JP2016149593A - Logical path control system, and logical path control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the number of logical paths.SOLUTION: A logical path control system 1 includes: a plurality of optical line terminals (OLT) 40-1, ..., 40-X; a plurality of redundant edges 50-2, ..., 50-Y, and a logical path management controller 10 for controlling logical paths between the plurality of optical line terminals 40-1, ..., 40-X and the plurality of redundant edges 50-2, ..., 50-Y. The logical path management controller 10 determines, for each of the optical line terminals 40-1, ..., 40-X, the number of logical paths to be set by the plurality of optical line terminals 40-1, ..., 40-X and sets logical paths, the number of which is the determined number, between the plurality of optical line terminals 40-1, ..., 40-X and the plurality of redundant edges 50-2, ..., 50-Y.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a logical path control system and a logical path control method.

  Conventionally, subscriber information and traffic processing using inter-device redundancy such as an edge router is performed using an active edge router device (hereinafter referred to as “active edge”) and a plurality of redundant edge router devices (hereinafter referred to as “active router”). And a redundant path ”) and a plurality of subscriber accommodation devices (OLT: Optical Line Terminal). FIG. 11 is a diagram for explaining a logical path setting method in the prior art. In FIG. 11, logical paths L201a to L204a with the working edge 250-1 are indicated by solid lines, and logical paths L201b to L204b and L201c to L204c with redundant edges 250-2, 250-3, and 250-Y (Y is a natural number). , L201d to L204d are indicated by broken lines.

  As shown in FIG. 11, when there are a plurality of redundant edges, the conventional logical path management controller 210 prepares for logical switching in advance in preparation for switching the chassis from the active edge to the redundant edge due to a failure of the active edge. The path will be set in full mesh. For example, when a failure occurs in the working edge 250-1, the chassis is switched to the redundant edge 250-2, and the redundant edge 250-2 is connected to the OLT 240-1, 240-2, and the logical paths L201b to L204b. Switch notification signals 201S to 204S are transmitted to each of 240-X-1 and 240-X (X is a natural number). In order to increase the speed of switching to such a redundant edge, the logical path management control apparatus 210 adds logical paths L201c to L204c and L201d to L204d, which are other switching destinations, in addition to the logical paths L201b to L204b in advance. Set.

Junji Nakatsumi, Ken Osaka, Yoshihiko Uematsu, Akio Kawabata, Toru Kidera, “Network Edge System Configuration with High Availability and Operability”, IEICE Technical Report (NS2011-6), pp.31-36, 2011 4 Moon

  However, the above-described conventional technology has the following problems. That is, in the logical path setting method in the prior art, all redundant edges and all subscriber accommodation devices connected to the edge redundancy management control device can be switched to the redundant edge due to the failure of the working edge at higher speed. In between, a logical path with a full mesh is set in advance. For example, in the example shown in FIG. 11, X × Y logical paths are set. Therefore, the scale of the logical path network increases, and the number of logical paths to be managed by the logical path management control device 210 may become enormous. As a result, management and control of the logical path becomes difficult.

  The disclosed technology has been made in view of the above, and an object thereof is to provide a logical path control system and a logical path control method capable of reducing the number of logical paths.

  In order to solve the above-described problems and achieve the object, a logical path control system disclosed in the present application, in one aspect, includes a plurality of first communication devices, a plurality of second communication devices, and the plurality of first communication devices. A logical path control system comprising: a control device that controls a logical path between the communication device and the plurality of second communication devices, wherein the control device sets the logic to be set in the plurality of first communication devices. A determination unit that determines the number of paths for each first communication device, and the number of logical paths determined by the determination unit between the plurality of first communication devices and the plurality of second communication devices. And a setting unit to set to.

  The logical path control method disclosed in the present application is, in one aspect, a logical path control method in which a control device controls a logical path between a plurality of first communication devices and a plurality of second communication devices. Determining the number of logical paths to be set in the plurality of first communication devices for each first communication device; and determining the number of logical paths determined in the determination step to the plurality of first communication devices. A setting step for setting between the communication device and the plurality of second communication devices.

