JP5539248B2 - Optical transmission system, optical transmission method and transmitter - Google Patents

Description

The present invention relates to an optical transmission system that transmits and receives an optical signal , an optical transmission method , and a transmission apparatus .

  In an optical transmission system that transmits and receives an optical signal between cities, a dispersion compensation technique that compensates for deterioration (wavelength dispersion) of the optical signal by an optical transmission path is indispensable for long-distance transmission and large-capacity transmission. Patent Document 1 discloses an example of this dispersion compensation technique. Specifically, dispersion compensation is performed by a tunable dispersion compensator in the system, and the variable dispersion compensator of the variable dispersion compensator is determined according to the bit error rate (BER) of the received data signal obtained from the dispersion-compensated optical signal. A technique for controlling the dispersion compensation amount is disclosed.

JP 2005-286382 A

  The optical transmission system as described above is currently in a transitional period from 10 GWDM (Wavelength Division Multiplex) using a 10 Gbps optical signal to 40 GWDM using a 40 Gbps optical signal capable of realizing further large-capacity transmission. .

  However, if an attempt is made to conduct a 40 Gbps optical signal without any change in the existing 10 G optical transmission system, the 40 Gbps optical signal is used for a 10 Gbps signal because the 40 Gbps optical signal has a wider spectrum than the 10 Gbps optical signal. Each time it passes through the optical filter, the low frequency component and the high frequency component of the 40 Gbps optical signal are attenuated by the filtering function of the optical filter. As a result, there is a problem that so-called spectrum narrowing occurs in which information included in the optical signal is lost. In such a case, it may be possible to change the optical filter for a 10 Gbps signal so that it corresponds to an optical signal of 40 Gbps. However, since a plurality of such optical filters are provided in the transmission line, There is a problem that it takes a lot of cost to change.

  The present invention has been made in view of the above problems, and an object thereof is to provide a technique capable of appropriately compensating for spectral narrowing and chromatic dispersion.

An optical transmission system according to the present invention transmits an optical signal as a transmission signal , performs transmission for performing spectral narrowing compensation and chromatic dispersion compensation on the transmission signal, a node having a filter, and via the node , and a receiver for receiving the transmission signal as a reception signal. A value based on the number of nodes is set to an initial value of a compensation value used for the spectrum narrowing compensation in the transmitter, and the received signal for the transmission signal compensated for the spectrum narrowing using the initial value of the searched compensation value of the wavelength dispersion compensation on the basis of the error rate, the compensation value obtained by the search, Ru is set to the compensation value for use in the chromatic dispersion compensation at the transmission device.

  According to the present invention, spectral narrowing compensation is performed on a transmission signal, and a second chromatic dispersion compensation value is obtained by a two-step search, thereby performing chromatic dispersion compensation on the transmission signal. Therefore, spectral narrowing and chromatic dispersion can be appropriately compensated. Therefore, for example, in an existing optical transmission system provided with a filter for 10 Gbps signal, even if a 40 Gbps optical signal is transmitted from the transmission device, the possibility that the reception device receives the desired optical signal can be increased. .

1 is a diagram illustrating a configuration of an optical transmission system according to Embodiment 1. FIG. It is a figure which shows the image of a lookup table. 3 is a flowchart illustrating a control procedure of the monitoring control device according to the first embodiment. FIG. 3 is a diagram showing a sequence of the optical transmission system according to the first embodiment. 6 is a diagram showing an example of a first chromatic dispersion compensation value search according to Embodiment 1. FIG. 6 is a diagram showing an example of a second chromatic dispersion compensation value search according to Embodiment 1. FIG. FIG. 3 is a diagram showing a sequence of the optical transmission system according to the first embodiment. 6 is a flowchart illustrating a control procedure of the monitoring control device according to the second embodiment. FIG. 10 is a diagram showing a sequence of the optical transmission system according to the second embodiment. 10 is a flowchart illustrating a control procedure of the monitoring control device according to the third embodiment. FIG. 10 is a diagram showing an example of a second chromatic dispersion compensation value search according to Embodiment 4.

<Embodiment 1>
FIG. 1 is a diagram showing a configuration of an optical transmission system according to Embodiment 1 of the present invention. As shown in this figure, the optical transmission system includes a transmission-side transmission device 10 that is a transmission device, a reception-side transmission device 20 that is a reception device, and a monitoring control device 30.

  Between the transmission device 10 on the transmission side and the transmission device 20 on the reception side, an optical transmission path 40 for transmitting an optical signal is provided. The optical transmission line 40 is composed of an optical fiber such as DCF (Dispersion Compensating Fiber), and only one or a plurality of optical transmission lines 40 may be provided between the transmission apparatus 10 on the transmission side and the transmission apparatus 20 on the reception side. It may be provided.

  As shown in FIG. 1, the optical transmission line 40 is provided with a plurality of nodes 42 each having an optical filter 41. In this embodiment, it is assumed that an optical filter for a 10 Gbps signal is provided as the optical filter 41 included in the node 42. Although not shown, the optical transmission path 40 is branched at the node 42, and the transmission side transmission device 10 or the reception side transmission device 20 is connected to the branch destination. The node 42 selectively transmits the optical signal received by itself to an appropriate branch destination, so that the optical signal can be transmitted from the transmission-side transmission device 10 to the desired reception-side transmission device 20. ing.

  The transmission-side transmission apparatus 10 includes a transmission-side monitoring control unit 11 and a transmission-side main signal unit 12, and transmits an optical signal on which data is superimposed by the wavelength division multiplexing method to the optical transmission line 40 as a transmission signal. .

