JP4520097B2 - Dispersion compensation method for optical communication path with dynamic control - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a dispersion compensation method and system for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network that cooperates with the data transmission network. Dispersion compensation method and system for optical communication path for performing dynamic control to shorten reception data reproduction delay time by starting dispersion compensation between ends (End-to-End) before receiving an optical signal About.
[0002]
[Prior art]
As is well known, in high-speed optical transmission, signal degradation due to chromatic dispersion (CD) by an optical fiber on the transmission path is a problem.
[0003]
In general, a dispersion compensation fiber (DCF) is laid in an optical transmission line in order to avoid regenerating a transmission signal from a degraded signal due to chromatic dispersion (CD). However, in high-speed optical transmission, a dispersion compensation fiber is used. Signal degradation due to residual dispersion that cannot be compensated by (DCF) is also a problem.
[0004]
  Conventionally, in order to avoid such signal degradation due to residual dispersion, optical signal reception as described in Patent Document 1 and Non-Patent Document 1 is performed when performing dispersion compensation of an optical communication path.At the edgeA technique for performing variable dispersion compensation is known.
[0005]
  That is, Patent Document 1 discloses reception of an optical signal.At the edgeAs a technique for performing variable dispersion compensation, an optimization control method for dispersion compensation is described.
[0006]
Non-Patent Document 1 describes a technique for automatic dispersion fluctuation tracking compensation using a variable dispersion compensator as a technique for performing variable dispersion compensation after receiving an optical signal.
[0007]
On the other hand, in the path where the end of the optical signal (transmission point one reception point) is fixed, there is almost no change in the residual dispersion of the transmission line, so how to arrange the compensation points for dispersion compensation However, practically sufficient signal reproduction can be performed by setting the compensation value fixedly.
[0008]
However, a path (Label Switched Path, hereinafter abbreviated as LSP), which is currently being studied, such as ASON (Automatic Switched Optical Network) and GMPLS (Generalized Multi-Protocol Label Switching). Since it is generated and deleted, it can be considered that the end of the optical signal (transmission point-to-reception point) changes dynamically, and even its path is dynamically changed.
[0009]
As shown in FIG. 1, on the optical transmission line that realizes such an LSP, depending on in which section the dispersion compensation is performed, that is, from the node N1 serving as the transmitting end to the receiving end via the nodes N2 and N3 The difference between whether the chromatic dispersion unit compensation interval is between nodes or between ends (transmission point-to-reception point, hereinafter referred to as End-to-End) in the communication path to which the node N4 is connected Depending on the situation, how to deal with it varies greatly.
[0010]
First, when applying dispersion compensation between nodes, that is, for each link, the compensation amount itself does not change even when dynamic path setting or change is applied, so the same dispersion compensation method as before Can be adopted.
[0011]
That is, as shown in FIG. 2, the communication path A to which the node N1 serving as the receiving end is connected via the node N1 from the node N1 serving as the transmitting end and the node N3 via the node N3, or the node N1 to the node N2 serving as the transmitting end In the communication paths B and C to which the node N4 serving as the receiving end is connected via N5, when the unit compensation section is between nodes, chromatic dispersion is provided at the nodes N2, N3, N5, and N4. The dispersion compensators FC1, FC2, FC3, FC4, and FC5 are compensated for each node, and only the dispersion generated in the link between the two nodes is the object of compensation.
[0012]
In this case, since the number of dispersion compensators used is equal to the number of all links of the communication channels A, B, and C, the introduction / operation cost may increase, but the dispersion compensation amount does not depend on the LSP route. Since it is constant, it is considered that even a compensation in which the dispersion compensation value of the link is fixedly set can withstand practical use.
[0013]
However, when the unit compensation interval is between nodes, the dispersion compensator is installed inside the network, which limits the bit rate range that the network itself can transmit, and as described above, Installing a dispersion compensator for each link is likely to increase the introduction and operation costs of the entire system.
[0014]
As another method, a unit compensation interval is set between ends (End-to-End), and a method of performing collective compensation with a dispersion compensator provided at the reception end or transmission end of the residual dispersion of all LSP paths is also conceivable.
[0015]
However, as shown in FIG. 3, the communication path A to which the node N1 serving as the receiving end is connected through the node N1 from the node N1 serving as the transmitting end and the node N4 via the node N3, or the node N1 to the node N2 serving as the transmitting end. In the communication path B to which the node N4 serving as the receiving end is connected via N5, when the unit compensation interval is end-to-end, the chromatic dispersion is provided at the receiving end or the transmitting end. Since compensation is performed collectively by VC, dispersion generated in all paths of LSP must be compensated by a variable dispersion compensator VC provided at the receiving end or transmitting end.
[0016]
In this case, since the dispersion compensation amount itself varies depending on the LSP path, it cannot be handled by fixed dispersion compensation. Therefore, the dispersion compensation amount VC is controlled using a variable dispersion compensator VC which is a compensation device capable of dynamic control. There is a need.
[0017]
Further, in the method in which the unit compensation interval is set to end-to-end, in principle, the number of variable dispersion compensators VC is very small, that is, only one of the receiving end and the transmitting end, so that the cost is reduced. However, since it is necessary to dynamically detect the dispersion value and set the compensation value to the tunable dispersion compensator VC, it is expected that a delay time until signal reproduction will occur.
[0018]
As described above, there are the following merits and demerits as the network characteristics due to the difference in the dispersion compensation interval.
[0019]
First, inter-node compensation has the advantages of low path switching delay and high reliability, but has the disadvantage of high cost.
[0020]
On the other hand, end-to-end compensation has a demerit that the path switching delay is large, but has an advantage that the cost is low.
[0021]
That is, inter-node compensation and end-to-end compensation have mutually contradictory characteristics.
[0022]
Devices currently developed by vendors as nodes for high-speed optical transmission are already equipped with dispersion compensation devices. Therefore, these devices must be purchased and a network with compensation intervals between the nodes must be configured. Is possible.
[0023]
However, in the inter-node compensation, the introduction and maintenance costs are very expensive as compared with the end-to-end compensation network, and the bit rate range that can be transmitted is limited. Therefore, with the advancement of technology in the future, especially if the path switching delay time can be greatly shortened, a network having an end-to-end range as a compensation unit section may be configured for a communication carrier. It can be a realistic option.
[0024]
That is, in end-to-end compensation, signal dispersion can be achieved by installing a dispersion compensator only at the receiving end or transmitting end of an optical signal, so the introduction and operation costs of the entire network are low. It is because it can be suppressed to.
[0025]
In end-to-end compensation, devices such as cross-connects and the network itself can be configured independent of the transmission rate, so that in addition to the operational cost advantage, optical network expansion This is also because it has the advantage that it can maintain its sexuality and flexibility.
[0026]
However, with inter-node compensation, it is not necessary to control the dispersion compensator itself, but since a compensator must be installed for each link, the introduction and operation costs of the entire network as described above are very high. It will be big.
[0027]
Further, in the inter-node compensation, the dispersion compensator has a dependency on the wavelength and the transmission rate. Therefore, a network in which the dispersion compensator is introduced is disadvantageous in terms of expandability and flexibility.
[0028]
In such a network that performs inter-node compensation, there are serious problems that the introduction and operation costs are high and the expandability and flexibility of the network are poor.
[0029]
In the inter-node compensation, since the dispersion value does not change due to the generation of the LSP or the path change, a stable signal can be instantaneously reproduced without controlling the dispersion compensation device.
[0030]
On the other hand, in end-to-end compensation, the dispersion value changes due to LSP generation / path change, so that it is necessary to instantaneously detect the dispersion value and to quickly control the dispersion compensation device. .
[0031]
In this way, in the case of end-to-end compensation in which collective compensation is performed at the receiving end or the transmitting end, the amount of residual dispersion also dynamically changes due to dynamic change of the path. Control is required.
[0032]
Therefore, in order to realize this, it is necessary to measure the amount of dispersion of the received signal and dynamically add compensation according to the amount of dispersion, so there is a high possibility that a delay time until signal reproduction will occur. .
[0033]
That is, the time spent for detecting and controlling the dispersion value required for end-to-end compensation is the loss time until signal regeneration at the receiving end, so that protection / recovery ( At the time of (Restoration) operation, there is a problem in that the loss time until the signal reproduction at the receiving end is reflected as it is as the instantaneous interruption time at the time of path switching.
[0034]
Therefore, from the viewpoint of network reliability, inter-node compensation is a stable method that can instantly cope with switching between protection (protection) and restoration (restoration).
[0035]
However, in end-to-end compensation, it is difficult to provide a highly reliable network unless the required dispersion value detection and control time is shortened.
[0036]
In this case, since the control time is proportional to the dispersion value, it is considered that the control time is increased in the core network having a large dispersion value.
[0037]
Therefore, end-to-end compensation is a best-effort network service in the short term, for example, in the metropolitan area network (MAN), which has high expandability and flexibility in line with future demand trends. Providing is considered realistic.
[0038]
On the other hand, according to Non-Patent Document 2 and Non-Patent Document 3, from the viewpoint of transmission characteristics, compensation by a compensation value that is not 100% compared to a case where 100% compensation is performed for each link by a dispersion compensating fiber (DCF). For example, it is known that better transmission characteristics can be obtained when 90% compensation or 110% compensation is performed.
[0039]
[Patent Document 1]
JP 2002-208992 A
[0040]
[Non-Patent Document 1]
Sugihara (3 others) “Automatic tracking compensation of dispersion fluctuation of 40Gb / s optical transmission line using grating type tunable dispersion compensator” 2002 IEICE General Conference B-10-180 p617
[0041]
[Non-Patent Document 2]
B. Zhu et al. "Experimental Investment of Dispersion Map for 40x10 Gb / s Transmission over 1600 km of Fiber with 3 FC NupripTripAmp3
[0042]
[Non-Patent Document 2]
Y. Su et al. "40Gb / s transmission over 2000km of nonzero-dispersion fiber using 100-km amplifier spacing" OFC2002 pp609-610
[0043]
[Problems to be solved by the invention]
  Reception of optical signals as described in Patent Document 1 and Non-Patent Document 1 described above.At the edgeThe existing dispersion compensation technology that performs variable dispersion compensation is an optical signal.ofReceiveLight at the edgeIt detects the dispersion value of the signal and adds appropriate compensation.