  The logical path control system and the logical path control method disclosed in the present application have an effect that the number of logical paths can be reduced.

FIG. 1 is a diagram illustrating a configuration of a logical path control system according to method 1-1. FIG. 2 is a diagram showing a configuration of a logical path control system according to method 1-2. FIG. 3 is a diagram showing the configuration of the logical path management control device. FIG. 4 is a diagram showing the configuration of the subscriber accommodation device management control device. FIG. 5 is a diagram showing the configuration of the edge redundancy management control device. FIG. 6 is a diagram showing the configuration of the subscriber accommodation device. FIG. 7 is a diagram showing the configuration of the working edge. FIG. 8 is a diagram for explaining the operation of the logical path control system. FIG. 9 is a diagram for explaining a modification of the logical path control system. FIG. 10 is a diagram illustrating that information processing by the logical path control program is specifically realized using a computer. FIG. 11 is a diagram for explaining a logical path setting method in the prior art.

  Hereinafter, embodiments of a logical path control system and a logical path control method disclosed in the present application will be described in detail with reference to the drawings. The logical path control system and the logical path control method disclosed in the present application are not limited by the following embodiments.

  First, the configuration of a logical path control system according to an embodiment disclosed in the present application will be described.

(Method 1-1)
FIG. 1 is a diagram showing a configuration of a logical path control system 1 according to method 1-1. As shown in FIG. 1, the logical path control system 1 includes a logical path management control device 10, a subscriber accommodation device management control device 20, an edge redundancy management control device 30, and a subscriber accommodation device (OLT) 40-1. , 40-2, 40-X-1, 40-X (X is a natural number), a working edge 50-1, and redundant edges 50-2, 50-3, 50-Y (Y is a natural number). There are a plurality of logics between the subscriber accommodation devices 40-1, 40-2, 40-X-1, 40-X and the working edge 50-1 and redundant edges 50-2, 50-3, 50-Y. A logical path network N is formed by the paths L1a, L1b, L2a, L2b, L3a, L3b, L3c, L3d, L4a, L4b, L4c, and L4d.

  The logical path management control device 10 does not set a logical path to all redundant edges 50-2, 50-3, 50-Y, but rather each subscriber accommodation device 40-1, 40-2, 40-X-. 1. A logical path is set toward a redundant edge defined in advance according to the number of subscribers accommodated in 40-X. The logical path management control device 10 determines the number of logical paths to be set for redundant edges based on the collected OLT subscriber number information, and sets logical paths for the redundant edges defined in advance. To do.

  For example, in the subscriber accommodation device 40-1, when the logical path setting order is defined in the order of redundant edges 50-2, 50-3, 50-Y, the number of subscribers of the subscriber accommodation device 40-1 is The number of logical paths for redundant edges is “one” with only five people. Therefore, the logical path management control device 10 determines the number of logical paths set for the redundant edge as the number of logical paths “1” corresponding to the number of subscribers “5”, and the setting order is first. The redundant edge 50-2 is selected as a redundant edge for setting a logical path. As a result, the logical path L1b is set between the subscriber accommodation device 40-1 and the redundant edge 50-2.

  On the other hand, in the case of a subscriber accommodation device having a large number of subscribers like the subscriber accommodation device 40-X, the number of logical paths for redundant edges also increases. For example, in the case of the subscriber accommodation device 40-X, the logical path management control device 10 sets the number of logical paths set for the redundant edge to the number of logical paths “K” (K) corresponding to the number of subscribers “1000”. Is a natural number) ”, and K redundant edges 50-2, 50-3, and 50-Y defined in advance are selected as redundant edges for setting a logical path. As a result, logical paths L4b, L4c, and L4d are set between the subscriber accommodation device 40-X and the redundant edges 50-2, 50-3, and 50-Y, respectively. Accordingly, the number of logical paths to be managed and controlled by the logical path management control device 10 is, for example, 12 (= 2 × 2 devices + 4 × 2) from the previous 16 (= 4 × 4 devices). Device).