  The reception-side transmission device 20 includes a reception-side monitoring control unit 21 and a reception-side main signal unit 22, and receives the optical signal transmitted by the transmission-side transmission device 10 via the optical transmission path 40. That is, the reception-side transmission device 20 receives the optical signal from the transmission-side transmission device 10 as a reception signal via the node 42 having the optical filter 41 (filter).

  The monitoring control device 30 is connected to the transmission device 10 on the transmission side and the transmission device 20 on the reception side via, for example, a LAN (Local Area Network). The monitoring control device 30 includes a memory 31 in which an initial value of a spectral narrowing compensation value for compensating for spectral narrowing and an initial value of a chromatic dispersion compensation value for compensating chromatic dispersion are stored. The transmission side transmission device 10 and the reception side transmission device 20 are managed (controlled) in an integrated manner.

  Note that spectrum narrowing means that, for example, every time a 40 Gbps transmission signal passes through the node 42, the low-frequency component and the high-frequency component of the transmission signal are attenuated by the filtering of the optical filter 41 of the node 42. This is a phenomenon in which data included in a signal is lost on the receiving side. Also, chromatic dispersion means that the wavelengths of optical signals multiplexed in the transmission signal are different from each other, resulting in a difference in their transmission speed, resulting in the waveform of the transmission signal collapsing and the data contained therein. This phenomenon is missing on the receiving side.

  In the optical transmission system according to the present embodiment, as will be described below, the monitoring and control apparatus 30 performs spectral narrowing compensation values (filter patterns) for performing spectral narrowing compensation and chromatic dispersion compensation. Is transmitted to the transmission apparatus 10 on the transmission side. Then, the transmission-side transmission device 10 performs spectrum narrowing compensation and wavelength dispersion compensation on the transmission signal based on the spectrum narrowing compensation value (filter pattern) and the wavelength dispersion compensation value from the monitoring control device 30.

  Next, the operation of the optical transmission system according to this embodiment will be described.

  Based on the initial value of the spectral narrowing compensation value and the initial value of the chromatic dispersion compensation value stored in the memory 31, the monitoring control device 30 transmits the spectrum to the transmission side monitoring control unit 11 in the transmission side transmission device 10. Instructs setting of a constriction compensation value (initial value) and a chromatic dispersion compensation value (initial value).

  The transmission-side monitoring control unit 11 sets the spectral narrowing compensation value (initial value) and the chromatic dispersion compensation value (initial value) instructed from the monitoring control device 30 to the transmission-side main signal unit 12. The transmission side main signal unit 12 is provided with a memory 13, and this memory 13 holds a look-up table (array), which will be described later, indicating compensation values determined from chromatic dispersion compensation values and spectral narrowing compensation values. ing. The transmission side main signal unit 12 selects a compensation value corresponding to the spectral narrowing compensation value and the chromatic dispersion compensation value set by the transmission side monitoring control unit 11 from the compensation values of the lookup table held in the memory 13. To do. Then, the transmission-side main signal unit 12 adds an electrical signal corresponding to the selected compensation value to the conventional electrical signal, converts the electrical signal obtained thereby into an optical signal, and uses the optical signal as a transmission signal. It transmits to the transmission line 40.

  Here, in the present embodiment, as described above, the transmission-side transmission apparatus 10 adds an electrical signal corresponding to the compensation value to the conventional electrical signal. As a result, the transmission-side transmission apparatus 10 raises (lifts) the intensity of the spectrum, which is expected to be attenuated by spectrum narrowing, to the transmission signal higher than that of other spectra. Therefore, even if attenuation due to spectrum narrowing occurs in the transmission signal, the attenuation and the intensity increased in advance are canceled out. As a result, the reception-side transmission apparatus 20 can receive an optical signal having a desired intensity. It has become. That is, according to the present embodiment, it is possible to perform spectrum narrowing compensation that compensates for spectrum narrowing of a transmission signal.

  Although the description has been given here of changing the spectrum intensity of the transmission signal, the effect of spectrum narrowing compensation is enhanced by appropriately changing the phase of the transmission signal as well. Further, in the above description, the spectral narrowing compensation has been described, but the chromatic dispersion compensation is also performed in substantially the same manner.

  The supervisory control device 30 instructs the reception-side supervisory control unit 21 in the reception-side transmission device 20 to measure a BER (code error rate) that is an error rate for the received signal received by the reception-side transmission device 20. To do. Upon receiving this instruction, the reception-side monitoring control unit 21 instructs the reception-side main signal unit 22 to perform BER measurement. When receiving this instruction, the receiving side main signal unit 22 measures the BER of the received signal and notifies the receiving side monitoring control unit 21 of the measurement result. The reception-side monitoring control unit 21 transmits the BER measurement result to the monitoring control device 30.

  The monitoring control device 30 changes the spectral narrowing compensation value and the chromatic dispersion compensation value from their initial values based on the BER measurement results transmitted from the receiving side monitoring control unit 21, respectively, and the transmitting side monitoring control unit 11. In contrast, the setting of the spectral narrowing compensation value and the chromatic dispersion compensation value after the change is instructed. By repeating the above operation, appropriate spectral narrowing compensation values and chromatic dispersion compensation values that lower the BER are determined, and spectral narrowing compensation and chromatic dispersion compensation are determined based on the corresponding compensation values in the lookup table. Is done.