[0044]
However, with these techniques alone, when performing dynamic control of the communication path, a great amount of time is required until the communication path is stabilized, and in particular, by end-to-end compensation. Performing dispersion compensation causes a fatal disconnection time in switching the communication path when a failure occurs.
[0045]
Also, from the viewpoint of transmission characteristics, X% (where X ≠ 100) compensation is performed for each link, not 100% compensation for each link, and X% (X ≠ 100) compensation for each link. A better transmission characteristic can be obtained when dispersion compensation is performed at the transmitting end or receiving end to compensate for the excess or deficiency with respect to the sum of the link dispersion values.
[0046]
The present invention has been made in view of the above circumstances, and dispersion compensation of an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network. A method of performing dynamic control for shortening a reception data reproduction delay time by starting end-to-end dispersion compensation before receiving an optical signal. An object is to provide a dispersion compensation method and system for a communication path.
[0047]
Further, the present invention is a dispersion compensation method for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network, as described above, By starting the end-to-end dispersion compensation of the optical communication path before receiving the optical signal, the received data reproduction delay time is shortened and X% (where X ≠ 100) Dynamic control in which good transmission characteristics can be obtained for the entire optical transmission line by performing compensation and compensating for excess and deficiency with respect to the total sum of link dispersion values by X% compensation throughout the entire link. An object of the present invention is to provide a dispersion compensation method and system for an optical communication path that performs the above.
[0048]
[Means for Solving the Problems]
In the present invention, when performing dispersion compensation (end-to-end dispersion compensation) between ends (end-to-end) in an optical communication path that performs dynamic control, the optimum dispersion compensation value is detected and the compensation device In view of the fact that the reduction of time spent for control greatly contributes to the improvement of network reliability using this method.
[0049]
Further, in the present invention, in addition to shortening the signal reproduction delay time described above, X% (where X ≠ 100) compensation is performed for each link from the viewpoint of transmission characteristics, and X% compensation is performed throughout the link. It is considered that good transmission characteristics can be obtained for the entire optical transmission line by compensating for the excess and deficiency with respect to the sum of the link dispersion values.
[0050]
For this reason, the present invention not only expects that the time spent for detecting the optimum dispersion compensation value and controlling the compensation device can be improved as each elemental technology improves, but also for device elements and measurements. This is not done by improving the algorithm, but by linking with network control technology.
[0051]
  That is, in the present invention, as shown in FIG.ofReceiveLight at the edgeInstead of detecting the dispersion value of the signal and adding appropriate end-to-end dispersion compensation, as shown in FIG. 4B, the end-to-end ( By starting the end-to-end) dispersion compensation before receiving the optical signal, it is possible to realize a dispersion compensation method and system for an optical communication path that performs dynamic control to shorten the signal reproduction delay time. .
[0052]
In the present invention, in addition to shortening the signal reproduction delay time described above, as a transmission characteristic, X% (where X ≠ 100) compensation is performed for each link, and each of the nodes by X% compensation is performed throughout the link. It is possible to realize a dispersion compensation method and system for an optical communication path that performs dynamic control so that good transmission characteristics can be obtained for the entire optical transmission line by compensating for excess and deficiency with respect to the sum of inter-dispersion values. It is said.
[0053]
  Therefore, in order to achieve the above object, according to the first aspect of the present invention, dynamic control is performed using a data transmission network using an optical fiber and a network control network linked to the data transmission network. A dispersion compensation method for an optical communication path, wherein, in the network control network, a specific transmission end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path A dispersion value presenting step for presenting a total sum of dispersion values by the optical fiber laid between the nodes in a plurality of nodes existing on a communication path from a specific receiving end to the specific receiving end, and a dispersion presented by the dispersion value presenting step Before establishing a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request based on the sum of the values, A dispersion compensation control step for starting compensation of total dispersion by the optical fiber in the communication path for a fixed receiving end, and the dispersion value presentation step should be generated in response to the communication path control request The direction from the transmitting end to the receiving end using the communication path control request for each node in a plurality of nodes existing in the communication path from the specific transmitting end to the specific receiving end of the data transmission network Then, the sum of the dispersion values of the specific receiving end is obtained from the specific transmitting end while adding the dispersion value due to the optical fiber laid between the nodes, and the sum of the obtained dispersion values is determined as the specific A dispersion compensation method for an optical communication path that performs dynamic control, characterized by being presented to the receiving end of the optical communication path.
According to a second aspect of the present invention, there is provided a dispersion compensation method for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network. In the network control network, a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. A dispersion value presenting step for presenting a sum of dispersion values by the optical fiber laid between the nodes in a plurality of existing nodes, and the communication path based on the sum of dispersion values presented by the dispersion value presenting step Before a communication path from a specific transmitting end of the data transmission network to a specific receiving end is established to be generated in response to a control request, the communication path is set to the specific transmitting end. ; And a dispersion compensation control step of starting the total dispersion compensation by the optical fiber, the dispersion value presentation step,
The response of the communication path control request is used for each node in a plurality of nodes existing in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request. Then, in the direction from the receiving end to the transmitting end, the sum of the dispersion values from the specific transmitting end to the specific receiving end is added while adding the dispersion value due to the optical fiber laid between the nodes. A dispersion compensation method for an optical communication path that performs dynamic control, characterized in that it is obtained and presents the sum of the obtained dispersion values to the specific transmission end.
  According to a third aspect of the present invention, there is provided a dispersion compensation method for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network. In the network control network, a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. A dispersion value presenting step for presenting a sum of dispersion values by the optical fiber laid between the nodes in a plurality of existing nodes, and the communication path based on the sum of dispersion values presented by the dispersion value presenting step Before a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a control request is established, the communication path is set to the specific reception end. A dispersion compensation control step for starting compensation of total dispersion by the optical fiber, and the dispersion value presenting step is performed from a specific transmission end of the data transmission network to be generated in response to the communication path control request. Based on the notification of the communication path to the receiving end, the dispersion value management server in the network control network obtains the sum of dispersion values by the optical fiber laid between the nodes in the plurality of nodes existing in the communication path. A dispersion compensation method for an optical communication path that performs dynamic control, which is presented to the specific receiving end of the communication path.
  According to a fourth aspect of the present invention, there is provided a dispersion compensation method for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network. In the network control network, a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. A dispersion value presenting step for presenting a sum of dispersion values by the optical fiber laid between the nodes in a plurality of existing nodes, and the communication path based on the sum of dispersion values presented by the dispersion value presenting step Before a communication path from a specific transmitting end of the data transmission network to a specific receiving end is established to be generated in response to a control request, the communication path is set to the specific transmitting end. A dispersion compensation control step for starting compensation of total dispersion by the optical fiber, and the dispersion value presenting step is performed from a specific transmission end of the data transmission network to be generated in response to the communication path control request. Based on the communication path to the receiving end, the communication is obtained by obtaining the sum of dispersion values by the optical fiber laid between the nodes in the plurality of nodes existing in the communication path by the dispersion value management server in the network control network. A dispersion compensation method for an optical communication path that performs dynamic control, characterized by being presented to the specific transmission end of the path.
  According to the fifth aspect of the present invention, it is used in a dispersion compensation system for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network. The dispersion compensation system, wherein the dispersion compensation system of the data transmission network is generated in response to a communication path control request relating to a wavelength path that requires dynamic control of the communication path in the network control network. Dispersion value presenting means for presenting a sum of dispersion values by the optical fiber laid between the nodes in a plurality of nodes existing on a communication path from a specific transmitting end to a specific receiving end, and presenting the dispersion value presenting Means is present in the communication path based on a communication path notification from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request. A dispersion value management server in the network control network obtains the inter-node dispersion value by the optical fiber laid between the nodes in the plurality of nodes and the sum of the dispersion values between the nodes, of the plurality of nodes A dispersion value for performing X% (where X ≠ 100) compensation of the dispersion value between the nodes is presented to at least one node, and is provided at at least one of the specific reception end and transmission end. Presenting a dispersion value for executing dispersion compensation for compensating for excess or deficiency with respect to the sum of dispersion values between the nodes by X% (X ≠ 100) compensation for the at least one node to the variable dispersion compensator; The dispersion compensation control device should generate a response to the communication path control request based on the sum of dispersion values presented by the dispersion value presenting means. Before the communication path from the specific transmission end to the specific reception end of the data transmission network is established, dynamic control is performed, in which compensation of total dispersion by the optical fiber in the communication path is started. An optical communication path dispersion compensation control device.
[0089]
DETAILED DESCRIPTION OF THE INVENTION
First, an outline of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention will be described.
[0090]
So far, in this type of dispersion compensation, only the dispersion compensation device control technology has been discussed, so it is considered that there is no way to solve the above problems other than improving the control speed of the dispersion compensation device. Yes.
[0091]
However, in the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention, the control of the network control system and the variable dispersion compensator is linked, and the variable dispersion compensator before receiving the optical signal at the receiving end. By starting the control, the total delay time from the communication path control request to the reception data reproduction can be shortened.
[0092]
Specifically, in the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention, an approximate value of the dispersion value to be compensated simultaneously with the communication path control request is provided at the receiving end or the transmission end. By notifying the compensator, the control of the tunable dispersion compensator is started before the optical signal is transmitted to the communication path.
[0093]
Thus, in the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention, it is possible to reduce the time from the completion of the dispersion compensation to the normal reproduction of the received data from the communication path control request. Can do.