(Method 1-2)
FIG. 2 is a diagram illustrating a configuration of the logical path control system 2 according to the method 1-2. As shown in FIG. 2, the configuration of the logical path control system 2 according to method 1-2 is the same as the configuration of the logical path control system 1 according to method 1-1 described above. Therefore, the same reference numerals are used for common components, and detailed description thereof is omitted.

  Method 1-2 differs from method 1-1 in that the number of subscribers of a specific service is used when determining the number of logical paths for redundant edges. That is, the logical path management control device 10 according to the method 1-2 determines the number of logical paths to be set for the redundant edge based on the collected number of subscribers information of the specific service, and the number of logical paths defined in advance is determined for the number. A logical path is set toward the redundant edge.

  For example, in the subscriber accommodation device 40-1, when the logical path setting order is defined in the order of redundant edges 50-2, 50-3, 50-Y, the specific service subscriber of the subscriber accommodation device 40-1 The number is 60, and the number of logical paths for redundant edges is “two”. Therefore, the logical path management control device 10 determines the number of logical paths set for the redundant edge as the number of logical paths “2” corresponding to the number of specific service subscribers “60”, and the setting order is 1 The first and second redundant edges 50-2 and 50-3 are selected as redundant edges for setting a logical path. As a result, logical paths L1b and L1c are set between the subscriber accommodation device 40-1 and the redundant edges 50-2 and 50-3.

  Similarly, in the subscriber accommodation device 40-X, when the logical path setting order is defined in the order of redundant edges 50-2, 50-3, 50-Y, the specific service subscription of the subscriber accommodation device 40-X. The number of persons is 50, and the number of logical paths for redundant edges is “two”. Therefore, the logical path management control device 10 determines the number of logical paths set for the redundant edge as the number of logical paths “2” corresponding to the specific service subscriber number “50”, and the setting order is 1. The first and second redundant edges 50-2 and 50-3 are selected as redundant edges for setting a logical path. As a result, logical paths L4b and L4c are set between the subscriber accommodation device 40-X and the redundant edges 50-2 and 50-3. As a result, the number of logical paths to be managed and controlled by the logical path management control device 10 is reduced from, for example, 16 (= 4 × 4 devices) to 12 (= 3 × 4 devices). .

  Next, the configuration of each device constituting the logical path control system 1 will be described.

  FIG. 3 is a diagram showing the configuration of the logical path management control device 10. As shown in FIG. 3, the logical path management control device 10 includes a logical path management unit 11a, a logical path setting unit 11b, a redundant edge logical path calculation unit 12, a subscriber accommodation device information storage unit 13a, and an edge information storage unit 13b. A subscriber accommodation device information collection unit 14a, an edge information collection unit 14b, and an input / output unit 15. The logical path management control device 10 further includes a subscriber accommodation device setting unit 16a, an edge setting unit 16b, a subscriber accommodation device management control device cooperation unit 17a, and an edge redundancy management control device cooperation unit 17b. Each of these components is connected so that signals and data can be input and output in one direction or in both directions.

  The logical path management unit 11a manages the usage status (for example, active or redundant) of the logical path. The logical path setting unit 11b sets a logical path between the subscriber accommodation device and the working edge and the redundant edge. The redundant edge logical path calculation unit 12 determines the number of logical paths based on the collected number of subscribers information, and determines the redundant edge and the subscriber accommodation apparatus for setting the logical path. The subscriber accommodation device information storage unit 13a stores information (for example, subscriber number information) collected from the subscriber accommodation device. The edge information storage unit 13b stores information collected from the working edge and the redundant edge. The subscriber accommodation device information collection unit 14a collects information from the subscriber accommodation device. The edge information collection unit 14b collects information from the working edge and the redundant edge. The input / output unit 15 inputs / outputs various information. The subscriber accommodation device setting unit 16a sets a logical path to the subscriber accommodation device. The edge setting unit 16b sets a logical path to the working edge and the redundant edge. The subscriber accommodation device management control device cooperation unit 17a cooperates with the logical path information of the subscriber accommodation device. The edge redundancy management control device linkage unit 17b links the logical path information of the working edge and the redundancy edge.