  FIG. 2 is a diagram illustrating an image of a lookup table held in the memory 13 of the transmission apparatus 10 on the transmission side. In this example, the range in which the chromatic dispersion compensation value C can be set is set from -α [ps / nm] to + α [ps / nm], and the chromatic dispersion compensation value is set in increments of Δ [ps / nm]. It shows what you can do. The filter pattern F shown in this figure is substantially the same as the above-described spectral narrowing compensation value. In the example shown in this figure, it is shown that the filter pattern F can be set in n types of 0 to (n−1). A compensation value held at a position where the chromatic dispersion compensation value C and the filter pattern F intersect each other is a compensation value to be set in the transmission apparatus 10 on the transmission side.

  When the chromatic dispersion amount of the optical transmission line 40 is C1, the chromatic dispersion compensation value set by the control of the monitoring control device 30 is “−C1”. The compensation amount for the spectral narrowing is performed based on the filtering characteristics of the optical filter 41, the narrowing amount, and the filter characteristics such as the shift amount in the optical filter 41. Therefore, the filter pattern F is patterned by changing the combination of parameters of these filter characteristics.

  When the supervisory control device 30 gives an instruction for the chromatic dispersion compensation value and the filter pattern to the transmission side supervisory control unit 11, the transmission side supervisory control unit 11 instructs the transmission side main signal unit 12 to use the dispersion compensation value and the filter pattern. To be notified. The transmission-side main signal unit 12 refers to the look-up table shown in FIG. 2 based on the notified dispersion compensation value and filter pattern, and selects the compensation value shown there. The transmission-side main signal unit 12 performs spectrum narrowing compensation and chromatic dispersion compensation on the transmission signal by generating an electric signal to be converted into the transmission signal based on the selected compensation value.

  As described above, the spectral narrowing compensation and the chromatic dispersion based on the compensation value are performed independently without performing the spectral narrowing compensation based on the spectral narrowing compensation value and the chromatic dispersion compensation based on the chromatic dispersion compensation value. The reason for performing the compensation at the same time is that some correlation is recognized between the spectral narrowing compensation and the chromatic dispersion compensation.

  However, in the following description, instead of the compensation value, one of the attention to be paid out of the spectral narrowing compensation value and the chromatic dispersion compensation value may be described. For example, when the supervisory control device 30 is designated to change the spectral narrowing compensation value and the chromatic dispersion compensation value is fixedly set, paying attention to the spectral narrowing compensation value, the “transmission-side transmission device” 10 may be described as “performs spectral narrowing compensation for a transmission signal based on the spectral narrowing compensation value designated by the monitoring control device 30”.

  FIG. 3 is a flowchart showing a control procedure under the control of the monitoring control device 30 according to the present embodiment. Hereinafter, the control of the monitoring control device 30 will be described with reference to FIG.

  At the start of conduction of the main signal, that is, when the transmission line adjustment starts in step S11, the monitoring control device 30 instructs the transmission side monitoring control unit 11 so that the initial value of the filter pattern is set in step S12. And give instructions.

  As described above, the reason for instructing the initial setting of the filter pattern is that the optical signal may not be conducted from the transmitting side transmission apparatus 10 to the receiving side transmission apparatus 20 in the state where the spectrum narrowing compensation is not performed. is there.

  Here, as described above, the transmission signal attenuates every time it passes through the node 42 (optical filter 41). That is, the attenuation amount of the transmission signal due to spectrum narrowing is proportional to the number of nodes 42 (number of stages of the optical filter 41) through which the transmission signal passes.

  Therefore, the monitoring control device 30 determines a filter pattern to be initialized based on the number of nodes 42 so that the optical signal can be reliably conducted. That is, in the present embodiment, the transmission apparatus 10 on the transmission side is controlled by the monitoring control apparatus 30 so that the transmission signal is received from the transmission apparatus 10 on the reception side 20 via the node 42. Spectral narrowing compensation is performed based on the number of nodes. Note that the correspondence between the number of nodes 42, the filter pattern to be initialized, and the maximum value of the filter pattern are stored in advance in the memory 31 of the monitoring control device 30.

  Then, an appropriate chromatic dispersion compensation value is searched for in step S13 and step S14 described below. In addition, the filter pattern which should be set to the transmission side transmission apparatus 10 is fixed to the initial value of the above-mentioned filter pattern between step S13 and step S14.

In step S13, first, one chromatic dispersion compensation value is set in the transmission-side transmission apparatus 10, and the BER of the received signal at that time is measured. Then, this BER measurement is repeated while changing the single chromatic dispersion compensation value in a wide range within a wide range. As a result, the first chromatic dispersion compensation value C ₀ ^* is detected in which the BER is equal to or less than a predetermined upper limit of BER (hereinafter referred to as “BER upper limit”). That is, here, the first chromatic dispersion compensation value C ₀ ^* is searched in coarse steps based on the BER of the received signal after step S12 under the control of the monitoring control device 30.

Next, in step S14, one chromatic dispersion compensation value around the first chromatic dispersion compensation value C ₀ ^* is set in the transmission-side transmission apparatus 10, and the BER of the received signal at that time is measured. Then, this BER measurement is repeated while changing the one chromatic dispersion compensation value within a narrow range around the first chromatic dispersion compensation value C ₀ ^{* in} smaller increments than before. As a result, the second chromatic dispersion compensation value C ₀ ^** having the minimum BER within the range is detected. That is, here, under the control of the supervisory control device 30, the second chromatic dispersion compensation value is finer than step S13 based on the first chromatic dispersion compensation value C ₀ ^* and the BER of the received signal after step S12. Search for C ₀ ^** .