[0094]
In the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention, several methods are conceivable as methods for informing the compensation point of the dispersion value of the signal light at the reception end or transmission end. Here, a dispersion cooperative dispersion compensation method and a centralized management dispersion compensation method are presented as specific examples.
[0095]
First, in the distributed cooperative dispersion compensation method, the dispersion value of the link to which the node confidence is connected is managed and added as the dispersion value of the path when the LSP is generated. A method is adopted in which dispersion values for the entire LSP are automatically passed to the dispersion compensator.
[0096]
In the centralized dispersion compensation method, a link dispersion value management server as a chromatic dispersion value management server is separately provided, and after calculating the LSP route, the sum of dispersion values on the route is sent from the link dispersion value management server to the signal receiving end or A method of notifying the tunable dispersion compensator provided at the compensation point at the transmission end is adopted.
[0097]
(Basic embodiment)
Next, a basic embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention based on the above outline will be described.
[0098]
FIG. 5 is a block diagram shown for explaining the fundamental configuration of the main part to which the basic embodiment of the dispersion compensation method and system for optical communication paths for performing dynamic control according to the present invention is applied.
[0099]
That is, as shown in FIG. 5, the present invention uses a data transmission network 11 that uses an optical fiber as a communication path and a network control network 12 that cooperates with the data transmission network 11 to dynamically change the communication path. The present invention is applied to a dispersion compensation method and system for an optical communication path that performs control.
[0100]
Here, in the data transmission network 11, an optical signal transmission unit 111 and an optical signal reception unit 112 which are signal transmission ends and reception ends of communication paths to be generated by dynamic control of the communication path are set.
[0101]
Between the optical signal transmitter 111 and the optical signal receiver 112, a transmission path and a transmission node 113 that receive a transmission signal from the optical signal transmitter 111, and variable dispersion that receives a degradation signal from the transmission path and the transmission node 113. The compensation device 114 is set.
[0102]
Then, the optical signal receiving unit 112 receives an optical signal for data reproduction subjected to dispersion compensation by the variable dispersion compensator 114 as will be described later.
[0103]
Note that FIG. 5 shows a case where the tunable dispersion compensator 114 is set on the optical signal receiving unit 112 side serving as a receiving end, but the optical signal transmitting unit 111 side serving as the transmitting end. It may be set to.
[0104]
On the other hand, the network control network 12 linked to the data transmission network 11 has a communication path closely linked to the optical signal transmission unit 111 and the transmission path and transmission node 113 set in the data transmission network 11. A control request unit 121 and a network control unit 122 that receives this communication path control request are set.
[0105]
A dispersion compensator controller 123 is set between the network controller 122 and the variable dispersion compensator 114.
[0106]
Note that the network control unit 122 in the network control network 12 has a specific transmission end to a specific reception end of the data transmission network 11 to be generated in response to a communication path control request for requesting dynamic control of the communication path. It functions as a dispersion value presentation device that presents the sum of dispersion values by optical fibers laid on the communication path.
[0107]
Further, the network control unit 122 is configured to generate a specific reception end from a specific transmission end of the data transmission network to be generated in response to the communication path control request based on the sum of the distribution values presented by the dispersion value presentation device. Before establishing the communication path to the variable dispersion compensator 114 provided on at least one side of the specific transmission end and the specific reception end in the communication path via the dispersion compensation apparatus control unit 123. It also functions as a dispersion compensation control device for starting dispersion compensation by the optical fiber in the communication path.
[0108]
FIG. 6 is a processing sequence diagram shown for explaining the principle operation procedure of the main part to which the dispersion compensation method and system for an optical communication path performing dynamic control according to the present invention is applied.
[0109]
That is, as shown in FIG. 6, when there is a communication path control request from the optical signal transmission section 111 or the communication path control request section 121 of the network control network 12 (step S1), a communication path control request from the network control section 122. And a control command is sent to the transmission line of the data transmission network 11 and the transmission node 113, thereby selecting a transmission line for setting a communication path to be generated by dynamic control of the communication path (step S2). .
[0110]
Then, based on the result of the transmission path selection, network control for setting a communication path to be generated by dynamic control of the communication path is performed by the network control unit 122 (step S3).
[0111]
In parallel with this network control, the network control unit 122 of the network control network 12 compensates at the reception end (or transmission end) by calculating a compensation value based on the communication path control request from the communication path control request unit 121. When the sum of the power dispersion values is calculated, a compensation value notification for notifying the dispersion compensation device controller 123 of the sum of the dispersion values as a compensation value is executed (step S4).
[0112]
In step S4, a communication path from a specific transmission end to a specific reception end of the data transmission network 11 to be generated in response to a communication path control request for requesting dynamic control of the communication path in the network control network 12. It functions as a dispersion value presenting step for presenting the sum of dispersion values by the optical fiber laid on the surface.
[0113]
Then, the dispersion compensator control unit 123 controls the dispersion compensator 114 to perform dispersion compensation based on the notified compensation value (step S5).
[0114]
This step S5 is a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated according to the communication path control request based on the sum of the dispersion values presented by the dispersion value presentation step. Is established, at least one of the specific transmitting end and the specific receiving end in the communication path is compensated for the total dispersion by the optical fiber in the communication path. Functions as a dispersion compensation control step.
[0115]
As a result, the optical signal receiver 112 reproduces the received data based on the optical signal that has been subjected to dispersion compensation by the tunable dispersion compensator 114 (step S6).
[0116]
That is, in the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention, as an optical communication path that performs dynamic control, for example, when a communication path (LSP) control request for high-speed optical communication occurs, The chromatic dispersion values of the optical transmission lines constituting the communication path to be requested are integrated, and the chromatic dispersion values of the entire communication path are calculated and presented.
[0117]
In the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention, the chromatic dispersion value of this optical transmission path is integrated, and the processing for calculating and presenting the chromatic dispersion value of the entire communication path is performed. By performing in parallel with the path control process, it becomes possible to control the variable dispersion compensator at the receiving end or the transmitting end before receiving the optical signal, and to shorten the time until the reception data reproduction at the receiving end. .
[0118]
As described above, the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention has been improved to present not only received light but also a dispersion value to be compensated using a network control system. Dispersion compensation processing can be performed in advance in a series of communication path setting procedures, and the merit that the time for communication path control can be shortened is obtained.
[0119]
That is, since the chromatic dispersion at the receiving end of the LSP is substantially equal to the sum of dispersion values in the links between the nodes on the path, if the LSP path is determined by the network control system, the chromatic dispersion immediately The total dispersion value to be compensated for at the receiving end or the transmitting end can be obtained.
[0120]
Furthermore, if the processing for obtaining the total dispersion value to be compensated at the receiving end or transmitting end can be performed before the end of the LSP generation processing, the overhead at the time of path switching can be shortened.
[0121]
In FIG. 5, the data transmission network 11 is shown in a simplified manner, but actually, the data transmission network 11 includes a large number of networks coupled to each other. A communication path to be generated is set by dynamic control.
[0122]
As the variable dispersion compensator 114 provided on one side of the specific transmission end or specific reception end in the set communication path, the nodes or edge portions of a large number of networks coupled to each other as described above The existing tunable dispersion compensator provided in can be used.
[0123]
And according to the present embodiment, a dispersion compensation system for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network, In the network control network, the data transmission network is laid on a communication path from a specific transmission end to a specific reception end to be generated in response to a communication path control request for requesting dynamic control of the communication path. A dispersion value presentation device that presents the sum of dispersion values by optical fibers, and the data transmission network to be generated in response to the communication path control request based on the sum of dispersion values presented by the dispersion value presentation device Variable dispersion provided at least on one side of the specific transmission end and the specific reception end in the communication path before the communication path from the transmission end to the specific reception end is established A dispersion compensation system for an optical communication path that performs dynamic control is realized, comprising a dispersion compensation control device that starts compensation for total dispersion by the optical fiber in the communication path for the compensator Is done.
[0124]
In the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention, as described above, as a method of notifying the compensation point of the dispersion value of the signal light at the reception end or the transmission end, dispersion coordination is used. Type dispersion compensation method and centralized management type dispersion compensation method are presented as specific examples.
[0125]
The details of the dispersion cooperative dispersion compensation method and the centralized management dispersion compensation method will be described in the following specific first to sixth embodiments.
[0126]
(Specific First Embodiment)
FIG. 7 and FIG. 8 show dispersion compensation type dispersion compensation by receiving end compensation as a first concrete embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention. It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part to which a system is applied.
[0127]
That is, as shown in FIG. 7, in the dispersion cooperative dispersion compensation method by receiving end compensation according to this embodiment, each of the nodes N1, N2, N3, and N4 is connected to each link. , For example, “0”, “10”, “5”, “2” are held as respective databases.
[0128]
In this case, the node N5 is excluded from the target of route selection based on the LSP setting request to be described later (if there is no particular description of the node N5, other embodiments will also be described). The same shall apply).
[0129]
First, a node N1 (transmission end) that issues an LSP setting request generates a setting request message Req with a dispersion value of “0” and transmits it to the downstream node N2.
[0130]
The downstream node N2 that has received the setting request message Req based on this LSP setting request determines a link to be used with the upstream node for the requested LSP setting, and the upstream node N1. The link dispersion value “10” is added to the message “0” received from the message “0” and transferred to the downstream node N3 as the message Req “10”.
[0131]
The node N3 that has received this message Req “10” determines the link to be used with the upstream node for the requested LSP setting, and receives the message Req ”received from the upstream node N2. The message Req “15” obtained by adding the link dispersion value “5” to 10 ”is transferred to the downstream node N4 (receiving end).
[0132]
The node N4 (receiving end) that has received this message Req “15” adds the link dispersion value “2” to the message Req “15” and is provided at the node N4 (receiving end). A compensation value “17” is set for the tunable dispersion compensator 100.