  FIG. 4 is a diagram showing a configuration of the subscriber accommodation device management control device 20. As shown in FIG. 4, the subscriber accommodation device management control device 20 includes a logical path setting unit 21, a logical path management unit 22, a logical path management control device linkage unit 23, an input / output unit 24, a subscriber information collection unit 25, And a subscriber information management unit 26. Each of these components is connected so that signals and data can be input and output in one direction or in both directions.

  The logical path setting unit 21 causes the subscriber accommodation apparatus to set a logical path. The logical path management unit 22 manages the usage status of the logical path set in the subscriber accommodation device. The logical path management control device linkage unit 23 links logical path information with the logical path management control device 10. The input / output unit 24 inputs / outputs various information (for example, logical path information). The subscriber information collection unit 25 collects subscriber information (for example, subscriber number information) from the subscriber accommodation device. The subscriber information management unit 26 manages the collected subscriber information.

  FIG. 5 is a diagram showing a configuration of the edge redundancy management control device 30. As shown in FIG. As shown in FIG. 5, the edge redundancy management control device 30 includes a logical path setting unit 31, a logical path management unit 32, a logical path management control device linkage unit 33, an input / output unit 34, an edge information collection unit 35, and an edge information management. Part 36. Each of these components is connected so that signals and data can be input and output in one direction or in both directions.

  The logical path setting unit 31 sets logical paths for the working edge and the redundant edge. The logical path management unit 32 manages the usage status of the logical paths set for the working edge and the redundant edge. The logical path management control device linkage unit 33 links logical path information with the logical path management control device 10. The input / output unit 34 inputs / outputs various information (for example, logical path information). The edge information collection unit 35 collects edge information from the working edge and the redundant edge. The edge information management unit 36 manages the collected edge information.

  FIG. 6 is a diagram illustrating a configuration of the subscriber accommodation device 40-1. As shown in FIG. 6, the subscriber accommodation device 40-1 includes a subscriber information collection unit 41-1, a subscriber information management unit 42-1, a subscriber information setting unit 43-1, and a subscriber information notification unit 44-. 1, logical path information collection unit 45-1, logical path management unit 46-1, input / output unit 47-1, and logical path setting unit 48-1. Each of these components is connected so that signals and data can be input and output in one direction or in both directions.

  The subscriber information collection unit 41-1 collects subscriber information (for example, subscriber number information). The subscriber information management unit 42-1 manages subscriber information. The subscriber information setting unit 43-1 sets subscriber information. The subscriber information notification unit 44-1 notifies the logical path management control device 10 of the subscriber information and the logical path information. The logical path information collection unit 45-1 collects logical path information. The logical path management unit 46-1 manages a logical path set between the subscriber accommodation device 40-1 and the working edge and redundant edge. The input / output unit 47-1 inputs / outputs various information (for example, subscriber information, logical path information). The logical path setting unit 48-1 sets a logical path between the subscriber accommodation device 40-1 and the working edge and redundant edge.

  As mentioned above, although the structure of the subscriber accommodation apparatus 40-1 was demonstrated typically, the structure of the other subscriber accommodation apparatuses 40-2, 40-X-1, and 40-X is the subscriber accommodation apparatus 40-1. Since it is the same as the configuration, its illustration and detailed description are omitted.

  FIG. 7 is a diagram showing the configuration of the working edge 50-1. As shown in FIG. 7, the working edge 50-1 includes an edge information collection unit 51-1, an edge information management unit 52-1, an edge setting unit 53-1, an edge information notification unit 54-1, and a logical path information collection unit. 55-1, a logical path management unit 56-1 and an input / output unit 57-1. Each of these components is connected so that signals and data can be input and output in one direction or in both directions.

  The edge information collection unit 51-1 collects subscriber information set for the own edge. The edge information management unit 52-1 manages the usage status of its own edge. The edge setting unit 53-1 sets its own edge as the working edge. The edge information notification unit 54-1 notifies the logical path management control device 10 of edge information and logical path information. The logical path information collection unit 55-1 collects logical path information set for its own edge. The logical path management unit 56-1 manages a logical path set between the own edge and the subscriber accommodation device. The input / output unit 57-1 inputs and outputs various types of information (for example, edge information and logical path information). The logical path setting unit 58-1 sets a logical path between the own edge and the subscriber accommodation device.