Thereafter, in step S15, the second chromatic dispersion compensation value C ₀ ^** is set, and the filter pattern is searched and set. Hereinafter, the process of step S15 is demonstrated in order.

First, the second chromatic dispersion compensation value C ₀ ^** is set in the transmission apparatus 10 on the transmission side. That is, under the control of the supervisory control device 30, the transmission side transmission device 10 is made to perform chromatic dispersion compensation for the transmission signal based on the second chromatic dispersion compensation value C ₀ ^** . Note that the chromatic dispersion compensation value to be set in the transmission-side transmission apparatus 10 is fixed to the second chromatic dispersion compensation value C ₀ ^** during the search for the filter pattern described below.

  Next, as a search for the filter pattern, one filter pattern is set in the transmission device 10 from the same number of filter patterns as the number of nodes 42 on the optical path, and the BER of the received signal at that time is measured. Then, this series of processing is repeated while changing the one filter pattern by the number of nodes 42 in order. As a result, one filter pattern that minimizes the BER among the plurality of filter patterns described above is determined.

  For example, when the number of nodes 42 on the optical path (optical transmission line 40) is 3, the filter pattern of the lookup table (FIG. 2) is set to the initial value, (initial value + 1), (initial value + 2). In this way, by changing in three steps in the direction of increasing one by one, one filter pattern having the smallest BER is determined. In the following description, one filter pattern determined here may be referred to as a “determined filter pattern”.

Then, by setting a decision filter pattern in the transmission apparatus 10 on the transmission side, spectrum narrowing compensation is performed on the transmission signal. The determination filter pattern is determined based on the BER of the received signal after performing chromatic dispersion compensation with the second chromatic dispersion compensation value C ₀ ^** . Therefore, in other words, in the present embodiment, under the control of the monitoring control device 30, the transmission-side transmission device 10 performs spectrum narrowing compensation on the transmission signal based on the BER of the reception signal.

  In step S16, the transmission line adjustment as described above is completed.

  FIG. 4 is a diagram illustrating a sequence of steps S12 to S14. Hereinafter, this sequence will be described in detail with reference to FIG.

  First, the sequence of filter pattern initial value setting (step S12) surrounded by a dotted line on the upper side of FIG. 4 will be described. The monitoring control device 30 transmits a setting request for setting the initial value of the filter pattern to the transmission device 10 on the transmission side. Upon receiving the setting request, the transmission apparatus 10 on the transmission side transmits a filter pattern setting response to the monitoring control device 30, and then sets the initial value of the filter pattern specified in the setting request. That is, the transmission-side transmission device 10 performs spectrum narrowing compensation for the transmission signal to enable the transmission signal based on the initial value of the filter pattern. Thereafter, the transmission-side transmission device 10 transmits a filter pattern setting completion notification to the monitoring control device 30.

  Next, a description will be given of a sequence of coarse search for chromatic dispersion compensation values (step S13) surrounded by a dotted line in the center of FIG. Upon receiving the filter pattern setting completion notification, the monitoring control device 30 transmits a setting request for setting a chromatic dispersion compensation value to the transmission-side transmission device 10. When receiving the setting request, the transmission apparatus 10 on the transmission side transmits a chromatic dispersion compensation value setting response to the monitoring control device 30, and then sets the chromatic dispersion compensation value specified in the setting request. That is, the transmission-side transmission device 10 performs chromatic dispersion compensation on the transmission signal based on the chromatic dispersion compensation value. Thereafter, the transmitting-side transmission device 10 transmits a chromatic dispersion compensation value setting completion notification to the monitoring control device 30.

When receiving the chromatic dispersion compensation setting completion notification, the supervisory control device 30 transmits a BER measurement start request to the reception-side transmission device 20. When receiving the BER measurement start request, the reception-side transmission device 20 transmits a BER measurement start response to the monitoring control device 30 and then starts BER measurement. The reception-side transmission device 20 transmits a BER measurement result to the monitoring control device 30 by a BER measurement completion notification after completion of the BER measurement. The monitoring control device 30 records the BER measurement result in the memory 31. The monitoring control device 30 repeats a series of processes from the chromatic dispersion compensation value setting request surrounded by the dotted line shown in the center of FIG. 4 to the measurement result recording while changing the chromatic dispersion compensation value of the setting request. Thereby, the supervisory control device 30 determines the first chromatic dispersion compensation value C ₀ ^* described above.

FIG. 5 is a diagram illustrating an example of the search for the first chromatic dispersion compensation value C ₀ ^* performed here (step S13). Here, in order to be able to detect the first chromatic dispersion compensation value C ₀ ^* in a short time, the transmission side starts from a chromatic dispersion compensation value that is predicted from the type of the optical transmission line 40 and is specific to the type. Set in the transmission device 10. Here, a case where the chromatic dispersion compensation value C ₀ unique to the DCF is set as a start point will be described.

The supervisory control device 30 changes the chromatic dispersion compensation value to be set in the transmitting side transmission device 10 so as to gradually move away from the starting point C ₀ by the coarse step size Δη, and the measured BER is the above-described BER upper limit. When one chromatic dispersion compensation value as follows is obtained, it is set as the chromatic dispersion compensation value C ₀ ^* . The first chromatic dispersion compensation value C ₀ ^* detected here is a starting point in the search for the second chromatic dispersion compensation value C ₀ ^** .

