JP2014078851A - Accommodation determination device in optical communication network - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an accommodation determination device for determining accommodation of a path by a subband in an optical communication network using an optical signal including a plurality of subbands.SOLUTION: An accommodation determination device comprises: determination means for determining presence of optical signals able to accommodate a path from a starting point of the path sequentially; and determination means which, when the determination means determined that there is not an optical signal able to accommodate the path, sets a new optical signal in a section between an endpoint of an optical signal able to accommodate the path at the last and an endpoint of the path, and determines to accommodate the path.

Description

  The present invention relates to a technique for determining accommodation of an optical signal of a path using subbands in an optical communication network using an optical signal including a plurality of subbands.

  For example, Non-Patent Document 1 proposes communication using an optical signal including a plurality of subbands, such as a signal obtained by optically modulating an orthogonal frequency division multiplexing (OFDM) signal. Non-Patent Document 2 proposes a configuration in which subbands are branched from these optical signals in an intermediate optical node, and subbands are inserted into these optical signals.

Roman Dischler, et al. , "Interleaving OFDM Signals for Multiple Access with Optical Routing Capability and High Spectral Efficiency," ECOC 2009, paper8.3.2, 2009. Noboru Yoshikane, et al. , "Benefits of Router Offload Utilities Superchannel Technology for Beyond-100-Gb-Networks," OFFCNFEC2012, JTh2A.45, 2012

  When an optical signal including a plurality of subbands is applied to an optical communication network and a path is set in units of subbands, it is necessary to determine processing necessary for setting the path. Here, the process necessary for setting the path is to determine whether or not the path can be set only with the existing optical signal. When the path cannot be set only with the existing optical signal, the process is newly performed in any section. Is to determine whether to set an optical signal, and to perform processing according to the determination.

  The present invention provides an accommodation determination device for determining accommodation of a path by subbands in an optical communication network using an optical signal including a plurality of subbands.

  According to one aspect of the present invention, in an optical communication network that uses an optical signal including a plurality of subbands, an accommodation determination device that determines accommodation of a path using subbands to an optical signal, the starting point of the path When the determination unit determines that there is no optical signal capable of accommodating the path, and the determination unit determines that there is no optical signal capable of accommodating the path, the determination is finally made that the path can be accommodated. And determining means for setting a new optical signal in a section from the end point of the optical signal to the end point of the path and determining to accommodate the path.

  It is possible to determine whether or not a new optical signal needs to be set in order to set a path and, if necessary, a section of the optical signal to be newly set.

The block diagram of the optical communication system by one Embodiment. The flowchart of the process in the accommodation determination apparatus by one Embodiment. The block diagram of the optical communication system for demonstrating the process in an accommodation determination apparatus. The figure which shows the precondition of each example explaining the process in a accommodation determination apparatus. Explanatory drawing of the optical signal containing a several subband. Explanatory drawing of the optical signal containing a several subband.

  Hereinafter, exemplary embodiments of the present invention will be described with reference to the drawings. In the following drawings, components that are not necessary for the description of the embodiments are omitted from the drawings. In the following embodiments, an optical OFDM signal is used as an example of an optical signal including a plurality of subbands, but the present invention is not limited to an optical OFDM signal.

  FIG. 1 is a configuration diagram of an optical communication system according to the present embodiment. The optical communication network 20 includes a plurality of optical nodes 2, and each optical node 2 has a function of terminating and repeating an optical OFDM signal. Furthermore, in this embodiment, each optical node 2 has a function of repeating / termination in units of subbands corresponding to subcarriers of the optical OFDM signal.

  The network management device 1 controls the optical communication network 20 to set and release a path using an optical OFDM signal and subbands. The network management device 1 includes the optical nodes 2 included in the optical communication network 20, the optical links connecting the optical nodes 2 and their distances, the number of optical OFDM signals that can be set for each optical link, and The topology information including the center wavelength, the currently set optical OFDM signal section, the subband used as the current path, and the usage information indicating the section are stored. For example, the set optical OFDM signal is represented by the center wavelength or a number corresponding to the center wavelength, and the subband used can be represented by a number in the optical OFDM signal.

