simultaneously adjusts the attenuation amounts of all the variable optical attenuators by using the linear inclination with respect to the wavelength in the variation amount of the transmission quality detected for each wavelength. After that, by analyzing the cause of the deterioration of the transmission quality, each attenuation amount of the variable optical attenuator is adjusted and set again to optimize.

The wavelength-multiplexed optical amplification repeater transmission system according to the next invention is characterized in that, in the above-mentioned invention, the detecting means and the adjusting means use optical power as a transmission quality.

According to the present invention, the signal light power is measured for each wavelength, and the wavelength of the change amount of the transmission quality detected for each wavelength for setting the variable optical attenuator is measured based on the measured signal light power. I try to find a linear slope.

A wavelength-multiplexed optical amplification relay transmission system according to the next invention is characterized in that, in the above-mentioned invention, the detecting means and the adjusting means use an optical SNR as a transmission quality.

According to the present invention, the optical SNR is measured for each wavelength, and a linear change with respect to the wavelength in the change amount of the transmission quality detected for each wavelength for setting the variable optical attenuator based on the measured optical SNR. I try to find the slope.

The wavelength-multiplexed optical amplification relay transmission system according to the next invention is characterized in that, in the above-mentioned invention, the detecting means and the adjusting means use a code error rate as a transmission quality.

According to the present invention, the code error rate is measured for each wavelength, and the wavelength of the change amount of the transmission quality detected for each wavelength for setting the variable optical attenuator is set based on the measured code error rate. I try to find a linear slope.

In the wavelength-division-multiplexed optical amplification repeater transmission system according to the next invention, in the above invention, the optical amplification repeater is an erbium-doped optical fiber amplifier, and a linear slope with respect to a wavelength in a change amount of the transmission quality is obtained. It is characterized in that it is calculated from two or more optical signals on the long wavelength side in the wavelength band.

According to the present invention, the optical amplification repeater is composed of an erbium-doped optical fiber amplifier, and has a linear slope with respect to the wavelength in the amount of change in the transmission quality of two or more optical signals on the long wavelength side in the wavelength band. It is calculated from

In the wavelength division multiplex optical amplification repeater transmission system according to the next invention, in the above invention, two or more optical signals on the long wavelength side in the wavelength band are signals on the longer wavelength side than about 1538 nm. Is characterized by.

According to the present invention, the two or more optical signals on the long wavelength side within the wavelength band are signals on the long wavelength side of approximately 1538 nm.

In the wavelength-division-multiplexed optical amplification repeater transmission system according to the next invention, in the above invention, the optical amplification repeater is an erbium-doped optical fiber amplifier, and a linear slope with respect to a wavelength in a change amount of the transmission quality is obtained. It is characterized in that it is calculated from two or more optical signals on the short wavelength side in the wavelength band.

According to the present invention, the optical amplification repeater is composed of an erbium-doped optical fiber amplifier, and has a linear slope with respect to the wavelength in the amount of change in transmission quality that is equal to or greater than two optical signals on the short wavelength side in the wavelength band. It is calculated from

In the wavelength multiplexing optical amplification repeater transmission system according to the next invention, in the above invention, two or more optical signals on the short wavelength side within the wavelength band are signals on the shorter wavelength side than about 1538 nm. Is characterized by.

According to the present invention, the two or more optical signals on the shorter wavelength side within the wavelength band are signals on the shorter wavelength side than about 1538 nm.

[0039]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of a wavelength division multiplexing optical amplifier repeater transmission system according to the present invention will be described in detail below with reference to the accompanying drawings.

Embodiment 1. The first embodiment of the present invention will be described with reference to FIGS. In the first embodiment, the optical receiver 2 separates and receives the optical signal transmitted by wavelength multiplexing from the optical transmitter 1, and the optical signal power monitor 10 installed in the optical receiver 2 receives the optical signal. By measuring the reception level of the optical signal for each wavelength, it is detected that an abnormality has occurred in either the optical transmission line 3 or the optical amplification repeater 4, and when the abnormality is detected, the signal light power monitor 10 Calculate the slope of the signal light power of each wavelength measured in
The slope increase / decrease amount is calculated by comparing the calculated slope with the slope of the reference data measured under normal conditions. When the calculated slope increase / decrease amount exceeds a preset threshold value, the attenuation amount variable value of the variable optical attenuator 5 is calculated from the slope increase / decrease amount and the characteristics of the optical amplification repeater 4, and the calculated attenuation amount variable value is equalized. The variable optical attenuators 5 are distributed and temporarily set in all the variable optical attenuators 5. After that, the failure occurrence point is specified, the individual attenuation amounts of the variable optical attenuators 5 are adjusted, and the attenuation amounts are reset so that the optimum conditions for all the variable optical attenuators 5 are obtained.