After the sequence of step S13, returning to FIG. 4, the sequence of fine search for the chromatic dispersion compensation value (step S14) surrounded by the dotted line on the lower side of the diagram is performed. In this sequence, a sequence similar to the above-described sequence surrounded by a dotted line in the center of FIG. 4 is performed. That is, the monitoring control device 30 repeats a series of processes from the chromatic dispersion compensation value setting request surrounded by the dotted line shown in the lower side of FIG. 4 to the measurement result recording while changing the chromatic dispersion compensation value of the setting request. Thereby, the supervisory control device 30 determines the second chromatic dispersion compensation value C ₀ ^** described above.

FIG. 6 is a diagram illustrating an example of the search for the second chromatic dispersion compensation value C ₀ ^** (step S14) performed here. Here, first, the first chromatic dispersion compensation value C ₀ ^* detected earlier is set as the starting point. Then, the monitoring control device 30 changes the chromatic dispersion compensation value to be set in the transmission device 10 so as to increase from the start point C ₀ ^* by a small step size Δζ (<Δη) (FIG. 6). (I)), search for the chromatic dispersion compensation value C _{E +} ((ii) of FIG. 6) corresponding to the BER exceeding the BER upper limit. Hereinafter, this search is referred to as a positive search. When the supervisory control device 30 detects the chromatic dispersion compensation value C _{E +} , this time, the supervisory control device 30 changes the chromatic dispersion compensation value set in the transmission-side transmission device 10 so as to decrease by a small step size Δζ from the start point C ₀ ^*. Then, the chromatic dispersion compensation value C _E− (FIG. 6 (iv)) corresponding to the BER exceeding the BER upper limit is searched. Hereinafter, this search is referred to as a negative search.

When detecting the chromatic dispersion compensation value C _E− , the supervisory control device 30 determines the midpoint between the chromatic dispersion compensation values C _{E +} and C _E− as the second chromatic dispersion compensation value C ₀ ^** ((( v)). As described above, the middle point of the chromatic dispersion compensation values C _{E +} and C _E− is set as the second chromatic dispersion compensation value C ₀ ^** even if the chromatic dispersion value changes slightly due to a temperature change or the like. This is because signal conduction can be ensured.

  FIG. 7 is a diagram showing the sequence of step S15 described above after the sequence of steps S12 to S14 shown in FIG. 4 is completed. Hereinafter, this sequence will be described in detail with reference to FIG.

After determining the second chromatic dispersion compensation value C ₀ ^** , the supervisory control device 30 transmits a setting request for setting the second chromatic dispersion compensation value C ₀ ^** to the transmission-side transmission device 10. Upon receiving the setting request, the transmitting-side transmission device 10 transmits a chromatic dispersion compensation value setting response to the monitoring control device 30, and then sets the second chromatic dispersion compensation value C ₀ ^** . That is, the transmission-side transmission apparatus 10 performs chromatic dispersion compensation on the transmission signal based on the second chromatic dispersion compensation value C ₀ ^** . Thereafter, the transmitting-side transmission device 10 transmits a chromatic dispersion compensation value setting completion notification to the monitoring control device 30.

  Next, a filter pattern search sequence surrounded by a dotted line in FIG. 7 will be described. When receiving the chromatic dispersion compensation value setting completion notification, the supervisory control device 30 transmits a setting request for setting a filter pattern to the transmitting side transmission device 10. Upon receiving the setting request, the transmission apparatus 10 on the transmission side transmits a filter pattern setting response to the monitoring control device 30, and then sets the filter pattern specified in the setting request. That is, the transmission-side transmission device 10 performs spectrum narrowing compensation on the transmission signal based on the filter pattern. Thereafter, the transmission-side transmission device 10 transmits a filter pattern setting completion notification to the monitoring control device 30.

  When the monitoring control device 30 receives the filter pattern setting completion notification, the monitoring control device 30 transmits a BER measurement start request to the reception-side transmission device 20. When receiving the BER measurement start request, the reception-side transmission device 20 transmits a BER measurement start response to the monitoring control device 30 and then starts BER measurement. Upon completion of the BER measurement, the receiving-side transmission device 20 transmits the BER measurement result to the monitoring control device 30 with a BER measurement completion notification. The monitoring control device 30 records the BER measurement result in the memory 31. Then, the monitoring control device 30 changes the filter pattern of the setting request by the number of nodes 42 on the optical path, and performs a series of processing from the filter pattern setting request surrounded by the dotted line shown in FIG. 7 to the measurement result recording. repeat. Thereby, the monitoring control apparatus 30 determines the above-mentioned determination filter pattern.

After determining the decision filter pattern, the monitoring control device 30 transmits a setting request for setting the decision filter pattern to the transmission-side transmission device 10. Upon receiving the setting request, the transmitting-side transmission device 10 transmits a filter pattern setting completion notification to the monitoring control device 30, and then sets a determined filter pattern. That is, the transmission-side transmission device 10 performs spectrum narrowing compensation on the transmission signal based on the determined filter pattern. That is, the transmission-side transmission apparatus 10 performs spectrum narrowing compensation on the transmission signal based on the BER after the chromatic dispersion compensation is performed using the second chromatic dispersion compensation value C ₀ ^** . Thereafter, the transmission-side transmission device 10 transmits a filter pattern setting completion notification to the monitoring control device 30.