  Hereinafter, with reference to FIGS. 5 and 6, an optical OFDM signal and path setting in units of subbands in the present embodiment will be described. In this embodiment, the section of the optical OFDM signal is a section starting from an optical node where all subbands are generated and ending at an optical node where all subbands are terminated. Therefore, as will be described later, the section of the optical OFDM signal changes according to the path setting or the like. In the examples of FIGS. 5 and 6, it is assumed that one optical OFDM signal has four subbands. In the initial state, it is assumed that no optical OFDM signal is set in any of the optical links from optical node #A to optical node #D.

  The upper part of FIG. 5 shows a state in which the path from the optical node #A to the optical node #D is set using one subband after the initial state. As shown in the upper part of FIG. 5, an optical OFDM signal including four subbands is generated in the optical node #A, and the four subbands are relayed in the intermediate optical nodes #B and #C. Then, the network management apparatus 1 controls each optical node 2 so as to terminate an optical OFDM signal including four subbands. Since only one path is set, one subband is used to flow a signal corresponding to the path, but the remaining three are dummy signals that do not flow. In the example shown in the upper part of FIG. 5, subband # 1 is used as a path for passing a signal, and subbands # 2 to # 4 are dummy. In the upper part of FIG. 5, the section of the optical OFDM signal is a section from the optical node #A to the optical node #D.

  Thereafter, for example, a path from the optical node #B to the optical node #D, a path from the optical node #A to the optical node #C, and a path from the optical node #C to the optical node #D are set. . In this case, the network management device 1 controls each optical node 2 so as to use the dummy subband as a path. For example, in the example shown in the lower part of FIG. 5, a path from the optical node #B to the optical node #D is set using the subband # 2, and the optical node #A is optically transmitted using the subband # 3. A path to node #C and a path from optical node #C to optical node #D are set. The section of the optical OFDM signal at this time is also a section from the optical node #A where the four subbands are generated to the optical node #D where the four subbands are terminated. That is, the section of the optical OFDM signal is not changed by the path setting.

  The upper part of FIG. 6 shows a state in which three paths from the optical node #A to the optical node #C are set. Specifically, subbands # 1 to # 3 are used as paths, and subband # 4 is a dummy. In this case, the section of the optical OFDM signal is a section from the optical node #A to the optical node #C. In this state, one path from the optical node #A to the optical node #D is set. In this case, first, a new optical OFDM signal from the optical node #C to the optical node #D is set first. All subbands of this new optical OFDM signal are dummy. Subsequently, the network management device 1 uses the subband # 4, which is a dummy of the optical OFDM signal from the previously set optical node #A to the optical node #C, and the newly set optical node #C to the optical node #D. The optical node #C is set so as to relay the subband # 4, which is a dummy of the optical OFDM signal reaching This state is shown in the lower part of FIG. In this embodiment, the path is set in this way.

  In the final state shown in the lower part of FIG. 6, it is the optical node #A that generates all four subbands including the dummy, and it is the optical node that terminates all four subbands including the dummy. Node #D. Therefore, only one optical OFDM signal is set from the optical node #A to the optical node #D. That is, the previously set optical OFDM signal from the optical node #A to the optical node #C and the newly set optical OFDM signal from the optical node #C to the optical node #D are subband # in the optical node #C. By setting to relay 4, it is integrated into one. In this way, the optical OFDM signal sections are relative and vary depending on how the subbands to be accommodated are set.