FIG. 1 is a block diagram showing the configuration of the wavelength division multiplexing optical amplification relay transmission system of the first embodiment. The wavelength division multiplexing optical amplification repeater transmission system according to the first embodiment is an ultra-wideband WDM in which the shortest wavelength is expanded to 1538 nm or less.
It is applied to an optical transmission system. Embodiment 1
In the wavelength-division-multiplexed optical amplification repeater transmission system, the optical transmitter 1 and the optical receiver 2 repeat the plurality of optical amplifier repeaters 4 (M units in this case) and the variable optical attenuator 5 so that the optical fiber They are connected by the transmission line 3.

Assuming that the optical transmission line 3 and the optical amplification repeater 4 are one repeater span, the variable optical attenuator 5 is arranged every N repeater spans. The relay span in which the variable optical attenuator 5 is arranged can be considered by including the variable optical attenuator 5 in the span loss by shortening the span by the initial attenuation setting value of the variable optical attenuator 5. ing. Specifically, the optical fiber loss used in the optical transmission line 3 is 0.25 dB /
If the span and the span length are 40 km and 10 km, respectively, the span loss is 10 dB. However, when the initial attenuation amount setting value of the variable optical attenuator 5 is set to 5 dB, the span is set on both sides of the variable optical attenuator 5. This means that there is an optical fiber with a loss of 5 dB and a length of 20 km.

The optical transmitter 1 wavelength-multiplexes a plurality of optical signals having different wavelengths and sends them to the optical transmission line 3.

The optical receiver 2 has a function of separating the wavelength-multiplexed optical signal transmitted from the optical transmitter 1 and transmitted through the optical transmission line 3 for each wavelength, and receiving the signal optical power monitor 10. I have it. The signal light power monitor 10 measures the reference data of the signal light power received by the optical receiver 2, which is used when detecting the communication abnormality of the present system.

The optical amplification repeater 4 is, for example, as shown in FIG. 7, an input optical monitor 101 for monitoring the input light intensity of the signal light inputted to the optical amplification repeater 4, and an amplification medium. An erbium-doped optical fiber 102, a WDM coupler 103 for supplying pumping light to the erbium-doped optical fiber 102 and extracting signal light, and an optical isolator 104 for preventing backflow of light amplified by the erbium-doped optical fiber 102. , An excitation light source 105 to the erbium-doped optical fiber 102, an output light monitor 106 for monitoring the output light intensity of the signal light output from the optical amplification repeater 4, an output of the input light monitor 101, and an output light monitor 106. Gain monitor 107 for calculating the gain from the output of
And a pump monitor 108 for compensating the loss of the WDM optical signal lost in the optical transmission line 3 and identifying the abnormal portion.

The variable optical attenuator 5 corrects loss compensation changes of the optical components of the optical amplification repeater 4 and the optical transmission line 3.

Next, the operation of the wavelength division multiplexing optical amplification repeater transmission system of the first embodiment will be described. Optical transmitter 1
Performs wavelength multiplexing on a plurality of optical signals having different wavelengths, aligns the signal levels, and sends out to the optical transmission line 3. The transmitted optical signal repeatedly passes through the repeater span composed of the optical transmission line 3 and the optical amplifying repeater 4 and the variable optical attenuator 5 arranged every N spans, and is transmitted to the optical receiver 2. It
The optical receiver 2 separates the transmitted optical signal for each wavelength and receives it. Data reproduction is performed on the separated WDM optical signal. The signal light power monitor 10 receives an optical signal in a normal state, measures the signal light power for each wavelength, and creates reference data for each wavelength. The created reference data is used to compare with the signal light power at the time of abnormality.