[0133]
Next, as shown in FIG. 8, in the dispersion cooperation type dispersion compensation method by receiving end compensation according to the present embodiment, the LSP receiving end (node N4) that has received the LSP setting message Req as described above. While the given compensation value is set, a reply message Ack to the request message Req as a control message is sequentially returned toward the upstream nodes N3, N2, and N1.
[0134]
After this reply message Ack arrives at the LSP transmission end (node N1), an actual optical signal is transmitted on the LSP from the LSP transmission end (node N1), and this optical signal is transmitted as shown in FIG. The signals are received by the LSP receiving end (node N4) in a state in which deterioration due to dispersion is compensated via the nodes N2 and N3 and the variable dispersion compensator 100.
[0135]
If the setting operation of the tunable dispersion compensator 100 is sufficiently high, the setting of the tunable dispersion compensator 100 is completed before receiving the optical signal at the LSP receiving end (node N4), and the LSP receiving end ( The signal reproduction delay at node N4) can be made zero.
[0136]
That is, in this embodiment, the dispersion value of the link to which each node itself is connected is managed and added as the dispersion value of the path when the LSP is generated, and the entire LSP is automatically generated at the signal receiving end. Thus, a dispersion compensation system for an optical communication path that performs dynamic control based on a dispersion-coordinated dispersion compensation scheme based on reception end compensation in which a dispersion value at 1 is passed to a variable dispersion compensator is realized.
[0137]
In the present embodiment, although not shown, as the network control network 12 that cooperates with the data transmission network 11, the optical signal transmission unit 111, the transmission path, and the transmission node that are set as the data transmission network 11 are used. 113 (each node N1, N2, N3, N4) and a network control unit 122 that receives a communication path control request from the communication path control request unit 121. Is set.
[0138]
In each of the nodes N1, N2, N3, and N4, it is held as each database that holds the dispersion value of the link to which the node is connected, and is used as a route dispersion value at the time of LSP generation. The function of adding these values and automatically presenting the dispersion value in the entire LSP at the signal receiving end corresponds to the function as the dispersion value presentation device.
[0139]
In addition, the tunable dispersion compensator 100 provided at the signal receiving end (node N4) starts compensation for dispersion by the optical fiber in the communication path based on the dispersion value presented by the dispersion value presentation device. This function corresponds to the function as the dispersion compensation control device.
[0140]
Then, according to the present embodiment, this dispersion compensation control device notifies the total dispersion value presented by the dispersion value presentation device to at least the variable dispersion compensator provided at the specific receiving end. Thus, a dispersion compensation system for an optical communication path that performs dynamic control, characterized by starting compensation for total dispersion by the optical fiber in the communication path, is realized.
[0141]
In addition, according to the present embodiment, a plurality of the distributed value presenting devices exist in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request. For each node in each node, the specific dispersion end compensator provided at the specific reception end while adding the dispersion value due to the optical fiber laid between the nodes, the specific transmission end side from the specific transmission end side A dispersion compensation system for an optical communication path that performs dynamic control, characterized by executing dispersion-coordinated dispersion value presentation that is presented in a forward-feed manner toward the receiving end side of the receiver.
[0142]
(Specific Second Embodiment)
FIG. 9 and FIG. 10 show that a dispersion cooperative dispersion compensation method based on transmission end compensation is applied as a specific second embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention. It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part made.
[0143]
That is, in the present embodiment, as another dispersion cooperative dispersion compensation method, a variable dispersion compensator is placed on the transmission end side, and the sum of dispersion values of each link is calculated using an LSP control request message. The optical signal optimized by the variable dispersion compensator on the transmission end side is transmitted so that the received optical signal is optimized.
[0144]
First, as shown in FIG. 9, in the dispersion-coordination-type dispersion compensation method based on transmission end compensation according to this embodiment, each of the nodes N4, N3, N2, and N1 is connected to each node. , For example, “0”, “2”, “5”, “10” are held as respective databases.
[0145]
Then, as shown in FIG. 9, the node N1 (transmission end) that issues the LSP setting request generates the setting request message Req and sequentially transmits it to the downstream nodes N2, N3, and N4. .
[0146]
Next, as shown in FIG. 10, in the dispersion coordination type dispersion compensation method using transmission end compensation according to this embodiment, the LSP receiving end (node N4) that has received the LSP setting message Req as described above. In order to set the given compensation value, the dispersion value “0” is sequentially returned to the upstream node N3 as a response message Ack to the request message Req as a control message.
[0147]
Then, as shown in FIG. 10, the upstream node N3 that has received this response message Ack “0” determines the link to be used with the downstream node for the requested LSP setting, The distribution value “2” of the link is added to the response message Ack “0” received from the downstream node N4, and the response message Ack “2” is transferred to the upstream node N2.
[0148]
The node N2 that has received the response message Ack “2” determines the link to be used with the downstream node for the requested LSP setting, and receives the response message from the downstream node N3. The dispersion value “5” of the link is added to Ack “2”, and is transferred as a response message Ack “7” to the upstream node N1 (transmission end).
[0149]
The node N1 (transmission end) that has received this response message Ack “7” adds the link dispersion value “10” to the response message Ack “7” received from the downstream node N2 (7 + 10 = 17). Then, it is set as a compensation value “17” for the tunable dispersion compensator 100 provided at the node N1 (transmission end).
[0150]
After the response message Ack arrives at the LSP transmission end (node N1), an actual optical signal is transmitted from the LSP transmission end (node N1) onto the LSP, and this optical signal is variable as shown in FIG. The signal is received by the LSP receiving end (node N4) in a state in which deterioration due to dispersion is compensated through the dispersion compensator 100 and nodes N2 and N3.
[0151]
If the setting operation of the tunable dispersion compensator 100 is sufficiently fast, the setting of the compensation value for the tunable dispersion compensator 100 is completed before the optical signal is received at the LSP receiving end (node N4). In addition, the signal reproduction delay at the LSP receiving end (node N4) can be set to zero.
[0152]
That is, in this embodiment, the dispersion value of the link to which each node itself is connected is managed and added as the dispersion value of the path when the LSP is generated, and the entire LSP is automatically added at the signal transmission end. Thus, a dispersion compensation system for an optical communication path that performs dynamic control based on a dispersion-coordinated dispersion compensation scheme based on transmission end compensation in which a dispersion value at 1 is passed to a variable dispersion compensator is realized.
[0153]
In the present embodiment, although not shown, as the network control network 12 that cooperates with the data transmission network 11, the optical signal transmission unit 111, the transmission path, and the transmission node that are set as the data transmission network 11 are used. 113 (each node N1, N2, N3, N4) and a network control unit 122 that receives a communication path control request from the communication path control request unit 121. Is set.
[0154]
In each of the nodes N1, N2, N3, and N4, it is held as each database that holds the dispersion value of the link to which the node is connected, and is used as a route dispersion value at the time of LSP generation. The function of adding these values and automatically presenting the dispersion value in the entire LSP at the signal receiving end corresponds to the function as the dispersion value presentation device.
[0155]
In addition, the tunable dispersion compensator 100 provided at the signal transmission end (node N1) starts compensation for dispersion by the optical fiber in the communication path based on the dispersion value presented by the dispersion value presentation device. This function corresponds to the function as the dispersion compensation control device.
[0156]
Then, according to the present embodiment, this dispersion compensation control device notifies the total dispersion value presented by the dispersion value presentation device to at least the variable dispersion compensator provided at the specific transmission end. Thus, a dispersion compensation system for an optical communication path that performs dynamic control, characterized by starting compensation for total dispersion by the optical fiber in the communication path, is realized.
[0157]
In addition, according to the present embodiment, a plurality of the distributed value presenting devices exist in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request. For each node in the node, the specific dispersion end compensator provided at the specific transmission end is added from the specific reception end side while adding the dispersion value by the optical fiber laid between the nodes. A dispersion compensation system for an optical communication path that performs dynamic control, which is characterized by executing dispersion-coordinated dispersion value presentation that is presented in a forward-feed manner toward the transmitting end side of the optical communication path, is realized.
[0158]
In the dispersion compensation system for an optical communication path that performs dynamic control using the dispersion cooperative dispersion compensation method according to the specific first and second embodiments as described above, a variable dispersion compensator is transmitted. Each node needs to manage the dispersion value of the connected link inside the node, regardless of whether the node is provided on the receiving side or the receiving side.
[0159]
As the dispersion value, a static numerical value measured at the time of link introduction may be used, but a mechanism for dynamically measuring between the opposite nodes sharing the link is introduced and periodically It is desirable to update to the latest measured value.
[0160]
Each node needs to manage a route table for request message transfer, which is realized by using an existing IP (Internet Protocol) technology using OSPF (Open Shortest Path First) or the like. It is possible.
[0161]
FIG. 11A shows an example of the link distribution value table 150 to be managed by the node A connected to the four opposing nodes B, C, D, and E, as shown in FIG. Show.
[0162]
That is, in this example, as the link distribution value table 150, the distribution value (CD) of the link between the nodes A and B (Link1) is “5”, and the distribution value (CD) of the link between the nodes A and C (Link2). Is “10”, the dispersion value (CD) of the link between the nodes A and D (Link 3) is “7”, and the dispersion value (CD) of the link between the nodes A and E (Link 4) is “9”. Show.
[0163]
Further, in the dispersion compensation system for an optical communication path that performs dynamic control by the dispersion cooperative dispersion compensation method according to the specific first and second embodiments as described above, the dispersion value is calculated. In the message used for the above, fields as shown in FIGS. 12A and 12B are required at a minimum.
[0164]
That is, FIG. 12A shows an LSP control request message (Msg) including a communication path start point, a communication path end point, and a dispersion integrated value as a message field when dispersion compensation is performed at the receiving end between the nodes A and B. An example of use is shown.
[0165]
FIG. 12B uses a control response message (Msg) including a communication path start point, a communication path end point, and a dispersion integrated value as a message field when dispersion compensation is performed at the transmission end between the nodes A and B. An example is shown.