Monitoring control device 30, the second wavelength dispersion compensation value C ₀ ^** and decision filter pattern, for holding the transmitting side transmission equipment 10, in the memory storage requirements, ^** and determining second wavelength dispersion compensation value C ₀ The filter pattern is transmitted to the transmission apparatus 10 on the transmission side. The transmission side transmission apparatus 10 records the second chromatic dispersion compensation value C ₀ ^** and the determined filter pattern in the memory 13, and then transmits a memory storage response to the monitoring control apparatus 30. Thereafter, when the monitoring control device 30 transmits a BER measurement start request to the reception-side transmission device 20, it receives a BER measurement start response from the reception-side transmission device 20. Thereafter, the supervisory control device 30 receives the BER measurement completion notification including the BER measurement result from the reception side transmission device 20, and the second chromatic dispersion compensation value C ₀ ^** and the decision filter pattern are transmitted to the transmission side transmission device 10. Check that it has been set.

According to the optical transmission system and the optical transmission method according to the present embodiment as described above, spectral narrowing compensation is performed on the transmission signal, and the second chromatic dispersion compensation value C ₀ ^** is obtained by a two-stage search, Thereby, chromatic dispersion compensation is performed on the transmission signal. Therefore, spectral narrowing and chromatic dispersion can be appropriately compensated. Therefore, for example, in an existing optical transmission system provided with an optical filter 41 for a 10 Gbps signal, even if a 40 Gbps optical signal is transmitted from the transmission side transmission apparatus, the reception side transmission apparatus 20 receives a desired optical signal. The possibility can be increased. As a result, it is not necessary to make a major change to the existing optical transmission system, so that the cost can be suppressed. In addition, since the optical signals of 10 Gbps and 40 Gbps have different frequencies and hardly interfere with each other, both can be transmitted and received at the same time without providing a special device such as a changeover switch device. Therefore, cost can be suppressed also from this viewpoint.

  In addition, according to the optical transmission system and the optical transmission method according to the present embodiment, the transmission signal is received by the reception-side transmission device 20 from the transmission-side transmission device 10 via the node 42, that is, the optical signal. Is compensated for spectrum narrowing based on the number of nodes. Therefore, it is possible to increase the possibility that the transmission signal is conducted to the reception-side transmission device 20 in the initial stage.

  In the above description, the control for performing spectral narrowing compensation and chromatic dispersion compensation has been described as being performed by the supervisory control device 30, but is not limited to this, and is performed by the transmitting-side transmission device 10. Alternatively, it may be performed by the reception-side transmission device 20.

<Embodiment 2>
FIG. 8 is a flowchart showing a control procedure of the supervisory control device 30 provided in the optical transmission system according to Embodiment 2 of the present invention. Hereinafter, the control of the monitoring control device 30 will be described with reference to FIG. Hereinafter, in the description of the optical transmission system and the optical transmission method according to the present embodiment, components similar to those described in the first embodiment are denoted by the same reference numerals.

  The flowchart shown in FIG. 8 is obtained by adding step S21 between steps S15 and S16 in the flowchart shown in FIG. 3 described in the first embodiment. Therefore, only step S21 will be described below.

In step S21, the filter pattern is fixed and substantially the same processing as in step S14 is performed. Specifically, one chromatic dispersion compensation value around the second chromatic dispersion compensation value C ₀ ^** is set in the transmission-side transmission apparatus 10, and the BER of the received signal at that time is measured. Then, the one chromatic dispersion compensation value is set within the narrow range around the second chromatic dispersion compensation value C ₀ ^** (here, the chromatic dispersion compensation values C _{E− to} C _{E +} obtained in step S14). This BER measurement is repeated while changing in increments smaller than Δη of (for example, Δζ). As a result, the third chromatic dispersion compensation value C ₀ ^*** having the smallest BER in the range is detected. That is, here, under the control of the supervisory control device 30, from step 13 based on the search result of step S14 (range of chromatic dispersion compensation values C _{E− to} C _{E +} ) and the BER of the received signal after step S15. The third chromatic dispersion compensation value C ₀ ^*** is searched in fine steps.

Thereafter, the third chromatic dispersion compensation value C ₀ ^*** is set in the transmission-side transmission device 10. That is, under the control of the supervisory control device 30, the transmission-side transmission device 10 performs chromatic dispersion compensation for the transmission signal based on the third chromatic dispersion compensation value C ₀ ^*** .

  FIG. 9 is a diagram showing the sequence of step S21. Hereinafter, this sequence will be briefly described with reference to FIG.

First, after the sequence of step S15 described in the first embodiment is performed, a sequence of fine search for chromatic dispersion compensation values (step S21) surrounded by a dotted line in FIG. 9 is performed. In this sequence, the same sequence as the sequence of the fine search (step S14) of the chromatic dispersion compensation value surrounded by the dotted line on the lower side of FIG. 4 is performed. That is, the monitoring control device 30 repeats a series of processes from the chromatic dispersion compensation value setting request surrounded by the dotted line shown in FIG. 9 to the measurement result recording while changing the chromatic dispersion compensation value of the setting request. Thereby, the supervisory control device 30 determines the above-described third chromatic dispersion compensation value C ₀ ^*** .

After determining the third chromatic dispersion compensation value C ₀ ^*** , the supervisory control device 30 transmits a setting request for setting the third chromatic dispersion compensation value C ₀ ^*** to the transmission-side transmission device 10. To do. Upon receiving the setting request, the transmitting-side transmission device 10 transmits a chromatic dispersion compensation value setting response to the monitoring control device 30, and then sets the third chromatic dispersion compensation value C ₀ ^*** . That is, the transmission-side transmission device 10 performs chromatic dispersion compensation on the transmission signal based on the third chromatic dispersion compensation value C ₀ ^*** . Thereafter, the transmitting-side transmission device 10 transmits a chromatic dispersion compensation value setting completion notification to the monitoring control device 30. The subsequent processing after the memory storage request is the same as the processing after the memory storage request shown in FIG.