During the system operation, the signal light power monitor 10 of the optical receiver 2 measures the reception level for each wavelength,
It is confirmed whether each reception level is within a predetermined reception level range. If all the received wavelengths are within the predetermined reception level range,
It is determined that the communication is normally performed.

Here, it is assumed that an abnormality occurs in which the loss of any one of the optical fibers in the optical transmission line 3 or the constituent optical components of the plurality of optical amplification repeaters 4 arranged changes. When an abnormality occurs, the reception level of each optical signal separated by each wavelength received by the optical receiving device 2 changes, and the measured reception level is outside the predetermined reception level range. The signal light power monitor 10 of the optical receiver 2 measures the reception levels at at least two wavelengths, and when the measured reception levels fall outside the predetermined reception level range, at least these measured levels are measured. The slope of the signal light power with respect to the wavelength is calculated using two reception levels, and the slope increase / decrease amount is calculated by comparing the calculated slope with the slope with respect to the wavelength of the signal light power of the reference data measured under normal conditions. To do. When the tilt increase / decrease amount exceeds a preset threshold value, the optical receiving device 2 calculates the attenuation amount variable value of the variable optical attenuator 5 based on the tilt increase / decrease amount and the characteristics of each optical amplification repeater 4, The calculated attenuation variable value is evenly distributed to all the variable optical attenuators 5. Then, the optical receiving device 2 sets the evenly distributed attenuation amount variable value to each variable optical attenuator 5 by simultaneously instructing all the variable optical attenuators 5 of the uniformly distributed attenuation amount variable value.

The optical receiving device 2 sets the attenuation variable values evenly distributed to all the variable optical attenuators 5, and then, FIGS.
As described above with reference to, the monitor function (input light monitor 101, output light monitor 106, gain monitor 107, pump monitor 108) of each optical amplification repeater 4 is sequentially measured to identify the location of failure. When the failure occurrence point is specified, the attenuation amount of the variable optical attenuator 5 installed at the location closest to the failure occurrence point is weighted and all the variable optical attenuators 5 are weighted.
Reset so that the attenuation amount of is the optimum condition. When the location of the failure is in the middle of the two variable optical attenuators 5, the attenuation amounts of the variable optical attenuators 5 on the optical transmission device 1 side are weighted and the attenuation amounts of all the variable optical attenuators 5 become optimum conditions. To reset.

FIG. 2 is a time chart showing from the occurrence of an abnormality in the wavelength division multiplexing optical amplifier repeater transmission system of the first embodiment until the optimum condition is set in the variable optical attenuator 5 and the transmission quality is restored. At time t ₁ , an abnormality occurs in the optical transmission line 3 or the optical amplification repeater 4, and the transmission quality gradually deteriorates. When the slope increase / decrease amount obtained by comparing the slope of the signal light power measured for each wavelength received at time t ₂ with respect to the wavelength of the reference data exceeds a threshold value, the slope increase / decrease amount and all the optical amplification repeaters 4 Since the variable attenuation amount is calculated from the characteristics and the variable optical attenuators 5 are equally distributed and set, the transmission quality returns to a value not exceeding the threshold value. After that, the monitor function of each optical amplification repeater 4 is sequentially measured to identify the fault, and resetting is performed so that the attenuation amount of each variable optical attenuator 5 is optimized. At time t ₃ , the transmission quality is completely changed. Return. That is, in the conventional technique shown in FIG. 12, the transmission quality continues to decrease until the transmission quality is restored after the abnormality is detected and the variable gain equalizer 40 is set. However, in the first embodiment, , All variable optical attenuators 5 immediately after abnormality detection
2 does not reach the optimum level as shown in FIG. 2, but minimizes the deterioration amount of the transmission quality while exchanging monitoring / control signals with all the optical amplification repeaters 4. Staying.