[0166]
(Specific Third Embodiment)
FIG. 13 is a schematic diagram showing a third embodiment of the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention. It is a block diagram shown in order to demonstrate the fundamental structure and function of a part.
[0167]
That is, as shown in FIG. 13, in the centralized management type dispersion compensation method by receiving end compensation according to the present embodiment, a control request is made at the transmission end (node N1) of the communication path request message or the link distributed value management server 200. The dispersion value of each link between the nodes N1, N2, N3, and N4 (receiving end) used by the communication channel is calculated, and the sum of the dispersion values of all the links is calculated.
[0168]
In this way, the transmission end (node N1) of the communication path request message or the dispersion value calculated in the link dispersion value management server 200 is notified as a compensation value to the reception end (node N4) of the optical signal, and is provided on the reception end side. A compensation value is set to the tunable dispersion compensator 100.
[0169]
In parallel with these dispersion compensation value setting processes, the communication path request message Req process and the response message (not shown) are processed, so that the compensation value setting process for the variable dispersion compensator 100 is sufficiently fast. If so, the dispersion compensation setting can be completed before the actual optical signal appears on the communication path, so that the delay of the optical signal reproduction at the receiving end can be made zero.
[0170]
That is, in this embodiment, the transmission end of the communication path request message or the link distribution value management server calculates the distribution value of each link between the nodes used by the communication path for which control is requested, and distributes all these links. Concentration by reception end compensation that calculates the sum of the values, notifies the reception end of the optical signal as the compensation value of the calculated dispersion value, and sets the compensation value to the variable dispersion compensator on the reception end side A dispersion compensation system for an optical communication path that performs dynamic control using a managed dispersion compensation system is realized.
[0171]
In the present embodiment, although not shown, as the network control network 12 that cooperates with the data transmission network 11, the optical signal transmission unit 111, the transmission path, and the transmission node that are set as the data transmission network 11 are used. 113 (each node N1, N2, N3, N4) and a network control unit 122 that receives a communication path control request from the communication path control request unit 121. Is set.
[0172]
Then, at the transmission end (node N1) of the communication path request message or the link distribution value management server, the distribution value of the link between the nodes used by the communication path requested for control is calculated, and the distribution value of all these links is calculated. And a function of notifying the reception end of the optical signal of the calculated sum of dispersion values as a compensation value corresponds to the function as the dispersion value presenting device.
[0173]
Further, by setting a compensation value notified by the dispersion value presenting device to the tunable dispersion compensator 100 provided at the signal receiving end (node N4), compensation of total dispersion by the optical fiber is started. The function corresponds to the function as the dispersion compensation control device.
[0174]
According to this embodiment, at least the variable dispersion compensator provided at the specific receiving end is notified of the total sum of dispersion values presented by the dispersion value presentation device, so that A dispersion compensation system for an optical communication path that performs dynamic control characterized by starting compensation for total dispersion by an optical fiber is realized.
[0175]
In addition, according to this embodiment, a plurality of the distributed value presenting devices exist in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request. A centralized management type dispersion value presentation that is presented to a variable dispersion compensator provided at the specific receiving end of the communication path by obtaining a sum of dispersion values by the optical fibers laid between the nodes A dispersion compensation system for an optical communication path that performs dynamic control and is characterized by being executed is realized.
[0176]
(Specific Fourth Embodiment)
FIG. 14 is a diagram illustrating a fourth embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention, to which a centralized dispersion compensation method using transmission end compensation is applied. It is a block diagram shown in order to demonstrate the fundamental structure and function of a part.
[0177]
That is, as shown in FIG. 14, in the centralized management type dispersion compensation method using transmission end compensation according to the present embodiment, a control request is made at the transmission end (node N1) of the communication path request message or the link distributed value management server 200. The dispersion value of each link between the nodes N1, N2, N3, and N4 (receiving end) used by the communication channel is calculated, and the sum of the dispersion values of all the links is calculated.
[0178]
Then, the transmission end (node N1) of the communication path request message or the link distributed value management server 200 transmits the distribution values of all links calculated by the transmission end (node N1) of the communication path request message or the link distributed value management server 200. The sum is notified to the optical signal transmission end (node N1) as a compensation value, and the compensation value is set for the tunable dispersion compensator 100 on the transmission end side.
[0179]
In parallel with these dispersion compensation value setting processes, the communication path request message Req process and the response message (not shown) are processed, so that the compensation value setting process for the variable dispersion compensator 100 is sufficiently fast. If so, the dispersion compensation setting can be completed before the actual optical signal appears on the communication path, so that the delay of the optical signal reproduction at the receiving end can be made zero.
[0180]
That is, in this embodiment, the transmission end of the communication path request message or the link distribution value management server calculates the distribution value of the links between the nodes used by the communication path requested to be controlled, and the distribution value of all these links. Of the centralized management based on transmission end compensation in which the calculated dispersion value is notified to the transmission end of the optical signal as a compensation value, and the compensation value is set to the variable dispersion compensator on the transmission end side. A dispersion compensation system for an optical communication path that performs dynamic control using a dispersion compensation method is realized.
[0181]
In the present embodiment, although not shown, as the network control network 12 that cooperates with the data transmission network 11, the optical signal transmission unit 111, the transmission path, and the transmission node that are set as the data transmission network 11 are used. 113 (each node N1, N2, N3, N4) and a network control unit 122 that receives a communication path control request from the communication path control request unit 121. Is set.
[0182]
Then, at the transmission end of the communication path request message or the link distribution value management server, the distribution value of the link between the nodes used by the communication path requested for control is calculated, and the sum of the distribution values of all the links is calculated. The function of notifying the calculated dispersion value to the optical signal transmission end as a compensation value corresponds to the function as the dispersion value presenting device.
[0183]
The function of starting dispersion compensation by an optical fiber by setting a compensation value notified by the dispersion value presenting device to the tunable dispersion compensator 100 provided at the signal transmission end (node N1). Corresponds to the function as the dispersion compensation control device.
[0184]
According to this embodiment, at least the variable dispersion compensator provided at the specific transmission end is notified of the total sum of the dispersion values presented by the dispersion value presentation device, so that A dispersion compensation system for an optical communication path that performs dynamic control characterized by starting compensation for total dispersion by an optical fiber is realized.
[0185]
In addition, according to this embodiment, a plurality of the distributed value presenting devices exist in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request. A centralized management type dispersion value presentation that is presented to a variable dispersion compensator provided at the specific transmission end of the communication path by obtaining a sum of dispersion values by the optical fiber laid between the nodes A dispersion compensation system for an optical communication path that performs dynamic control and is characterized by being executed is realized.
[0186]
In the dispersion compensation system for an optical communication path that performs dynamic control using the centralized dispersion compensation method according to the specific third and fourth embodiments as described above, the dispersion compensator is connected to the transmission side. Regardless of whether it is provided on the receiving side, the transmission end of the communication path request message or the link distributed value management server 200 manages nodes to be connected and distributed values for all the links constituting the network. It is necessary to calculate the dispersion value of the links between the nodes used by the communication path for which control is requested, and to calculate the sum of the dispersion values of all the links.
[0187]
As the dispersion value, a static numerical value measured at the time of link introduction may be used, but a mechanism for dynamically measuring between the opposite nodes sharing the link is introduced and periodically It is desirable to update to the latest measured value.
[0188]
Each node needs to manage a route table for request message transfer, which is realized by using an existing IP (Internet Protocol) technology using OSPF (Open Shortest Path First) or the like. It is possible.
[0189]
FIG. 15A shows a connection link (Link 1, 2, 3, 4, 5) between five nodes A, B, C, D, and E connected as shown in FIG. An example of the link distributed value table 300 managed by the distributed value management server 200 to be managed is shown.
[0190]
That is, as shown in FIG. 15B, when a route notification is made from the node A (transmission end) to the distributed value management server 200, the distributed value management server 200 sends a node A (transmission end) or a node E (reception end). ) Is notified based on the contents of the link dispersion value table 300 managed by the dispersion value management server 200.
[0191]
That is, as shown in FIG. 15A, the content of the link distribution value table 300 is such that the distribution value (CD) of the connection link (Link1) between the nodes A and B is “5”, and the connection node B-C. The connection value (CD2) of the connection link (Link2) between them is "7", the connection value (CD) of the connection link (Link3) between the connection nodes BD is "10", and the connection link between the connection nodes CD In this example, the distribution value (CD) of (Link4) is “9”, and the distribution value (CD) of the connection link (Link5) between the connection nodes DE is “8”.
[0192]
In the dispersion compensation system for an optical communication path that performs dynamic control according to the centralized management type dispersion compensation method according to the specific third and fourth embodiments as described above, a dispersion value management server, It is necessary to exchange messages between the node at the transmission end and the reception end of the communication path.
[0193]
In these messages, the message used for notifying the compensation value requires at least a field as shown in FIG.
[0194]
That is, in FIG. 16, when dispersion compensation is performed at the transmission end or reception end via the relay nodes 1 and 2, the transmission node, relay is used as a message field for route notification from the transmission end to the distributed value management server 200. There are fields of nodes 1 and 2 and a reception node, and there is a field of compensation value as a message field for notifying the transmission value from the dispersion value management server 200 to the transmission end, and compensation from the dispersion value management server 200 to the reception end. There is a compensation value field as a message field for notifying the value.
[0195]
Further, in the dispersion compensation system for an optical communication path that performs dynamic control using the centralized dispersion compensation method according to the specific third and fourth embodiments as described above, as shown in FIG. It is necessary to select a link to be used for the communication path from the notified path (relay node group) and calculate the chromatic dispersion value of the entire communication path.
[0196]
That is, the link used for the communication path is selected in the connection links (Links 1, 2, 3, 4, 5) between the five connection nodes A, B, C, D, and E connected as shown in FIG. Then, the chromatic dispersion value of the entire communication path is calculated based on the contents of the link dispersion value table 300 similar to that shown in FIG.