  Subsequently, returning to FIG. 1, the accommodation determination device 3 obtains the topology information and the usage information held by the network management device 1 and sets a new optical OFDM signal when the start point and the end point of the path are given. If it is possible to set a path, the path is also determined. If the setting is not possible, the section in which a new optical OFDM signal is provided and the path of the path to be set are determined. As described with reference to FIG. 6, the new optical OFDM signal is set to include only a dummy subhand, and is then used to accommodate a path. Thus, when a new optical OFDM signal is used to accommodate a path along with a dummy subband of the existing optical OFDM signal, it is integrated with the existing optical OFDM signal as described in the example of FIG. It will be. The accommodation determination device 3 notifies the network management device 1 of the determined result, and the network management device 1 controls the optical communication network 20 according to the determination of the accommodation determination device 3.

  Hereinafter, the processing in the accommodation determination device 3 will be described with reference to FIG. In S10, the accommodation determination device 3 determines whether there is an optical OFDM signal having a vacant band that can accommodate the path, that is, a dummy subband, at the start point of the path based on the topology information and the usage information. If there is no free band, in S17, a new optical OFDM signal connecting the start point and end point of the path is set, one subband of the optical OFDM signal is used as a path, and the remaining subbands are dummy. It will be decided.

On the other hand, when the free bandwidth exists, from the starting point of the path, determines the distance D _o to the end point of the optical OFDM signal that accommodates the path at its starting point, the distance D _sub from the starting point of the path to the end point, In S11, it is determined whether D _diff = (D _o −D _sub ) is 0 or more. If it is greater than or equal to 0, the path is terminated in the optical OFDM signal, so that the accommodation determination device 3 uses one of the subbands used as a dummy of the optical OFDM signal in S16 as a path. Decide to use.

On the other hand, if it is less than 0 in S11, this means that the set path is terminated at the optical node 2 beyond the optical OFDM signal. That is, this corresponds to a state in which a path reaching the optical nodes #A to #D is set in FIG. In this case, the accommodation determining apparatus 3 sets another optical OFDM signal in the next section, that is, in the example of FIG. 6, from the optical node #C, and the subband of the same wavelength of the optical OFDM signal. Is determined to be a dummy in S12. If it is a dummy, that is, it is empty, the distance to the end point of this other optical OFDM signal is set to _Do2 , and the accommodation determination device 3 determines whether ( _Do2- | _Ddiff |) is 0 or more in S13. Judge with. If it is greater than or equal to 0, the path is terminated in the other optical OFDM signals, so in S16, the optical OFDM signal determines that the set path is accommodated in these two optical OFDM signals. On the other hand, if it is less than 0 in S13, this means that the path to be set is terminated at the optical node 2 that exceeds this other optical OFDM signal. Therefore, the accommodation determination device 3 updates D _diff to (D _o2 − | D _diff |) in S14, and repeats the processing from S12. Further, if there is no empty subband of the same wavelength in the optical OFDM signal of the next section in the process of S12, the accommodation determination device 3 determines whether there is another subband that can be used in S15. More specifically, in S15, the accommodation determination device 3 determines whether or not there is a vacancy in a subband having a wavelength different from that of the subband initially used for the path at the start point of the path. If there is a vacancy, the process is repeated from S11 to determine again whether or not accommodation is possible from the start point of the path. On the other hand, if there is no other subband that can be used in S15, the accommodation determination device 3 determines in S16 that a new optical OFDM signal is set for a section in which there is no space. This corresponds to setting a new optical OFDM signal from the optical node #C to the optical node #D in FIG.

  Hereinafter, the process of FIG. 2 will be described using a specific example. FIG. 3 shows an optical communication network 20 used in the following example. As shown in FIG. 3, it is assumed that optical nodes # 1 to # 5 are connected. For simplicity, the distance of each optical link is 80 km.

<Example 1>
In this example, it is assumed that the optical OFDM signal from the optical node # 1 to the optical node # 5 is set via the optical node # 2, the optical node # 3, and the optical node # 4 in this order. The subband # 1 of this optical OFDM signal is used for other paths in the section from the optical node # 1 to the optical node # 3, and the section from the optical node # 3 to the optical node # 5 is a dummy ( (See FIG. 4 (a)). From this state, a new path is set from the optical node # 3 to the optical node # 5.

