JPWO2005117365A1 - Communication control device and communication control method - Google Patents

Abstract

In the communication control apparatus 200 provided in a certain node of the network that enables connection-type communication by configuring a path, the minimum number T of paths to be secured is set, and the number of working paths is set to T due to a failure. When the number falls below, path setting for newly securing a path is performed, and signaling for newly securing a path is performed, thereby reducing the frequency of signaling for newly securing a path. As a result, a high load state accompanying avoidance of a line failure in the network is reduced, high-speed failure handling is performed, and a highly reliable network is constructed.

Description

  The present invention relates to a communication control device and a communication control method, and more particularly to a communication control device and a communication control method for setting a path.

2. Description of the Related Art In recent years, MPLS (Multi-Protocol-Label-Switching) has attracted attention as a packet transmission method that can guarantee communication quality for voice and stream traffic in an IP network.
MPLS is a technology that enables a connection-type communication by creating a path called LSP (Label Switched Path) on a connectionless IP network.
In general, data transfer between routers used on the Internet uses an IP header as routing (route selection) information, but MPLS uses a short fixed-length identification mark called a label instead of the IP header. In a network constituted by MPLS-compatible routers (Label-Switching Router), transfer processing and route calculation processing can be separated, reducing the burden on individual routers and realizing high-speed processing. It is also possible to construct a higher level communication quality control (QoS) and a private network independent of the network configuration.
In the MPLS network, a path that is switched when a failure occurs in the working path (hereinafter referred to as a backup path) is set in addition to a currently reserved path (hereinafter referred to as a working path). Upon detection, the communication control device in the router can switch the path, bypass the failure, and transmit the packet.
Similarly, in an ATM network using a virtual path, a working path and a protection path are set in the same manner. When a failure occurs, the working path is switched to a protection path to bypass the failure.
In the conventional path switching method, as disclosed in Patent Document 1 (Japanese Patent Laid-Open No. 2003-2442202), a working path and a backup path are set in advance, and the line is identified for each line in the network. A set of line numbers that do not affect communication is registered and managed as a path management table for each path. When a failure occurs in the network, the line identification number is assigned to the device that detected the failure. Is used to switch the path by referring to the path management table based on the notification and determining whether or not switching is necessary.
FIG. 1 shows a flow from detection of a failure occurring in a working path to securing a path according to the prior art. When the conventional communication control device detects a path failure (step S1), the working path is switched to the backup path by the method described above (step S3), the routing table is updated (step S5), and the switched backup path is updated. Secured by signaling (step S7). At this time, transmission / reception of updated routing information and transmission / reception of signaling information for securing a path are performed with other nodes in the network.
In the prior art, every time a failure occurs, signaling and changing routing information are exchanged. Therefore, a network in which line failures occur frequently, such as a narrow band network or a network using a wireless section where the line is not stable. In this case, the load due to the information increases, which hinders data transmission.