[0197]
In this case, the connection link between the connection nodes A and B (Link 1), the connection link between the connection nodes B and D (Link 3), and the connection between the connection nodes D and E from the node A (transmission end) to the distributed value management server 200 When a route notification for selecting the link (Link 5) is made, the distributed value management server 200 reads the corresponding connection link (Link 1), (Link 3) from the link distributed value table 300 similar to that shown in FIG. , (Link5), the dispersion values “5”, “10”, and “8” are extracted and added (5 + 10 + 8 = 23), thereby calculating the chromatic dispersion value “23” of the entire communication path.
[0198]
(Specific Fifth Embodiment)
Next, in the optical communication system that performs dynamic control of the optical communication path as in the first to fourth embodiments described above, the end of the optical communication path that uses the optical fiber for the data transmission network. By starting the end-to-end dispersion compensation before receiving the optical signal, the received data reproduction delay time is shortened and X% (where X ≠ 100) compensation is performed for each link. In this dynamic, the entire optical transmission line can obtain good transmission characteristics by compensating for the excess and deficiency with respect to the total dispersion value of all links by X% (where X ≠ 100) compensation throughout the link. A specific fifth embodiment for providing a dispersion compensation method and system for an optical communication path that performs appropriate control will be described.
[0199]
First, an outline of the present embodiment will be described.
[0200]
Normally, the chromatic dispersion values “10”, “5”, and “2” of the optical fiber used for the transmission path for each link in the nodes N1 to N5 connected as shown in FIG. Thus, dispersion compensation is performed, and chromatic dispersion compensation is performed on the reception side (or transmission side) of the residual dispersion between ends (end-to-end) using a variable dispersion compensator.
[0201]
In that case, the chromatic dispersion with respect to the distance exhibits a sawtooth-like variation as shown in FIG.
[0202]
On the other hand, as described above, according to Non-Patent Document 2 and Non-Patent Document 3, from the viewpoint of transmission characteristics, each link is compensated by a compensation value that is not 100% compared to the case where 100% compensation is performed by DCF. For example, it is known that good transmission characteristics can be obtained when 90% compensation or 110% compensation is performed.
[0203]
FIG. 20 shows how the chromatic dispersion fluctuates with respect to the distance when 90% compensation is performed for each link.
[0204]
That is, when 100% compensation is performed for each link, transmission characteristics deteriorate compared to X% compensation (where X ≠ 100), so that the path of the target link in the present invention changes dynamically. In order to realize X% compensation (however, X ≠ 100, for example, X = 90, 110, etc.) in each path, each link at the receiving end or transmitting end (or both receiving end and transmitting end) Therefore, dynamic chromatic dispersion control is required to execute dispersion compensation that compensates for excess / deficiency with respect to the sum of dispersion values of all links by X% (where X ≠ 100) compensation.
[0205]
FIG. 21 shows a centralized management type based on transmission end compensation as a specific fifth embodiment of the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention based on the above outline. It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part to which this dispersion compensation system is applied.
[0206]
That is, as shown in FIG. 21, in the centralized management type dispersion compensation method using transmission end compensation according to the present embodiment, the link dispersion value is determined based on the LSP route notification from the transmission end (node N1) as the communication path request message. In the management server 200, the dispersion value of each link between the nodes N1, N2, N3, and N4 (receiving end) used by the communication path requested to be controlled and the sum of the dispersion values of all the links are calculated.
[0207]
In this case, it is assumed that the user (communication carrier) sets in advance a dispersion compensation value for each link for each node.
[0208]
Further, in this case, the variable dispersion compensator 100 is installed in each of the nodes N1 (transmission end), N2, N3, and N5, and each link is managed by the link dispersion value management server 200 as a centralized wavelength dispersion value management server. It is assumed that the variable dispersion compensation setting amounts of the nodes N1 (transmission end), N2, N3, and N5 are controlled.
[0209]
Then, the link dispersion value management server 200 pre-compensates dispersion compensation values to be compensated for each link based on dispersion compensation values “10”, “5”, and “2” set for each link, and all links. Is calculated, and X% (where X ≠ 100) of the calculated dispersion value of each link is notified to each variable dispersion compensator 100 of the intermediate nodes N2 and N3 as a compensation value. These are set as respective compensation values.
[0210]
Further, in order to perform dispersion compensation that compensates for excess and deficiency with respect to the sum of dispersion values of all links by compensation of X% (where X ≠ 100) at intermediate nodes N2 and N3, intermediate node N2 , N3 is notified to the variable dispersion compensator 100 at the transmitting end (node N1) of the dispersion value for the total sum of dispersion values of all links by X% (where X ≠ 100) compensation and compensates for it. Let it be set as a value.
[0211]
In parallel with these compensation value setting processes, the communication path request message Req process and the response message (not shown) are processed as described above, so that the compensation value setting process for each tunable dispersion compensator 100 is performed. Is sufficiently fast, the dispersion compensation setting can be completed before the actual optical signal appears on the communication path, so that the delay of optical signal reproduction at the receiving end can be made zero.
[0212]
That is, in the present embodiment, in the link dispersion value management server, the dispersion compensation value to be compensated in each link between each node used by the communication path requested from the transmission end, and the sum of dispersion values of all links And X% of the dispersion compensation value to be compensated at each link (where X ≠ 100) is notified to the intermediate node as a compensation value, and X% at the intermediate node (However, X.noteq.100) An excess / deficiency dispersion value with respect to the sum of dispersion values of all links by compensation is notified to the transmitting end, and setting of compensation values to each variable dispersion compensator is started before receiving an optical signal. As a result, the reception data reproduction delay time at the receiving end can be shortened, and good transmission characteristics can be obtained for the entire optical transmission line, so that longer distance transmission can be realized. Management-type dispersion compensation method Dispersion compensation system of an optical communication path for dynamic control Tsu is realized.
[0213]
In this case, it is possible to obtain stable transmission characteristics instantaneously at the time of path change, and by setting the dispersion compensation rate dynamically and freely for each link, setting the same compensation rate for all links and for each link Individual compensation rates can be set, and transmission characteristics can be further improved.
[0214]
Further, it is possible to change the compensation rate for each type of fiber to be used and for each wavelength channel, and transmission characteristics can be further improved.
[0215]
In the present embodiment, although not shown, as the network control network 12 that cooperates with the data transmission network 11, the optical signal transmission unit 111, the transmission path, and the transmission node that are set as the data transmission network 11 are used. 113 (each node N1, N2, N3, N4, N5) and a network control unit that receives a communication path control request from this communication path control request unit 121 122 is set.
[0216]
Then, the link dispersion value management server calculates the sum of the dispersion values of the links between the nodes and the dispersion values of all the links used by the communication path requested by the transmission end, and compensates for each of the calculated links. X% of the power dispersion compensation value (where X ≠ 100) is notified to the intermediate node as a compensation value, and the dispersion of all links is compensated by X% (where X ≠ 100) compensation at the intermediate node. The function of notifying the transmitting end of the variance value corresponding to the sum total of the values is equivalent to the function as the variance value presenting device.
[0217]
The function of starting dispersion compensation by an optical fiber by setting each compensation value notified by the dispersion value presenting device to each variable dispersion compensator 100 provided at each intermediate node and transmission end. Corresponds to the function as the dispersion compensation control device.
[0218]
And according to the present embodiment, a plurality of the distributed value presenting devices exist in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request. An intermediate variable dispersion provided in at least one of the plurality of nodes by obtaining a dispersion value between the nodes by the optical fiber laid between the nodes and a sum of the dispersion values between the nodes. A dispersion value for causing the compensator to perform X% (where X ≠ 100) compensation of the inter-node dispersion value is presented, and at least the entire variable dispersion compensator provided at the specific transmission end On the other hand, a dispersion value for executing dispersion compensation that compensates for excess / deficiency with respect to the sum of dispersion values between nodes by X% (where X ≠ 100) compensation in the intermediate variable dispersion compensator is provided. Dispersion compensation system of an optical communication path for performing dynamic control and executes the variance presentation of Shimesuru centralized is realized.
[0219]
(Specific Sixth Embodiment)
FIG. 22 shows a specific sixth embodiment of the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention, based on the same outline as that of the specific fifth embodiment described above. It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part to which the centralized management type dispersion compensation system by receiving end compensation is applied as a form.
[0220]
That is, as shown in FIG. 22, in the centralized management type dispersion compensation method using the receiving end compensation according to the present embodiment, the link dispersion value is determined based on the LSP route notification from the transmitting end (node N1) as the communication route request message. In the management server 200, the dispersion value of each link between the nodes N1, N2, N3, and N4 (receiving end) used by the communication path requested to be controlled and the sum of the dispersion values of all the links are calculated.
[0221]
In this case, it is assumed that the user (communication carrier) previously sets the dispersion compensation rate in each link for each node.
[0222]
Further, in this case, the variable dispersion compensator 100 is installed in each of the nodes N1 (transmission end), N2, N3, and N5, and each link is managed by the link dispersion value management server 200 as a centralized wavelength dispersion value management server. It is assumed that the variable dispersion compensation setting amount of the nodes N2, N3, N4 (receiving end) is controlled.
[0223]
Then, the link dispersion value management server 200 pre-compensates dispersion compensation values to be compensated for each link based on dispersion compensation values “10”, “5”, and “2” set for each link, and all links. Is calculated, and X% (where X ≠ 100) of the calculated dispersion value of each link is notified to each variable dispersion compensator 100 of the intermediate nodes N2 and N3 as a compensation value. These are set as respective compensation values.
[0224]
Further, in order to perform dispersion compensation that compensates for excess / deficiency with respect to the sum of dispersion values of all links by X% (where X ≠ 100) compensation at the intermediate nodes N2 and N3, the intermediate node N2 , N3 is notified to the variable dispersion compensator 100 at the receiving end (node N4) of the dispersion value corresponding to the sum of dispersion values of all links by X% (where X ≠ 100) compensation, and this is the compensation value. Let it be set as.