  The configuration of the working edge 50-1 has been described above representatively, but the configurations of the redundant edges 50-2, 50-3, and 50-Y are the same as the configuration of the working edge 50-1, Detailed description is omitted.

  Next, the operation will be described.

  FIG. 8 is a diagram for explaining the operation of the logical path control system 1. In this embodiment, the subscriber accommodation device (OLT) 40-1 and the redundant edge 50-2 are taken as an example, and the operation will be described. However, the same operation is performed for other subscriber accommodation devices and other redundant edges. Is possible.

  First, in S1, the edge information collection unit 14b of the logical path management control apparatus 10 collects edge information by transmitting an information acquisition signal to the working edge 50-1. In S2, the working edge 50-1 responds with edge information. In other words, the working edge 50-1 transmits the logical path information of the logical path management unit 56-1 and the subscriber information of the edge information management unit 52-1 to the logical path management control device 10, and performs logical path management control. The device 10 stores the logical path information and the subscriber information in the edge information storage unit 13b.

  In S3, the subscriber accommodation device information collection unit 14a of the logical path management control device 10 collects subscriber accommodation device information by transmitting a subscriber information acquisition signal to the subscriber accommodation device 40-1. In S4, the subscriber accommodation device 40-1 responds with the subscriber accommodation device information. That is, the subscriber accommodation device 40-1 transmits the number of subscribers information of the subscriber information management unit 42-1 and the logical path information of the logical path management unit 46-1 to the logical path management control device 10, The logical path management control device 10 stores the number of subscribers information and the logical path information in the subscriber accommodation device information storage unit 13a.

  In S5, the redundant edge logical path calculation unit 12 of the logical path management controller 10 uses the information collected in S1 to S4 to determine the number of redundant edge logical paths. That is, the redundant edge logical path calculation unit 12 sorts the information collected in S1 to S4, and the redundant edge logical path according to the number of OLT subscribers from the redundant edge logical path information (see FIG. 1). Determine the number. The number of logical paths is determined for each subscriber accommodation device 40-1, 40-2, 40-X-1, and 40-X. For example, since the subscriber accommodation devices 40-1 and 40-2 have 5 and 10 subscribers, respectively, the redundant edge logical path calculation unit 12 determines the number of redundant edge logical paths as one and joins them. Since the number of subscribers of the user accommodation devices 40-X-1 and 40-X is 750 and 1000, respectively, the number of logical paths for redundant edges is determined to be K. In addition, the redundant edge logical path calculation unit 12 determines redundant edges (for example, redundant edges 50-2) for setting logical paths for the determined number of logical paths.

  In S6, the edge setting unit 16b of the logical path management control apparatus 10 instructs the redundant edge 50-2 determined in S5 to set a logical path to the subscriber accommodation apparatus 40-1. In S7, the logical path setting unit 58-1 of the redundant edge 50-2 sets the logical path to the subscriber accommodation device 40-1 according to the above instruction, and the logical path setting is completed to the logical path management control device 10. Respond.

  In S8, the subscriber accommodation device setting unit 16a of the logical path management controller 10 instructs the subscriber accommodation device 40-1 to set a logical path to the redundant edge 50-2. In S9, the logical path setting unit 48-1 of the subscriber accommodation device 40-1 sets a logical path to the redundant edge 50-2 in accordance with the above instruction, and the logical path setting is completed to the logical path management control device 10. Respond.

  In S <b> 10, the edge redundancy management controller linkage unit 17 b of the logical path management controller 10 transmits the logical path information set in S <b> 6 and S <b> 7 to the edge redundancy management controller 30. Similarly, in S11, the subscriber accommodation device management control device cooperation unit 17a of the logical path management control device 10 gives the information on the logical path set in S8 and S9 to the subscriber accommodation device management control device 20. Send.