According to the optical transmission system and the optical transmission method according to the present embodiment as described above, chromatic dispersion compensation by the third chromatic dispersion compensation value C ₀ ^*** is performed on the transmission signal after the processing of the first embodiment. . Therefore, spectral narrowing and chromatic dispersion can be compensated more appropriately than in the first embodiment, so that the effect described in the first embodiment can be realized more reliably.

<Embodiment 3>
FIG. 10 is a flowchart showing a control procedure of the supervisory control device 30 provided in the optical transmission system according to Embodiment 3 of the present invention. Hereinafter, the control of the monitoring control device 30 will be described with reference to FIG. Hereinafter, in the description of the optical transmission system and the optical transmission method according to the present embodiment, components similar to those described in the first embodiment are denoted by the same reference numerals.

  The flowchart shown in FIG. 10 is obtained by changing step S15 in the flowchart shown in FIG. 3 described in the first embodiment to step S31. Therefore, step S31 will be mainly described below.

As described above, in step S14, when searching for the second chromatic dispersion compensation value C ₀ ^** , the BER upper limit or less (below a predetermined threshold) is around the first chromatic dispersion compensation value C ₀ ^* . A plurality of chromatic dispersion compensation values (C _{E− to} C _{E +} ) corresponding to BER are required.

In step S31, first, the chromatic dispersion compensation value to be set in the transmission apparatus 10 is fixed at C _E− . Then, as in step S15 described above, one filter pattern is set in the transmission-side transmission apparatus 10 from the same number of filter patterns as the number of nodes 42 on the optical path, and the BER of the received signal at that time is measured. . Then, this series of processing is repeated while changing the one filter pattern by the number of nodes 42 in order. Thereby, one filter pattern (referred to as “ _CE- filter pattern”) that minimizes the BER among the plurality of filter patterns described above is determined. This C _E- filter pattern is held in the memory 31 in the monitoring controller 30 together with the BER.

Subsequently, the chromatic dispersion compensation value to be set in the transmission apparatus 10 on the transmission side is fixed to (C _E− + Δζ). Then, by performing the same process as described above, one filter pattern (referred to as “(C _E− + Δζ) filter pattern”) having the smallest BER among the plurality of filter patterns described above is determined, and together with the BER It is held in the memory 31. This operation is performed until the one filter pattern (referred to as “C _{E +} filter pattern”) corresponding to the chromatic dispersion compensation value C _{E +} is held in the memory 31. Repeat while changing the value by Δζ.

Then, one of the C _E− filter patterns, (C _E− + Δζ) filter patterns,..., C _{E +} filter patterns held in the memory 31 is obtained as a filter pattern having the lowest BER. Here, obtaining one filter pattern having the lowest BER corresponds to obtaining a set of chromatic dispersion compensation values and filter patterns corresponding to the smallest BER.

As described above, in the present embodiment, a combination of a plurality of chromatic dispersion compensation values (C _{E− to} C _{E +} ) and the same number of filter patterns as the number of nodes 42 is controlled by the monitoring controller 30. In all cases, the transmission-side transmission apparatus 10 is made to perform chromatic dispersion compensation and spectrum narrowing compensation for the transmission signal. Then, for each combination, one combination corresponding to the smallest error rate is searched for among the BERs of the reception signals received by the reception-side transmission apparatus 20.

  Then, based on one chromatic dispersion compensation value and one filter pattern that are searched for under the control of the supervisory control device 30, the transmitting side transmission device 10 makes chromatic dispersion compensation and spectral narrowing compensation for the transmission signal. To do.

  According to the optical transmission system and the optical transmission method according to the present embodiment as described above, the combination of the chromatic dispersion compensation value and the filter pattern is obtained over a wider range than in the first embodiment, and the wavelength is determined based on the combination. Dispersion compensation and spectral narrowing compensation are performed. Therefore, spectral narrowing and chromatic dispersion can be compensated more appropriately than in the first embodiment, so that the effect described in the first embodiment can be realized more reliably.

<Embodiment 4>
In the above description, the second chromatic dispersion compensation value C ₀ ^** at the second stage is searched in fine steps, but this search method may take time. Therefore, in the optical transmission system and the optical transmission method according to Embodiment 4 of the present invention, a high-speed search for the chromatic dispersion compensation value that should be the second chromatic dispersion compensation value C ₀ ^** is possible. Hereinafter, in the description of the optical transmission system and the optical transmission method according to the present embodiment, components similar to those described in the first embodiment are denoted by the same reference numerals.

  FIG. 11 is a diagram showing an operation image of the high-speed search according to the present embodiment. In the present embodiment, the following control is performed instead of step S14 described above.

First, the first chromatic dispersion compensation value C ₀ ^* is used as a search start point, the chromatic dispersion compensation value is changed so as to gradually move away from C ₀ ^{* at} an interval of Δξ (> Δζ), and the measured BER is described above. The chromatic dispersion compensation value and the corresponding BER are acquired until the upper limit of BER is exceeded. Then, a characteristic curve (here, a quadratic regression curve using the least square method) is obtained based on the plurality of chromatic dispersion compensation values and the plurality of BERs. In the characteristic curve, the chromatic dispersion compensation value corresponding to the lowest BER is set as the second chromatic dispersion compensation value C ₀ ^** . Thereafter, the control in step S15 is performed.