An object of the present invention is to provide a communication control apparatus and a communication control method capable of reducing a high load state due to routing information and signaling information when a line failure occurs in a network.
Another object of the present invention is to provide a communication control apparatus and a communication control method capable of dealing with a line failure in accordance with network characteristics and user needs.
The communication control apparatus according to the present invention, the communication control method according to the present invention, and the communication control program according to the present invention are as follows.
(1) a routing information processing unit connected to at least one other node via a communication network;
A signaling processor connected to the other node via the communication network;
A path management processing unit connected to the routing information processing unit and the signaling processor;
The routing information processing unit transmits / receives routing information for routing data to / from the other node, and detects a path failure based on the received routing information, the failure information is sent to the path management processing unit. Send
The path management processing unit holds the minimum number T of paths to be reserved, calculates the number R of currently reserved paths taking into account the received failure information, and calculates the R as the number Compared with T, when R <T, it decides to secure a new path, performs path setting for newly securing the path, and notifies the routing information processing section of the contents of the path setting A path setting command based on the contents of the path setting is sent to the signaling processor;
The routing information processing unit transmits routing information based on the contents of the path setting to the other node,
The communication control apparatus, wherein the signaling processor performs signaling with the other node based on the received path setting command, and newly secures a path set in the path management processing unit.
(2) The communication control device according to (1) above,
The number of paths to be newly secured is D,
If the number of paths that can be secured to the maximum is M,
The path management processing unit holds D which is an arbitrary fixed value satisfying T ≦ R + D ≦ M, and performs path setting for newly securing the D paths when R <T, A communication control apparatus characterized by newly securing D paths.
(3) In the communication control device according to (2) above,
The path management processing unit is connected to an external device, receives an arbitrary D satisfying T ≦ R + D ≦ M from the external device, and a path for newly securing the D paths when R <T. A communication control apparatus that performs setting and newly secures the D paths.
(4) The communication control device according to (2) above,
A history storage unit,
The history storage unit records the secured duration of the path in the past and the probability that the path has failed,
The path control processing unit calculates the D from the duration and the probability.
(5) The communication control device according to (4) above,
The history storage unit records, in a time series, a time duration during which a path is secured and a probability that a failure has occurred in the path,
The path control processing unit calculates the D from the duration and the probability.
(6) The communication control device according to (1) above,
A routing table connected to the routing information processing unit;
In the routing table, routing information for routing data received from the other node is recorded, and the routing information processing unit includes the path setting content received from the path management processing unit. A communication control device that rewrites a routing table based on the routing information and transmits the routing information based on the contents of the path setting to the other node.
(7) The communication control device according to (1) above,
A data buffer, a data reception unit connected to the other node via a network, and a data transmission unit,
The data buffer is connected to the data receiving unit and the data transmitting unit, and when R is 0, records data received by the data receiving unit,
When the path is newly secured and 0 <R, the data transmission unit transmits the data stored in the data buffer to the other node.
(8) In a communication network in which a link is formed by a plurality of nodes,
A communication control method that is implemented in the node and sets a path to be used for data transmission,
Detecting a failure of the path having a failure;
Calculating the number R of currently reserved paths, taking into account the detected fault information;
Comparing with the minimum number T of paths to be secured, and when R <T, setting a path for newly securing a path; and
Sending routing information based on the contents of the path setting to the other nodes;
A communication control method comprising: performing signaling with the other node based on the contents of the path setting and newly securing the path.
(9) In the communication control method according to (8) above,
The number of paths to be newly secured is D,
If the number of paths that can be secured to the maximum is M,
Holding D that satisfies T ≦ R + D ≦ M, and setting a path for newly securing the D paths when R <T;
And a step of newly securing the D paths based on the path setting.
(10) In the communication control method according to (9) above,
Receiving D satisfying T ≦ R + D ≦ M from the outside;
A path setting for newly securing the D paths when R <T, and a step of newly securing the D paths based on the path settings. Control method.
(11) The communication control method according to (9) above,
Recording the duration that the path was secured in the past and the probability that the path has failed;
And a step of calculating the D from the duration and the probability.
(12) The communication control method according to (9) above,
Recording the secured duration of the path and the probability of failure of the path in time series;
And a step of calculating the D from the duration and the probability.
(13) The communication control method according to (8) above,
Rewriting a routing table for routing data received by the node based on routing information including contents of the path setting;
And a step of transmitting the routing information to another node.
(14) The communication control method according to (8) above,
If R is 0, recording data received at the node;
A communication control method comprising: securing the path and transmitting data to the other node when 0 <R.
(15) A communication control program for realizing the communication control method according to claim 8 by a computer.
The communication control apparatus according to the present invention can be applied to any form of packet communication network as long as it is a transmission method that enables connection-type communication by setting a path.
Advantageous Effects of Invention According to the communication control apparatus and method of the present invention, it is possible to reduce a high load state due to routing information and signaling information when a line failure occurs in a network.
Furthermore, according to the communication control apparatus and method of the present invention, it is possible to cope with a line failure in accordance with network characteristics and user needs.