  As described above, the logical path control systems 1 and 2 include a plurality of subscriber accommodation devices (OLTs) 40-1,..., 40-X and a plurality of redundant edges 50-2,. , And a logical path management control for controlling a logical path between a plurality of subscriber accommodation devices 40-1,..., 40-X and a plurality of redundant edges 50-2,. Device 10. The logical path management controller 10 includes a redundant edge logical path calculation unit 12 and a logical path setting unit 11b. The redundant edge logical path calculation unit 12 determines the number of logical paths set by the plurality of subscriber accommodation devices 40-1,..., 40-X as the subscriber accommodation devices 40-1,. Determine every 40-X. The logical path setting unit 11b uses the number of logical paths determined by the redundant edge logical path calculation unit 12 as a plurality of subscriber accommodation devices 40-1, ..., 40-X and a plurality of redundant edges 50-. 2, ..., 50-Y.

  Further, the logical path calculation unit 12 for redundant edges of the logical path management control device 10 determines the logical path according to the number of subscribers of each of the plurality of subscriber accommodation devices 40-1,..., 40-X. The number may be determined. Furthermore, the logical path calculation unit 12 for redundant edges of the logical path management control device 10 determines the number of logical paths so that the subscriber accommodation apparatus with a smaller number of subscribers has a smaller number of logical paths. It is good. The number of subscribers is, for example, the number of subscribers of a specific service provided by a plurality of subscriber accommodation devices 40-1, ..., 40-X.

  In other words, the logical path control systems 1 and 2 collect the number of subscribers accommodated in the subscriber accommodation devices 40-1, 40-2, 40-X-1, and 40-X or the number of specific service subscribers. And a function of setting the number of logical paths corresponding to the number toward a redundant edge defined in advance. As a result, the logical paths to be set are narrowed down, and as a result, the number of logical paths can be reduced.

(Modification)
Next, modified examples of the above-described logical path control systems 1 and 2 will be described. FIG. 9 is a diagram for explaining a modification of the logical path control systems 1 and 2. As shown in FIG. 9, there are four patterns for collecting information on subscriber information and the number of specific service subscribers. That is, a first pattern (T1) for collecting information from the logical path management control device 10 to the working edge 50-1, the redundant edges 50-2, 50-3, 50-Y and the subscriber accommodation device 40-1. On the other hand, second information is transmitted from the working edge 50-1, the redundant edges 50-2, 50-3, 50-Y and the subscriber accommodation device 40-1 to the logical path management control device 10. There is a pattern (T2). Further, a third pattern (T3) for collecting information from the logical path management control device 10 to the edge redundancy management control device 30 and the subscriber accommodation device management control device 20, and on the contrary, edge redundancy management control There is a fourth pattern (T4) for transmitting information from the device 30 and the subscriber accommodation device management control device 20 to the logical path management control device 10.

  Further, the subscriber information and the number of specific service subscribers are not necessarily the active edge 50-1, redundant edges 50-2, 50-3, 50-Y, edge redundancy management control device 30, and subscriber accommodation device 40-1. It need not be acquired from all the devices with the subscriber accommodation device management control device 20, and may be acquired from at least one device. Further, regarding the collection timing of subscriber information, the number of specific service subscribers, and logical path information, a method of periodically collecting each of the above four patterns at a predetermined period and a time defined by the administrator (on time) Two patterns with the collection method are applicable.

(Logical path control program)
FIG. 10 is a diagram showing that the information processing by the logical path control program is specifically realized by using the computer 100. As shown in FIG. 10, a computer 100 includes, for example, a memory 101, a CPU (Central Processing Unit) 102, a hard disk drive interface 103, a disk drive interface 104, a serial port interface 105, a video adapter 106, a network, and the like. These units are connected by a bus C.

  As shown in FIG. 10, the memory 101 includes a ROM (Read Only Memory) 101a and a RAM (Random Access Memory) 101b. The ROM 101a stores a boot program such as BIOS (Basic Input Output System). The hard disk drive interface 103 is connected to the hard disk drive 108 as shown in FIG. The disk drive interface 104 is connected to the disk drive 109 as shown in FIG. For example, a removable storage medium such as a magnetic disk or an optical disk is inserted into the disk drive 109. The serial port interface 105 is connected to, for example, a mouse 110 and a keyboard 111 as shown in FIG. The video adapter 106 is connected to a display 112, for example, as shown in FIG.