[0225]
In parallel with these compensation value setting processes, the communication path request message Req process and the response message (not shown) are processed as described above, so that the compensation value setting process for each tunable dispersion compensator 100 is performed. Is sufficiently fast, the dispersion compensation setting can be completed before the actual optical signal appears on the communication path, so that the delay of optical signal reproduction at the receiving end can be made zero.
[0226]
That is, in the present embodiment, in the link dispersion value management server, the dispersion compensation value to be compensated in each link between each node used by the communication path requested from the transmission end, and the sum of dispersion values of all links And X% of the dispersion compensation value to be compensated at each link (where X ≠ 100) is notified to the intermediate node as a compensation value, and X% at the intermediate node (However, X.noteq.100) The dispersion value corresponding to the sum of the dispersion values of all links by compensation is notified to the receiving end, and the setting of the compensation value to each variable dispersion compensator is started before reception of the optical signal. As a result, it is possible to shorten the reception data reproduction delay time at the receiving end, obtain good transmission characteristics for the entire optical transmission line, and achieve concentration over longer distances by means of receiving end compensation. Management-type dispersion compensation method Dispersion compensation system of an optical communication path for dynamic control Tsu is realized.
[0227]
In this case, it is possible to obtain stable transmission characteristics instantaneously at the time of path change, and by setting the dispersion compensation rate dynamically and freely for each link, setting the same compensation rate for all links and for each link Individual compensation rates can be set, and transmission characteristics can be further improved.
[0228]
Further, it is possible to change the compensation rate for each type of fiber to be used and for each wavelength channel, and transmission characteristics can be further improved.
[0229]
In the present embodiment, although not shown, as the network control network 12 that cooperates with the data transmission network 11, the optical signal transmission unit 111, the transmission path, and the transmission node that are set as the data transmission network 11 are used. 113 (each node N1, N2, N3, N4, N5) and a network control unit that receives a communication path control request from the communication path control request unit 121 122 is set.
[0230]
Then, the link dispersion value management server calculates the sum of the dispersion values of the links between the nodes and the dispersion values of all the links used by the communication path requested by the transmission end, and compensates for each of the calculated links. X% of the power dispersion compensation value (where X ≠ 100) is notified to the intermediate node as a compensation value, and the dispersion of all links is compensated by X% (where X ≠ 100) compensation at the intermediate node. The function of notifying the receiving end of the variance value corresponding to the sum total of the values is equivalent to the function as the variance value presenting device.
[0231]
Further, the function of starting dispersion compensation by an optical fiber by setting each compensation value notified by the dispersion value presenting device to each variable dispersion compensator 100 provided at each node and receiving end, This corresponds to the function as the dispersion compensation control device.
[0232]
And according to the present embodiment, a plurality of the distributed value presenting devices exist in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request. An intermediate variable dispersion provided in at least one of the plurality of nodes by obtaining a dispersion value between the nodes by the optical fiber laid between the nodes and a sum of the dispersion values between the nodes. A dispersion value for causing the compensator to perform X% (where X ≠ 100) compensation of the inter-node dispersion value is presented, and at least the entire variable dispersion compensator provided at the specific receiving end On the other hand, a dispersion value for executing dispersion compensation that compensates for excess / deficiency with respect to the sum of dispersion values between nodes by X% (where X ≠ 100) compensation in the intermediate variable dispersion compensator is provided. Dispersion compensation system of an optical communication path for performing dynamic control and executes the variance presentation of Shimesuru centralized is realized.
[0233]
In the dispersion compensation system for an optical communication path that performs dynamic control based on the centralized dispersion compensation method according to the specific fifth and sixth embodiments as described above, the dispersion compensator is connected to the transmission side, Regardless of whether it is provided on the receiving side, the link distributed value management server manages the nodes to be connected and the distributed values for all the links constituting the network, and uses the communication path for which control is requested. It is necessary to calculate the variance value of all links between nodes and to calculate the sum of the variance values of these links.
[0234]
As the dispersion value, a static numerical value measured at the time of link introduction may be used, but a mechanism for dynamically measuring between the opposite nodes sharing the link is introduced and periodically It is desirable to update to the latest measured value.
[0235]
Each node needs to manage a route table for request message transfer, which is realized by using an existing IP (Internet Protocol) technology using OSPF (Open Shortest Path First) or the like. It is possible.
[0236]
Also in the specific fifth and sixth embodiments as described above, the link distribution value table managed by the distribution value management server 200 is the link distribution as shown in FIG. The value table 300 can be applied mutatis mutandis.
[0237]
【The invention's effect】
Therefore, as described above, according to the present invention, a dispersion compensation method for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network. An optical communication that performs dynamic control to shorten a reception data reproduction delay time by starting end-to-end dispersion compensation before receiving an optical signal. A dispersion compensation method and system for a road can be provided.
[0238]
In addition, according to the present invention, as described above, there is provided a dispersion compensation method for an optical communication path in which dynamic control is performed using a data transmission network using an optical fiber and a network control network linked to the data transmission network. Thus, the end-to-end dispersion compensation of the optical communication path is started before the reception of the optical signal, so that the reception data reproduction delay time is shortened and X% (however, X ≠ 100) compensation is performed, and the entire optical transmission line can be transmitted satisfactorily by compensating for excess and deficiency with respect to the sum of dispersion values between nodes by X% (where X ≠ 100) compensation throughout the link. It is possible to provide a dispersion compensation method and system for an optical communication path that performs dynamic control so as to obtain characteristics.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining whether a unit compensation section of chromatic dispersion is between nodes or between ends (End-to-End).
FIG. 2 shows that when the unit compensation interval is between nodes, the chromatic dispersion is compensated at each node, and only the dispersion generated at the link between the two nodes is compensated. It is a figure shown in order to demonstrate becoming object.
FIG. 3 shows that when the compensation section is end-to-end, the chromatic dispersion generated in all the paths of the LSP is compensated collectively by a compensator provided at the receiving end or transmitting end. It is a figure shown in order to demonstrate what must be done.
4A is a diagram for explaining a method of detecting a dispersion value of a signal after receiving an optical signal and applying appropriate compensation, and FIG. 4B is a diagram illustrating the method of FIG. Shows a method for shortening the signal reproduction delay time by starting end-to-end dispersion compensation before receiving an optical signal in cooperation with a network control technology. FIG.
FIG. 5 is a diagram for explaining a fundamental configuration of a main part to which a basic embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention is applied; It is a block diagram.
FIG. 6 is a processing sequence diagram for explaining the principle operation procedure of the main part to which the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention is applied; .
FIG. 7 is a diagram showing a first embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention. It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part to which a compensation system is applied.
FIG. 8 is a diagram showing a first embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention. It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part to which a compensation system is applied.
FIG. 9 is a diagram showing a dispersion coordinating dispersion compensation method using transmission end compensation as a specific second embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention; It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part applied.
FIG. 10 is a diagram showing a dispersion coordinating dispersion compensation method using transmission end compensation as a second embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention; It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part applied.
11A is a link distribution value table to be managed by a node A connected to four opposing nodes B, C, D, and E, as shown in FIG. 11B. It is a figure which shows an example.
12A is a diagram illustrating an example in which an LSP control request message (Msg) is used as a message field when dispersion compensation is performed at the receiving end between nodes A and B. FIG. (B) is a figure which shows the example which utilizes a control response message (Msg) as a message field, when dispersion | distribution compensation is performed by the transmission end between node A and B. FIG.
FIG. 13 is a diagram illustrating a third embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention. It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part applied.
FIG. 14 is a diagram showing a centralized management type dispersion compensation method using transmission end compensation as a fourth embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention; It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part applied.
15A is a connection link (Link 1, 2, 3, 4) between five nodes A, B, C, D, and E connected as shown in FIG. 15B. , 5) is a diagram showing an example of a link distributed value table 300 managed by the distributed value management server to be managed.
FIG. 16 is a diagram illustrating an example of a message field used for notifying a compensation value in specific third and fourth embodiments;
FIG. 17 is a diagram of selecting a link to be used for a communication path from the paths (relay node group) notified in specific third and fourth embodiments, and chromatic dispersion of the entire communication path; It is a figure which shows an example of the form which calculates a value.
FIG. 18 is a diagram illustrating chromatic dispersion of an optical fiber used for a transmission line for each link by DCF (dispersion compensation fiber), and residual dispersion between ends (end-to-end) on the receiving side. FIG. 10 is a diagram illustrating a normal example in which chromatic dispersion compensation is performed using a tunable dispersion compensator (or on the transmission side).
FIG. 19 is a diagram illustrating an example of chromatic dispersion with respect to distance in the normal example of FIG. 18;
FIG. 20 is a diagram illustrating how chromatic dispersion varies with distance when 90% compensation is performed for each link;
FIG. 21 shows a centralized management type dispersion compensation method using transmission end compensation as a fifth embodiment of the dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention; It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part applied.
FIG. 22 shows a centralized management type dispersion compensation method by receiving end compensation as a specific sixth embodiment of a dispersion compensation method and system for an optical communication path that performs dynamic control according to the present invention; It is a block diagram shown in order to demonstrate the fundamental structure and function of the principal part applied.
[Explanation of symbols]
11: Data transmission network,
12. Data transmission network
11 network control network,
111 ... Optical signal transmitter,
112 ... an optical signal receiver,
113 ... transmission path and transmission node,
114 ... dispersion compensation device,
121 ... Communication channel control request unit,
122... Network control unit (dispersion value presentation device, dispersion compensation control device),
123 ... Dispersion compensation device controller,
N1, N2, N3, N4 ... nodes,
100: variable dispersion compensator,
200: Link distributed value management server,
150: Link distribution value table,
300: Link distribution value table.