As described above, in the first embodiment, the optical receiver 2 separates and receives the optical signal wavelength-multiplexed and transmitted from the optical transmitter 1, and the optical signal installed in the optical receiver 2 is received. When the power monitor 10 detects the occurrence of a loss in either the optical transmission line 3 or the optical amplification repeater 4 by measuring the reception level of the optical signal for each received wavelength, the occurrence of the loss is detected. The inclination increase / decrease amount is obtained by calculating the inclination of the signal light power with respect to the wavelength measured by the signal light power monitor 10 with respect to the wavelength and comparing the calculated inclination with the reference data measured in the normal state. When the tilt increase / decrease amount exceeds a preset threshold value, the attenuation amount variable value of the variable optical attenuator 5 is evenly distributed to all the variable optical attenuators 5 based on the inclination increase / decrease amount and the characteristics of the optical amplification repeater 4. Since the setting is performed and then the failure occurrence point is specified and the attenuation amount is reset so that the optimum conditions are set for all the variable optical attenuators 5, an abnormality is detected due to deterioration of transmission quality, It is possible to minimize the deterioration amount of the transmission quality during the identification of the abnormality.

Embodiment 2. A second embodiment of the present invention will be described with reference to FIG. In the first embodiment, the optical transmission line 3
Alternatively, the occurrence of an abnormality in any of the optical amplifier repeaters 4 is detected by measuring the reception level, and the signal light power is measured for each wavelength in order to guarantee the transmission quality. Based on this, the set value of the variable optical attenuator 5 is changed.

In the second embodiment, the optical SNR is measured by measuring the optical signal level and the optical noise level instead of the signal light power.
(Signal to noise ratio: received signal strength to noise ratio) is used to change the setting value of the variable optical attenuator 5 to compensate the transmission quality.

FIG. 3 is a block diagram showing the configuration of the wavelength division multiplexing optical amplification relay transmission system of the second embodiment. In the wavelength division multiplexed optical amplification relay transmission system according to the second embodiment, the optical receiver 2 is provided with the optical SNR monitor 11. The components having the same functions as those in the first embodiment shown in FIG. 1 are designated by the same reference numerals, and the duplicate description will be omitted.

The optical SNR monitor 11 measures the optical signal level and the optical noise level and calculates the optical SNR.

Next, the operation of the wavelength division multiplexed optical amplification relay transmission system of the second embodiment will be described. Optical transmitter 1
Performs wavelength multiplexing on a plurality of optical signals having different wavelengths, aligns the signal levels, and sends out to the optical transmission line 3. The transmitted optical signal repeatedly passes through the repeater span composed of the optical transmission line 3 and the optical amplifying repeater 4 and the variable optical attenuator 5 arranged every N spans, and is transmitted to the optical receiver 2. It
The optical receiver 2 separates the transmitted optical signal for each wavelength and receives it. Data reproduction is performed on the separated WDM optical signal. The optical SNR monitor 11 receives the optical signal at the normal time, measures the optical signal level and the optical noise level for each wavelength,
The optical SNR is calculated from the measurement result, and reference data is created for each wavelength. The created reference data is the optical SNR at the time of abnormality.
Used to compare with.

Further, during the system operation, the optical SNR monitor 11 of the optical receiver 2 displays the optical SNR calculated for each wavelength as
It is confirmed whether or not each optical SNR is within a predetermined optical SNR range. If all the received wavelengths are within the predetermined optical SNR range, it is determined that the communication is normally performed.

Here, it is assumed that an abnormality occurs in which the loss of any one of the optical fibers in the optical transmission line 3 or the constituent optical components of the plurality of optical amplification repeaters 4 arranged changes. When an abnormality occurs, the optical signal level and the optical noise level of each optical signal received by the optical receiving device 2 separated for each wavelength change, and the optical SNR changes accordingly. Therefore, the calculated optical SNR is predetermined. The optical SNR is out of the range. Optical receiver 2
The optical SNR monitor 11 is configured to calculate the optical SNRs of at least two wavelengths, and when the calculated optical SNRs fall outside the predetermined optical SNR range, the calculated optical SNRs of the at least two optical SNRs are calculated. The tilt of the optical SNR with respect to the wavelength is calculated using the calculated tilt, and the tilt increase / decrease amount is calculated by comparing the calculated tilt with the tilt of the reference data measured under normal conditions with respect to the wavelength of the optical SNR. When the tilt increase / decrease amount exceeds a preset threshold value, the optical receiving device 2 calculates the attenuation amount variable value of the variable optical attenuator 5 based on the tilt increase / decrease amount and the characteristics of each optical amplification repeater 4, The calculated attenuation variable value is evenly distributed to all the variable optical attenuators 5. Then, the optical receiving device 2 sets the evenly distributed attenuation amount variable value to each variable optical attenuator 5 by simultaneously instructing all the variable optical attenuators 5 of the uniformly distributed attenuation amount variable value.