Referring to the flowchart of FIG. 2, since the optical OFDM signal from the optical node # 1 to the optical node # 5 has a space in the section from the optical node # 3 to the optical node # 5, S10 is “Yes”. . In this example, the distance D _sub from the optical node # 3 that is the start point of the path to the optical node # 5 that is the end point of the path is 160 km, and the optical OFDM signal from the optical node # 3 that inserts the path into the optical OFDM signal. Since the distance _Do to the optical node # 5, which is the end point of, is 160 km, D _diff = (D _o −D _sub ) = 0, and “Yes” in S11. Therefore, the accommodation determination device 3 determines in S16 that the path to be set is accommodated in the subband # 1 of the optical OFDM signal.

<Example 2>
In this example, it is assumed that an optical OFDM signal from the optical node # 1 to the optical node # 4 is set via the optical node # 2 and the optical node # 3 in this order. It is assumed that no other optical OFDM signal is set. The subband # 1 of this optical OFDM signal is used for other paths in the section from the optical node # 1 to the optical node # 3, and the section from the optical node # 3 to the optical node # 4 is a dummy ( (Refer FIG.4 (b).). In this state, a new path is set from optical node # 3 to optical node # 5. It is assumed that all other subbands of this optical OFDM signal are in use.

Referring to the flowchart of FIG. 2, since the optical OFDM signal from the optical node # 1 to the optical node # 4 has a space in the section from the optical node # 3 to the optical node # 4, S10 is “Yes”. . In this example, the distance D _sub from the optical node # 3 that is the start point of the path to the optical node # 5 that is the end point of the path is 160 km, and the optical OFDM signal from the optical node # 3 that inserts the path into the optical OFDM signal. Since the distance _Do to the optical node # 4, which is the end point of, is 80 km, D _diff = (D _o −D _sub ) = − 80 km, and “No” in S11. In this example, since no other optical OFDM signal is set, S12 is “No”, and since there are no other subbands, S15 is also “No”. Therefore, the accommodation determining apparatus 3 determines in S17 that a new optical OFDM signal is set to accommodate the path for the section from the optical node # 4 to the optical node # 5. As described above, this new optical OFDM signal is eventually integrated into one optical OFDM signal by accommodating a new path together with the existing optical OFDM signal.

<Example 3>
In this example, the optical OFDM signal # 1 from the optical node # 1 to the optical node # 4 is set in the order of the optical node # 2 and the optical node # 3, and is directly transmitted from the optical node # 4 to the optical node # 5. It is assumed that the optical OFDM signal # 2 is set. Note that subband # 1 of optical OFDM signal # 1 and optical OFDM signal # 2 are both dummy, and all other subbands are in use. (See FIG. 4C.) In this state, a new path is set from optical node # 1 to optical node # 5.

Referring to the flowchart of FIG. 2, the subband # 1 of the optical OFDM signal # 1 from the optical node # 1 to the optical node # 4 is empty in all sections, so S10 is “Yes”. In this example, the distance D _sub from the optical node # 1 that is the start point of the path to the optical node # 5 that is the end point of the path is 320 km, and from the optical node # 1 that inserts the path into the optical OFDM signal # 1 to the optical OFDM Since the distance _Do to the optical node # 4 which is the end point of the signal # 1 is 240 km, D _diff = (D _o −D _sub ) = − 80 km and S11 is “No”. Subsequently, in this example, since the optical OFDM signal # 2 is set and the subband # 1 is empty, S12 becomes “Yes”. In this example, since the distance D _o2 from the optical node # 4 that is the start point of the optical OFDM signal # 2 to the optical node # 5 that is the end point is 80 km, D _o2 − | D _diff | = 0 km and S13 is “ Yes ". Accordingly, the accommodation determining device 3 determines in S16 that the path is accommodated in the optical OFDM signals # 1 and # 2.