Claims (14)

A dispersion compensation method for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network,
In the network control network, exists in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. A dispersion value presenting step for presenting a total sum of dispersion values by the optical fiber laid between the nodes in the plurality of nodes;
Before establishing a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request based on the sum of the distribution values presented by the dispersion value presentation step And a dispersion compensation control step for starting compensation of total dispersion by the optical fiber in the communication path for the specific receiving end ,
The variance value presenting step includes:
Using the communication path control request for each node in a plurality of nodes existing in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request In the direction from the transmitting end to the receiving end, the sum of the dispersion values of the specific receiving end is determined from the specific transmitting end while adding the dispersion value by the optical fiber laid between the nodes, A dispersion compensation method for an optical communication path that performs dynamic control, wherein the total sum of the obtained dispersion values is presented to the specific receiving end .   A dispersion compensation method for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network,
  In the network control network, exists in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. A dispersion value presenting step for presenting a sum of dispersion values by the optical fiber laid between the nodes in the plurality of nodes;
  Before establishing a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request based on the sum of the distribution values presented by the dispersion value presentation step And a dispersion compensation control step for starting compensation of total dispersion by the optical fiber in the communication path for the specific transmitting end,
  The variance value presenting step includes:
  The response of the communication path control request is used for each node in a plurality of nodes existing in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request. Then, in the direction from the receiving end to the transmitting end, the sum of the dispersion values from the specific transmitting end to the specific receiving end is added while adding the dispersion value due to the optical fiber laid between the nodes. A method for compensating for dispersion in an optical communication path that performs dynamic control, characterized in that the sum of the obtained dispersion values is presented to the specific transmission end.   A dispersion compensation method for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network,
  In the network control network, exists in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. A dispersion value presenting step for presenting a sum of dispersion values by the optical fiber laid between the nodes in the plurality of nodes;
  Before establishing a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request based on the sum of the distribution values presented by the dispersion value presentation step And a dispersion compensation control step for starting compensation of total dispersion by the optical fiber in the communication path for the specific receiving end,
  The variance value presenting step includes:
  Based on the notification of the communication path from the specific transmission end to the specific reception end of the data transmission network to be generated in response to the communication path control request, laid between the nodes in the plurality of nodes existing in the communication path Optical communication for performing dynamic control, characterized in that a sum of dispersion values by the optical fiber is obtained by a dispersion value management server in the network control network and presented to the specific receiving end of the communication path Road dispersion compensation method.   A dispersion compensation method for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network,
  In the network control network, exists in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. A dispersion value presenting step for presenting a sum of dispersion values by the optical fiber laid between the nodes in the plurality of nodes;
  Before establishing a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request based on the sum of the distribution values presented by the dispersion value presentation step And a dispersion compensation control step for starting compensation of total dispersion by the optical fiber in the communication path for the specific transmitting end,
  The variance value presenting step includes:
  Based on a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request, it is laid between nodes in a plurality of nodes existing in the communication path An optical communication path for performing dynamic control, characterized in that a total sum of dispersion values by the optical fiber is obtained by a dispersion value management server in the network control network and presented to the specific transmission end of the communication path. Dispersion compensation method.   The dispersion compensation control step includes:
  Compensation of the total dispersion by the optical fiber in the communication path is started by notifying the variable dispersion compensator provided at the specific receiving end of the total dispersion value presented by the dispersion value presentation step. 4. The dispersion compensation method for an optical communication path that performs dynamic control according to claim 1 or 3.   The dispersion compensation control step includes:
  Compensation of total dispersion by the optical fiber in the communication path is started by notifying the variable dispersion compensator provided at the specific transmission end of the total dispersion value presented by the dispersion value presentation step. 5. The dispersion compensation method of an optical communication path for performing dynamic control according to claim 2 or 4, characterized by the above.   The variance value presenting step includes:
  7. The pre-measured value of any one of a value measured at the time of laying the communication path or a value periodically measured and updated is provided as the variance value. A dispersion compensation method for an optical communication path that performs dynamic control as described in 1.   A dispersion compensation control device used in a dispersion compensation system for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network,
  The dispersion compensation system includes:
  In the network control network, exists in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. Dispersion value presenting means for presenting the sum of dispersion values by the optical fiber laid between the nodes in a plurality of nodes,
  The variance value presenting means includes:
  Using the communication path control request for each node in a plurality of nodes existing in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request In the direction from the transmitting end to the receiving end, the sum of the dispersion values of the specific receiving end is determined from the specific transmitting end while adding the dispersion value by the optical fiber laid between the nodes, Presenting the sum of the obtained dispersion values to the specific receiving end,
  The dispersion compensation control device includes:
  Before establishing a communication path from a specific transmitting end to a specific receiving end of the data transmission network to be generated in response to the communication path control request based on the total sum of the distributed values presented by the distributed value presenting means In addition, a dispersion compensation control apparatus for an optical communication path that performs dynamic control, characterized in that compensation for total dispersion by the optical fiber in the communication path is started for the specific receiving end.   A dispersion compensation control device used in a dispersion compensation system for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network,
  The dispersion compensation system includes:
  In the network control network, exists in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. Dispersion value presenting means for presenting the sum of dispersion values by the optical fiber laid between the nodes in a plurality of nodes,
  The variance value presenting means includes:
  The response of the communication path control request is used for each node in a plurality of nodes existing in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to the communication path control request. Then, in the direction from the receiving end to the transmitting end, the sum of the dispersion values from the specific transmitting end to the specific receiving end is added while adding the dispersion value due to the optical fiber laid between the nodes. And presenting the sum of the obtained dispersion values to the specific transmitting end,
  The dispersion compensation control device includes:
  Before establishing a communication path from a specific transmitting end to a specific receiving end of the data transmission network to be generated in response to the communication path control request based on the total sum of the distributed values presented by the distributed value presenting means In addition, a dispersion compensation control apparatus for an optical communication path that performs dynamic control, characterized in that compensation for total dispersion by the optical fiber in the communication path is started for the specific transmission end.   A dispersion compensation control device used in a dispersion compensation system for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network,
  The dispersion compensation system includes:
  In the network control network, exists in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. Dispersion value presenting means for presenting the sum of dispersion values by the optical fiber laid between the nodes in a plurality of nodes,
  The variance value presenting means includes:
  Based on the notification of the communication path from the specific transmission end to the specific reception end of the data transmission network to be generated in response to the communication path control request, laid between the nodes in the plurality of nodes existing in the communication path Obtained by the dispersion value management server in the network control network to obtain the sum of dispersion values by the optical fiber and present it to the specific receiving end of the communication path,
  The dispersion compensation control device includes:
  Before establishing a communication path from a specific transmitting end to a specific receiving end of the data transmission network to be generated in response to the communication path control request based on the total sum of the distributed values presented by the distributed value presenting means In addition, a dispersion compensation control apparatus for an optical communication path that performs dynamic control, characterized in that compensation for total dispersion by the optical fiber in the communication path is started for the specific receiving end.   A dispersion compensation control device used in a dispersion compensation system for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network,
  The dispersion compensation system includes:
  In the network control network, exists in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. Dispersion value presenting means for presenting the sum of dispersion values by the optical fiber laid between the nodes in a plurality of nodes,
  The variance value presenting means includes:
  Based on the notification of the communication path from the specific transmission end to the specific reception end of the data transmission network to be generated in response to the communication path control request, laid between the nodes in the plurality of nodes existing in the communication path Obtained by the dispersion value management server in the network control network to obtain the sum of dispersion values by the optical fiber and present it to the specific transmission end of the communication path,
  The dispersion compensation control device includes:
  Before establishing a communication path from a specific transmitting end to a specific receiving end of the data transmission network to be generated in response to the communication path control request based on the total sum of the distributed values presented by the distributed value presenting means In addition, a dispersion compensation control apparatus for an optical communication path that performs dynamic control, characterized in that compensation for total dispersion by the optical fiber in the communication path is started for the specific transmission end.   The dispersion compensation control device includes:
  12. Compensation of total dispersion by the optical fiber in the communication path is started by notifying a total sum of dispersion values presented by the dispersion value presenting means. 4. A dispersion compensation control device for an optical communication path that performs dynamic control according to 1.   A dispersion compensation control device used in a dispersion compensation system for an optical communication path that performs dynamic control using a data transmission network using an optical fiber and a network control network linked to the data transmission network,
  The dispersion compensation system includes:
  In the network control network, exists in a communication path from a specific transmission end to a specific reception end of the data transmission network to be generated in response to a communication path control request for a wavelength path that requires dynamic control of the communication path. Dispersion value presenting means for presenting the sum of dispersion values by the optical fiber laid between the nodes in a plurality of nodes,
  The variance value presenting means includes:
  Based on the notification of the communication path from the specific transmission end to the specific reception end of the data transmission network to be generated in response to the communication path control request, laid between the nodes in the plurality of nodes existing in the communication path The inter-node dispersion value by the optical fiber and the total sum of the inter-node dispersion values are obtained by a dispersion value management server in the network control network, and each of the plurality of nodes is compared with each of the nodes. A dispersion value for performing X% (where X ≠ 100) compensation of the inter-node dispersion value is presented, and at least the variable dispersion compensator provided at at least one of the specific reception end and transmission end Dispersion for executing dispersion compensation to compensate for excess and deficiency with respect to the sum of dispersion values between the nodes by X% (X ≠ 100) compensation for one node It presents a,
  The dispersion compensation control device includes:
  Before establishing a communication path from a specific transmitting end to a specific receiving end of the data transmission network to be generated in response to the communication path control request based on the total sum of the distributed values presented by the distributed value presenting means Start compensation of total dispersion by the optical fiber in the communication channel
A dispersion compensation control device for an optical communication path that performs dynamic control.   The variance value presenting means includes:
  14. The pre-measured value of any one of a value measured at the time of laying the communication path or a value periodically measured and updated is provided as the variance value. 4. A dispersion compensation control device for an optical communication path that performs dynamic control according to 1.

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