The optical receiving device 2 sets the attenuation variable values of all the variable optical attenuators 5 to equal distribution, and then monitors each optical amplification repeater 4 as described above with reference to FIGS. The functions (the input light monitor 101, the output light monitor 106, the gain monitor 107, and the excitation monitor 108) are sequentially measured to identify the location of failure. When the failure occurrence point is specified, the attenuation values of the variable optical attenuators 5 installed closest to the failure occurrence point are weighted so that the attenuation values of all the variable optical attenuators 5 become optimum conditions. Reset to. When the location of the failure is in the middle of the two variable optical attenuators 5, the attenuation amounts of the variable optical attenuators 5 on the optical transmission device 1 side are weighted and the attenuation amounts of all the variable optical attenuators 5 become optimum conditions. To reset.

As described above, in the second embodiment, the optical receiver 2 separates and receives the optical signal transmitted by the wavelength division multiplexing from the optical transmitter 1, and the optical SNR installed in the optical receiver 2 is received. The monitor 11 measures the optical signal level and the optical noise level of the optical signal for each received wavelength and calculates the optical SNR, thereby confirming that a loss has occurred in either the optical transmission line 3 or the optical amplification repeater 4. When the occurrence of the loss is detected, the inclination of the optical SNR for each wavelength calculated by the optical SNR monitor 11 with respect to the wavelength is calculated, and the calculated inclination is compared with the reference data measured under normal conditions. Calculate the amount of slope increase / decrease. When the tilt increase / decrease amount exceeds a preset threshold value, the attenuation amount variable value of the variable optical attenuator 5 is evenly distributed to all the variable optical attenuators 5 based on the inclination increase / decrease amount and the characteristics of the optical amplification repeater 4. Since the setting is performed and then the failure occurrence point is specified and the attenuation amount is reset so that the optimum conditions are set for all the variable optical attenuators 5, an abnormality is detected due to deterioration of transmission quality, It is possible to minimize the deterioration amount of the transmission quality during the identification of the abnormality.

Embodiment 3. A third embodiment of the present invention will be described with reference to FIG. In the second embodiment, the optical transmission line 3
Alternatively, the occurrence of loss in any of the optical amplifier repeaters 4 is detected by measuring the optical signal level and the optical noise level and calculating the optical SNR from the measurement result. The set value of the variable optical attenuator 5 is changed based on the slope of the optical SNR.

In the third embodiment, an error correction code (BER: Bit Error Rate) is used instead of the optical SNR to change the set value of the variable optical attenuator 5.

FIG. 4 is a block diagram showing the configuration of the wavelength division multiplexed optical amplification relay transmission system of the third embodiment. In the wavelength division multiplexed optical amplification relay transmission system according to the third embodiment, the BER monitor 12 is installed in the optical receiver 2. The components having the same functions as those in the first embodiment shown in FIG. 1 are designated by the same reference numerals, and the duplicate description will be omitted.

The BER monitor 12 measures the code error rate for each wavelength using an LSI or the like for optical communication using error code correction.

Next, the operation of the wavelength division multiplexed optical amplification relay transmission system of the third embodiment will be described. Optical transmitter 1
Performs wavelength multiplexing on a plurality of optical signals having different wavelengths, aligns the signal levels, and sends out to the optical transmission line 3. The transmitted optical signal repeatedly passes through the repeater span composed of the optical transmission line 3 and the optical amplifying repeater 4 and the variable optical attenuator 5 arranged every N spans, and is transmitted to the optical receiver 2. It
The optical receiver 2 separates the transmitted optical signal for each wavelength and receives it. Data reproduction is performed on the separated WDM optical signal. The BER monitor 12 receives an optical signal in a normal state, measures a code error rate for each wavelength, and creates reference data for each wavelength. The created reference data is used for comparison with the code error rate at the time of abnormality.

During the system operation, B of the optical receiver 2
In the ER monitor 12, the code error rate measured for each wavelength is
It is confirmed whether or not each bit error rate is within a predetermined bit error rate range. If all the received wavelengths are within the predetermined code error rate range,
It is determined that the communication is normally performed.