  Here, as shown in FIG. 10, the hard disk drive 108 stores, for example, an OS (Operating System) 108a, an application program 108b, a program module 108c, program data 108d, subscriber information, edge information, logical path information, and the like. . In other words, the logical path control program according to the disclosed technique is stored in, for example, the hard disk drive 108 as the program module 108c in which a command executed by the computer 100 is described. Specifically, the logical path management unit 11a, logical path setting unit 11b, redundant edge logical path calculation unit 12, subscriber accommodation device information storage unit 13a, edge information storage unit 13b, subscriber accommodation described in the above embodiment. Device information collection unit 14a, edge information collection unit 14b, input / output unit 15, subscriber accommodation device setting unit 16a, edge setting unit 16b, subscriber accommodation device management control device linkage unit 17a, edge redundancy management control device linkage unit 17b A program module 108c describing various procedures for executing the same information processing as each of the information is stored in the hard disk drive 108. Data used for information processing by the logical path control program is stored in the hard disk drive 108 as program data 108d, for example. Then, the CPU 102 reads the program module 108c and the program data 108d stored in the hard disk drive 108 to the RAM 101b as necessary, and executes the above various procedures.

  The program module 108c and the program data 108d related to the logical path control program are not limited to being stored in the hard disk drive 108, but are stored in, for example, a removable storage medium and read by the CPU 102 via the disk drive 109 or the like. May be. Alternatively, the program module 108c and the program data 108d relating to the logical path control program are stored in another computer connected via a network (LAN (Local Area Network), WAN (Wide Area Network), etc.), and the network interface 107 It may be read by the CPU 102 via

  Note that the value of the number of logical paths for redundant edges referred to by the logical path management control device 10 does not necessarily have to be a fixed value, such as the number of OLT subscribers, the number of subscriber accommodation devices, or the traffic volume in the carrier communication network. Depending on the situation, the system administrator or the like may variably set it. Further, a system administrator or the like defines in advance also a redundant edge selection method for setting the determined number of logical paths from the subscriber accommodation devices 40-1, 40-2, 40-X-1, and 40-X. It is not limited to the method to keep. For example, the logical path calculation unit 12 for the redundant edge of the logical path management control device 10 may preferentially select from redundant edges that are close to each other based on the distance from the subscriber accommodation device that sets the logical path. You may preferentially select from redundant edges with a small number of logical paths in use. Alternatively, the redundant edge logical path calculation unit 12 preferentially selects a redundant edge having a large memory free capacity or a redundant edge having a low CPU load ratio as a redundant edge for setting a logical path based on the resource status. Also good. Further, the redundant edge logical path calculation unit 12 may consider QoS (Quality of Service), communication data amount, communication fee, and the like when selecting a redundant edge for setting a logical path.

  In the above-described embodiments and modifications, router devices such as edge routers are assumed as the working edge 50-1, redundant edges 50-2, 50-3,..., 50-Y. The present invention is not limited to this, and can be applied to other network devices such as a repeater, a bridge, a gateway, and a switching hub.

  Further, the components of the logical path control systems 1 and 2 described above do not necessarily need to be physically configured as illustrated. That is, the specific mode of distribution / integration of each device is not limited to the illustrated one, and all or a part thereof is functionally or physically distributed in an arbitrary unit according to various loads or usage conditions. -It can also be integrated and configured. For example, regarding the logical path management control device 10, the subscriber accommodation device information storage unit 13a and the edge information storage unit 13b, or the subscriber accommodation device information collection unit 14a and the edge information collection unit 14b are integrated as one component. Also good. On the contrary, regarding the logical path calculation unit 12 for redundant edge, it is distributed into a part for sorting collected subscriber accommodation device information and edge information and a part for determining the number of logical paths for redundant edge according to the number of OLT subscribers. May be. Furthermore, the hard disk drive 108 for storing subscriber information, edge information, logical path information, etc. may be connected as an external device of the logical path control systems 1 and 2 via a network or a cable.