According to the optical transmission system and the optical transmission method according to the present embodiment as described above, a wavelength corresponding to the above-described second chromatic dispersion compensation value C ₀ ^** is obtained using a characteristic curve instead of searching in fine steps. Search for dispersion compensation value. Therefore, the second chromatic dispersion compensation value C ₀ ^** can be searched at high speed.

  DESCRIPTION OF SYMBOLS 10 Transmission side transmission apparatus, 20 Reception side transmission apparatus, 30 Monitoring and control apparatus, 41 Optical filter, 42 nodes.

Claims (9)

A transmission device that transmits an optical signal as a transmission signal and performs spectral narrowing compensation and chromatic dispersion compensation on the transmission signal ;
A node having a filter ;
A receiving device for receiving the transmission signal as a reception signal via the node ;
With
A value based on the number of nodes is set to an initial value of a compensation value used for the spectrum narrowing compensation in the transmission device,
The compensation value of the chromatic dispersion compensation is searched based on the error rate of the reception signal with respect to the transmission signal subjected to the spectrum narrowing compensation using the initial value, and the compensation value obtained by the search is Ru is set to the compensation value to be used for the wavelength dispersion compensator, the optical transmission system. The search is
A first search for searching for a compensation value of the chromatic dispersion compensation in coarse increments based on an error rate of the received signal;
A second search for searching for a compensation value for the chromatic dispersion compensation in finer increments than the first search based on the compensation value obtained by the first search and the error rate of the received signal;
The optical transmission system according to claim 1, comprising: Instead of performing the second search, a characteristic curve is obtained based on a plurality of compensation values around the compensation value obtained in the first search and the error rates of the plurality of received signals corresponding thereto, and the characteristic curve is obtained. The optical transmission system according to claim 2, wherein a compensation value of the chromatic dispersion compensation is obtained based on the compensation value . A monitor control device that sets a filter pattern as a compensation value of the spectral narrowing compensation and a compensation value of the chromatic dispersion compensation in the transmission device;
The transmitter is
The spectrum narrowing compensation is performed with the filter pattern set by the supervisory control device, and the chromatic dispersion compensation is performed with a compensation value of the chromatic dispersion compensation set by the supervisory control device. Item 4. The optical transmission system according to Item 3 . Instead of performing the second search, around the compensation value obtained in the first search, a plurality of compensation values of the chromatic dispersion compensation corresponding to an error rate of the received signal below a predetermined threshold value are obtained, The reception device receives the chromatic dispersion compensation and spectral narrowing compensation for the transmission signal for all combinations of the chromatic dispersion compensation value and the plurality of filter patterns, and the reception device receives each of the combinations. Performing a third search for searching for one of the combinations corresponding to the smallest error rate of the signals;
Based on one chromatic dispersion compensation value and one filter pattern forming the one combination obtained in the third search, the transmitting apparatus performs chromatic dispersion compensation and spectrum narrowing compensation on the transmission signal. The optical transmission system according to claim 2 . In a transmission device that transmits an optical signal as a transmission signal, performs spectral narrowing compensation and chromatic dispersion compensation on the transmission signal, and a reception device that receives the transmission signal as a reception signal via a node having a filter An optical transmission method performed,
Setting a value based on the number of nodes to an initial value of a compensation value used for the spectrum narrowing compensation in the transmission device;
Searching for a compensation value of the chromatic dispersion compensation based on an error rate of the received signal with respect to the transmission signal subjected to the spectral narrowing compensation using the initial value;
Setting the compensation value obtained in the searching step to a compensation value used for the chromatic dispersion compensation in the transmitting device;
An optical transmission method comprising: The step of performing the search includes:
Performing a search for the compensation value of the chromatic dispersion compensation as a first search in coarse increments based on the error rate of the received signal;
A step of performing a search for the compensation value of the chromatic dispersion compensation as a second search at a finer step than the first search based on the compensation value obtained in the step of performing the first search and the error rate of the received signal. When
The optical transmission method according to claim 6, comprising: A transmission device that is connected to a reception device via a node having a filter and transmits an optical signal received as a reception signal by the reception device as a transmission signal,
A transmission side supervisory control unit for setting a compensation value for spectral narrowing compensation and a compensation value for chromatic dispersion compensation;
Spectral narrowing compensation based on the compensation value of spectral narrowing compensation set by the transmission side monitoring control unit, and chromatic dispersion compensation based on the compensation value of chromatic dispersion compensation set by the transmission side monitoring control unit A transmission-side main signal section for transmitting the transmission signal;
With
The transmission side monitoring control unit
A value based on the number of nodes is set to an initial value of a compensation value used for the spectrum narrowing compensation in the transmission main signal unit,
A search is made for a compensation value of the chromatic dispersion compensation based on an error rate of the reception signal with respect to the transmission signal subjected to the spectrum narrowing compensation using the initial value, and the compensation value obtained by the search is obtained as the transmission main signal. A transmission device that sets the compensation value used for the chromatic dispersion compensation in the unit. The search of the transmission side monitoring control unit is:
A first search for searching for a compensation value of the chromatic dispersion compensation in coarse increments based on an error rate of the received signal;
A second search for searching for a compensation value for the chromatic dispersion compensation in finer increments than the first search based on the compensation value obtained by the first search and the error rate of the received signal;
The transmission device according to claim 8, comprising:

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