Here, it is assumed that an abnormality occurs in which the loss of any of the optical fibers in the optical transmission line 3 or the constituent optical components of the plurality of optical amplification repeaters 4 arranged changes. When an abnormality occurs, the code error rate of each optical signal separated for each wavelength received by the optical receiving device 2 changes, and the measured code error rate falls outside the predetermined code error rate range. The BER monitor 12 of the optical receiver 2 measures the code error rates at at least two wavelengths, and when the measured code error rates fall outside the predetermined code error rate range, these measurements are performed. Calculating the slope of the code error rate with respect to wavelength using at least two code error rates,
The slope increase / decrease amount is calculated by comparing the calculated slope with the slope of the code error rate of the reference data measured under normal conditions with respect to the wavelength. When the tilt increase / decrease amount exceeds a preset threshold value, the optical receiving device 2 calculates the attenuation amount variable value of the variable optical attenuator 5 based on the tilt increase / decrease amount and the characteristics of each optical amplification repeater 4, The calculated attenuation variable value is evenly distributed to all the variable optical attenuators 5. Then, the optical receiving device 2 sets the evenly distributed attenuation amount variable value to each variable optical attenuator 5 by simultaneously instructing all the variable optical attenuators 5 of the uniformly distributed attenuation amount variable value.

The optical receiving device 2 sets the attenuation variable values evenly distributed to all the variable optical attenuators 5, and then, FIGS.
As described above with reference to, the monitor function (input light monitor 101, output light monitor 106, gain monitor 107, pump monitor 108) of each optical amplification repeater 4 is sequentially measured to identify the location of failure. When the failure occurrence point is specified, the attenuation amount of the variable optical attenuator 5 installed at the location closest to the failure occurrence point is weighted and all the variable optical attenuators 5 are weighted.
Reset so that the attenuation amount of is the optimum condition. When the location of the failure is in the middle of the two variable optical attenuators 5, the attenuation amounts of the variable optical attenuators 5 on the optical transmission device 1 side are weighted and the attenuation amounts of all the variable optical attenuators 5 become optimum conditions. To reset.

As described above, in the third embodiment, the optical receiving apparatus 2 separates and receives the optical signal transmitted from the optical transmitting apparatus 1 after being wavelength-multiplexed, and is installed in the optical receiving apparatus 2.
The ER monitor 12 measures the code error rate of the optical signal for each received wavelength, whereby the optical transmission line 3 or the optical amplification repeater 4
When an abnormality is detected in any of the above, and when the abnormality is detected, the slope of the code error rate for each wavelength measured by the BER monitor 12 is calculated with respect to the wavelength, and the calculated slope is a standard measured in the normal state. The slope increase / decrease amount is obtained by comparing the slope with the data. When the tilt increase / decrease amount exceeds a preset threshold value, the attenuation amount variable value of the variable optical attenuator 5 is evenly distributed to all the variable optical attenuators 5 based on the inclination increase / decrease amount and the characteristics of the optical amplification repeater 4. Since the setting is performed and then the failure occurrence point is specified and the attenuation amount is reset so that the optimum conditions are set for all the variable optical attenuators 5, an abnormality is detected due to deterioration of transmission quality, It is possible to minimize the deterioration amount of the transmission quality during the identification of the abnormality.

Since the linear slope with respect to the wavelength in the amount of change in transmission quality changes between the short wavelength side and the long wavelength side with the vicinity of 1538 nm as a boundary, the optical signals on the longer wavelength side and the shorter wavelength side than 1538 nm are different from each other. It is not possible to calculate a linear slope with respect to the wavelength in an accurate change amount of transmission quality. Therefore, as shown in FIG. 5, at least two or more wavelengths for calculating a linear inclination with respect to the wavelength in the amount of change in transmission quality have a long wavelength side or a short wavelength side of approximately 1538 nm in the wavelength band. Select from the optical signals in.

[0072]

As described above, according to the present invention, the optical receiving device separates the wavelength-multiplexed optical signal received by the detecting means for each wavelength and detects the transmission quality for each wavelength. When an abnormality in the transmission quality is detected, the adjusting means simultaneously adjusts the attenuation amounts of all the variable optical attenuators by using the linear inclination with respect to the wavelength in the variation amount of the transmission quality detected for each wavelength, and thereafter. Since the amount of attenuation of each variable optical attenuator is adjusted and optimized, an abnormality is detected due to the deterioration of transmission quality, and the amount of deterioration of transmission quality is minimized while the abnormality is specified. The optical signal power can always be kept within a desired range.