DESCRIPTION OF SYMBOLS 1, 2 Logical path control system 10 Logical path management control apparatus 11a Logical path management part 11b Logical path setting part 12 Logical path calculation part 13a for redundant edges Subscriber accommodation apparatus information storage part 13b Edge information storage part 14a Subscriber accommodation apparatus information Collection unit 14b Edge information collection unit 15 Input / output unit 16a Subscriber accommodation device setting unit 16b Edge setting unit 17a Subscriber accommodation device management control device linkage unit 17b Edge redundancy management control device linkage unit 20 Subscriber accommodation device management control device 21 Logic Path setting unit 22 Logical path management unit 23 Logical path management control device linkage unit 24 Input / output unit 25 Subscriber information collection unit 26 Subscriber information management unit 30 Edge redundancy management control device 31 Logical path setting unit 32 Logical path management unit 33 Logic Path management control device linkage unit 34 Input / output unit 35 Edge information collection unit 36 Edge information management unit 4 0-1, 40-2, ..., 40-X-1, 40-X Subscriber accommodation device (OLT)
41-1 Subscriber information collecting unit 42-1 Subscriber information managing unit 43-1 Subscriber information setting unit 44-1 Subscriber information notifying unit 45-1 Logical path information collecting unit 46-1 Logical path managing unit 47-1 Input / output unit 48-1 Logical path setting unit 50-1 Working edges 50-2, 50-3,..., 50-Y Redundant edge 51-1 Edge information collection unit 52-1 Edge information management unit 53-1 Edge Setting unit 54-1 Edge information notification unit 55-1 Logical path information collection unit 56-1 Logical path management unit 57-1 Input / output unit 58-1 Logical path setting unit 100 Computer 101 Memory 101a ROM
101b RAM
102 CPU
103 Hard Disk Drive Interface 104 Disk Drive Interface 105 Serial Port Interface 106 Video Adapter 107 Network Interface 108 Hard Disk Drive 108a OS
108b Application program 108c Program module 108d Program data 109 Disk drive 110 Mouse 111 Keyboard 112 Display 200 Logical path control system 200N Logical path network 201S, 202S, 203S, 204S Switching notification signal 210 Logical path management control apparatus 220 Subscriber accommodation apparatus management Control device 230 Edge redundancy management control device 240-1, 240-2, ..., 240-X-1, 240-X Subscriber accommodation device (OLT)
250-1 Working edge 250-2, 250-3, ..., 250-Y Redundant edge C Buses L1a, L1b, L1c, L2a, L2b, L2c, L3a, L3b, L3c, L3d, L4a, L4b, L4c, L4d, L201a, L201b, L201c, L201d, L202a, L202b, L202c, L202d, L203a, L203b, L203c, L203d, L204a, L204b, L204c, L204d Logical path N Logical path network

Claims (5)

A logical path control system having a plurality of first communication devices, a plurality of second communication devices, and a control device that controls a logical path between the plurality of first communication devices and the plurality of second communication devices. Because
The controller is
A determining unit that determines, for each first communication device, the number of logical paths set in the plurality of first communication devices;
A logical path control system comprising: a setting unit configured to set the number of logical paths determined by the determination unit between the plurality of first communication devices and the plurality of second communication devices.   The logical path control system according to claim 1, wherein the determination unit of the control device determines the number of the logical paths according to the number of subscribers of each of the plurality of first communication devices.   3. The logic according to claim 2, wherein the determination unit of the control device determines the number of the logical paths such that the first communication device having a smaller number of subscribers has a smaller number of the logical paths. Path control system.   The logical path control system according to claim 2, wherein the number of subscribers is the number of subscribers of a specific service provided by the plurality of first communication devices. A control device is a logical path control method for controlling a logical path between a plurality of first communication devices and a plurality of second communication devices,
A determination step of determining, for each first communication device, the number of the logical paths set in the plurality of first communication devices;
A logical path control method comprising: a setting step of setting the number of logical paths determined in the determination step between the plurality of first communication devices and the plurality of second communication devices. .

Images