<Example 4>
In this example, an optical OFDM signal # 1 directly from the optical node # 1 to the optical node # 2 and an optical OFDM signal # 2 from the optical node # 2 to the optical node # 4 via the optical node # 3 are set. Shall. Note that subband # 1 of optical OFDM signal # 1 and optical OFDM signal # 2 are both dummy, and all other subbands are in use. Furthermore, it is assumed that no other optical OFDM signal is set (see FIG. 4D). In this state, a new path is set from optical node # 1 to optical node # 5.

Referring to the flowchart of FIG. 2, the subband # 1 of the optical OFDM signal # 1 from the optical node # 1 to the optical node # 2 is empty, so S10 is “Yes”. In this example, the distance D _sub from the optical node # 1 that is the start point of the path to the optical node # 5 that is the end point of the path is 320 km, and from the optical node # 1 that inserts the path into the optical OFDM signal # 1 to the optical OFDM Since the distance _Do to the optical node # 2, which is the end point of the signal # 1, is 80 km, D _diff = (D _o −D _sub ) = − 240 km, and S11 is “No”. In this example, since the optical OFDM signal # 2 is set and the subband # 1 is empty, S12 becomes “Yes”. In this example, since the distance D _o2 from the optical node # 2 that is the start point of the optical OFDM signal # 2 to the optical node # 4 that is the end point is 160 km, D _o2 − | D _diff | = −80 km in S13, S13 is “No”. Accordingly, the accommodation determination device 3 updates D _diff to −80 km in S14.

  In this example, since no other optical OFDM signal is set, the second S12 is “No”, and there is no other subband, so S15 is also “No”. Therefore, in S17, it is determined to set a new optical OFDM signal from the optical node # 4 to the optical node # 5. Therefore, the new path is accommodated in the optical OFDM signal # 1, the optical OFDM signal # 2, and the new optical OFDM signal from the optical node # 4 to the optical node # 5. By accommodating a new path, these three optical OFDM signals are integrated into one.

  As described above, in order from the start point of the path, the optical OFDM signal that can accommodate the path is determined, and when there is no optical OFDM signal that can accommodate the path, the end point of the optical OFDM signal that is finally determined to accommodate the path From this, it is determined that a new optical OFDM signal is set up to the end point of the path. With this configuration, it is possible to efficiently determine the accommodation of the path.

  The accommodation determination device 3 according to the present invention can be realized by a program that causes a computer to operate as the accommodation determination device 3. These computer programs can be stored in a computer-readable storage medium or distributed via a network.

Claims (5)

In an optical communication network that uses an optical signal including a plurality of subbands, an accommodation determination device that determines accommodation in an optical signal of a path using subbands,
Determination means for determining presence of an optical signal capable of accommodating the path in order from the start point of the path;
When the determination unit determines that there is no optical signal capable of accommodating the path, a new optical signal is obtained in a section from the end point of the optical signal that is finally determined to be capable of accommodating the path to the end point of the path. And determining means for determining to accommodate the path;
An accommodation determination device comprising: The optical signal has a subband used for the path and a dummy subband not used for the path,
The accommodation determination apparatus according to claim 1, wherein the determination unit determines whether the path can be accommodated from a dummy subband section of the optical signal.   The accommodation determination device acquires information indicating an optical signal set in the optical communication network and a subband used for a path in each optical signal from the control device of the optical communication network. The accommodation determination device according to claim 1 or 2.   The determination unit can accommodate the path to the end point of the path by sequentially reducing the distance from the start point to the end point of the path by the distance of the section of the optical signal that is determined to accommodate the path. 4. The accommodation determination device according to claim 1, wherein a determination is made as to whether or not an optical signal is present. 5.   5. The accommodation determining apparatus according to claim 1, wherein the optical signal is a signal subjected to orthogonal frequency division multiplexing modulation.

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