According to the next invention, the adjusting means uniformly adjusts the attenuation amounts of all the variable optical attenuators at once by using the linear inclination with respect to the wavelength in the variation amount of the transmission quality detected for each wavelength. After that, by analyzing the cause of the deterioration of transmission quality, the individual attenuation amounts of the variable optical attenuator are adjusted and set again to be optimized. It is possible to minimize the amount of deterioration of the transmission quality during the specification of, and to always maintain the optical signal power within the desired range.

According to the next invention, the signal light power is measured for each wavelength, and the wavelength in the variation amount of the transmission quality detected for each wavelength for setting the variable optical attenuator based on the measured signal light power. Since the linear inclination with respect to is obtained, the optical signal power can always be maintained within a desired range.

According to the next invention, the optical SNR is measured for each wavelength, and the linearity with respect to the wavelength in the change amount of the transmission quality detected for each wavelength for setting the variable optical attenuator based on the measured optical SNR. Since such a slope is obtained, the optical signal power and thus the optical SNR can always be maintained within a desired range.

According to the next invention, the code error rate is measured for each wavelength, and the wavelength in the change amount of the transmission quality detected for each wavelength for setting the variable optical attenuator based on the measured code error rate. Since the linear slope with respect to is obtained, the optical signal power and hence the code error rate can be always maintained within a desired range.

According to the next invention, the optical amplification repeater is composed of an erbium-doped optical fiber amplifier, and has a linear slope with respect to the wavelength in the amount of change in transmission quality that is equal to or greater than that of two or more optical signals on the long wavelength side in the wavelength band. Since it is calculated from the signals, even if the number of wavelength-multiplexed optical signals is small, it is possible to always maintain the transmission quality within a desired range by measuring at least two optical signals.

According to the next invention, since the two or more optical signals on the long wavelength side in the wavelength band are signals on the longer wavelength side than approximately 1538 nm, the attenuation amount of the variable optical attenuator is increased from the wavelength of 1538 nm or more. Can be set to obtain a system that guarantees transmission quality even in an ultra-wide band expanded to a wavelength of 1538 nm or less.

According to the next invention, the optical amplification repeater is composed of an erbium-doped optical fiber amplifier, and has a linear slope with respect to the wavelength in the amount of change in transmission quality that is equal to or greater than that of two or more optical signals on the short wavelength side in the wavelength band. Since it is calculated from the signals, even if the number of wavelength-multiplexed optical signals is small, it is possible to always maintain the transmission quality within a desired range by measuring at least two optical signals.

According to the next invention, since the two or more optical signals on the short wavelength side in the wavelength band are signals on the shorter wavelength side than approximately 1538 nm, the attenuation amount of the variable optical attenuator from the wavelength of 1538 nm or less. Can be set to obtain a system that guarantees the transmission quality even in the ultra-wide band expanded to a wavelength of 1538 nm or more.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a wavelength division multiplexing optical amplification relay transmission system according to a first embodiment.

FIG. 2 is a time chart showing transmission quality of the wavelength division multiplexing optical amplification relay transmission system of the first embodiment.

FIG. 3 is a block diagram showing a configuration of a wavelength division multiplexing optical amplification relay transmission system according to a second embodiment.

FIG. 4 is a block diagram showing a configuration of a wavelength division multiplexing optical amplification relay transmission system according to a third embodiment.

FIG. 5 is a diagram showing a linear slope with respect to wavelength in the amount of change in transmission quality.

FIG. 6 is a block diagram showing a configuration of a conventional optical communication system.

7 is a block diagram showing a configuration of the optical amplification repeater shown in FIG.

8 is a block diagram for explaining a monitor function of the optical amplification repeater shown in FIG.

9 is a block diagram for explaining a monitor function of the optical amplification repeater shown in FIG.

10 is a block diagram for explaining a monitor function of the optical amplification repeater shown in FIG.

11 is a block diagram for explaining a monitor function of the optical amplification repeater shown in FIG.

FIG. 12 is a time chart showing the transmission quality of the prior art.

[Explanation of symbols]

1 optical transmitter, 2 optical receiver, 3, 3a, 30 optical transmission line, 4 optical amplification repeater, 5 variable optical attenuator, 10
Signal optical power monitor, 11 optical SNR monitor, 12 BE
R monitor, 32 optical repeater, 34 fixed gain equalizer, 3
6 variable gain equalization unit, 38 optical amplifier, 101
Input light monitor, 102 Erbium-doped optical fiber, 1
03 WDM coupler, 104 Optical isolator, 105
Pump light source, 106 output light monitor, 107 gain monitor, 108 pump monitor.

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04B 17/00 H04B 9/00 EK H04J 14/00 14/02 (72) Inventor Kuniaki Honjima Chiyoda, Tokyo 2-3 2-3 Marunouchi Ward Sanryo Electric Co., Ltd. F term (reference) 5F072 AB09 AK06 YY17 5K002 AA01 AA03 AA06 BA02 BA05 CA13 DA02 EA07 FA01 5K042 CA10 CA15 DA17 DA33 EA15

Claims (9)

[Claims] 1. A WD using an optical amplifier as a repeater, which collectively amplifies wavelength-multiplexed light by a plurality of optical signals having different wavelengths.
An optical transmission device which is applied to an M optical transmission system and which wavelength-multiplexes and transmits a plurality of optical signals having different wavelengths; and an optical transmission line of an optical fiber which transmits the wavelength-multiplexed optical signal transmitted from the optical transmission device, An optical receiver that separates and receives the wavelength-multiplexed optical signal transmitted by the optical transmission line for each wavelength, a plurality of optical amplification repeaters for compensating for the loss of the optical transmission line, and the optical amplification repeater And a wavelength-division-multiplexed optical amplification repeater transmission system including two or more variable optical attenuators for compensating for loss change caused in the optical transmission line, wherein the optical receiving device sets the transmission quality of the received optical signal to the wavelength. Detection means for detecting each, and when the detection means detects an abnormality in transmission quality,
Adjust the attenuation of all the variable optical attenuators all at once using the linear slope with respect to the wavelength in the amount of change in transmission quality detected for each wavelength, and then adjust the attenuation of each variable optical attenuator. A wavelength-multiplexed optical amplification repeater transmission system comprising: an adjusting means for optimizing. 2. The adjusting means adjusts the attenuation amounts of all the variable optical attenuators uniformly and simultaneously by using a linear inclination with respect to the wavelength in the variation amount of the transmission quality detected for each wavelength, and thereafter, The wavelength-multiplexed optical amplification repeater transmission system according to claim 1, wherein the attenuation of each variable optical attenuator is adjusted by analyzing the cause of the deterioration of the transmission quality, and the variable optical attenuator is reset and optimized. 3. The detecting means and the adjusting means use optical power as a transmission quality.
Alternatively, the wavelength division multiplexing optical amplification repeater transmission system according to the item 2. 4. The wavelength division multiplexing optical amplifier repeater transmission system according to claim 1, wherein the detecting means and the adjusting means use an optical SNR as a transmission quality. 5. The wavelength division multiplexing optical amplifier repeater transmission system according to claim 1, wherein the detecting means and the adjusting means use a code error rate as a transmission quality. 6. The optical amplification repeater is an erbium-doped optical fiber amplifier, and calculates a linear slope with respect to a wavelength in the amount of change in the transmission quality from two or more optical signals on the long wavelength side in the wavelength band. The wavelength division multiplexing optical amplification repeater transmission system according to any one of claims 1 to 5. 7. The wavelength division multiplexed optical amplification repeater transmission system according to claim 6, wherein the two or more optical signals on the long wavelength side in the wavelength band are signals on the long wavelength side of approximately 1538 nm. . 8. The optical amplification repeater is an erbium-doped optical fiber amplifier, and calculates a linear slope with respect to the wavelength in the amount of change in the transmission quality from two or more optical signals on the short wavelength side in the wavelength band. The wavelength division multiplexing optical amplification repeater transmission system according to any one of claims 1 to 5. 9. The wavelength division multiplexed optical amplification repeater transmission system according to claim 8, wherein the two or more optical signals on the short wavelength side in the wavelength band are signals on the shorter wavelength side than about 1538 nm. .