FIG. 1 is a flowchart for explaining operations from failure detection to path securing according to the prior art.
FIG. 2 is a diagram showing a network constituted by a plurality of nodes to which the present invention is applied.
FIG. 3 is a diagram for describing an example of a virtual path configured in the network illustrated in FIG.
FIG. 4 is a block diagram of the communication control apparatus according to the first embodiment of the present invention.
FIG. 5 is a diagram used for explaining the operation of the communication control apparatus when the communication control apparatus of FIG. 4 is mounted on a certain node in the network.
FIG. 6 is a flowchart for explaining the operation from the failure detection to the new path reservation of the communication control apparatus according to the present invention.
FIG. 7 is a block diagram of a communication control apparatus according to the second embodiment of the present invention.
FIG. 8 is a block diagram of a communication control apparatus according to the third embodiment of the present invention.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 2 is a diagram showing a network 100 composed of a plurality of nodes 30, 50,... To which the present invention is applied. The network 100 is a network having an unstable line that is likely to cause a failure, such as a network using a wireless communication network or a narrow-band network.
In such a network 100, each node (for example, a certain node 30) forms a plurality of virtual paths (for example, a path 111 to a path 115) as shown in FIG. Connection-type communication for transmitting various packet data such as images and images to the counterpart node 50 can be ensured.
Referring to FIG. 4, a communication control apparatus 200 according to the first embodiment of the present invention is shown. This communication control apparatus 200 is mounted on each node of the network 100 shown in FIG. 1 (or FIG. 2).
For example, the communication control apparatus 200 is mounted on a certain node 30 in the network 100 in the state shown in FIG. 5 and is transmitted to a path currently reserved for use in communication (hereinafter referred to as a working path). When a failure such as a failure or a device failure occurs, switch to a spare path that is not in use (hereinafter referred to as a backup path), and secure a backup path to bypass the failure and obtain a reliable network. To do.
In FIG. 4, the communication control apparatus 200 includes a routing information processing unit 31, a signaling processor 32, and a path management processing unit 33. The routing information processing unit 31 is connected to the adjacent other node 40 via the network 100 (FIG. 5). The signaling processor 32 is also connected to the other node 40 via the network 100. The path management processing unit 33 is connected to the routing information processing unit 31 and the signaling processor 32.
The routing information processing unit 31 performs transmission / reception of the routing information 201 including node information on the working path, information on the used bandwidth, and information necessary for routing with the other nodes 40 to monitor the status of the working path. When the occurrence of a failure in the working path is detected, the failure information 202 is transmitted to the path management processing unit 33.
The signaling processor 32 is controlled by the path management processing unit 33, and in order to secure a backup path with the counterpart node 50 (FIG. 5) by the path setting command 203 from the path management processing unit 33, And secure the path.
The path management processing unit 33 detects a fault from the fault information 202, manages the working path and the backup path, holds the minimum number T of paths to be secured, and takes the fault information 202 into consideration. This is a part for determining the number R of paths (currently reserved paths), setting the path, notifying the routing information processing unit 31 of the contents of the path setting, and controlling the signaling processor 32.
Specifically, the path management processing unit 33 monitors the routing information processing unit 31, identifies the working path in which the failure has occurred based on the failure information 202 received from the routing information processing unit 31, and the failure has occurred. The number R of working paths other than the working path is calculated. Next, the path management processing unit 33 compares the minimum number of paths T to be retained and determines the number D of paths to be newly secured when R <T. Path setting for setting the backup path as a new working path is performed. In this way, when the path management processing unit 33 performs path setting for newly securing D paths, it notifies the routing information processing unit 31 of the path setting content 203 and sets the path setting to the signaling processor 32. A path setting command 204 based on the contents of is sent.
The routing information processing unit 31 transmits routing information based on the path setting content 202 to the other node 40. The signaling processor 32 performs signaling with the other node 40 based on the received path setting command 204 and newly secures a path set in the path management processing unit 33. In this way, the signaling processor 32 secures D backup paths as new working paths based on the path setting command 204.
FIG. 6 shows operations from failure detection to path setting of the communication control device 200 (FIG. 4) in a certain node 30 when the failure 1 occurs in the network 100 shown in FIG. ing.
Referring to FIG. 6, in FIG. 5, between the node 30 and the node 50 in the network 100, there are three working paths (path 111 to path 113) and three backup paths (path 211 to path 213). The operation of the communication control apparatus 200 (FIG. 4) of a certain node 30 when failure 1 occurs in the path 113 when set is described.
Assuming that a node adjacent to a certain node 30 is another node 40, when a failure 1 occurs in the path 113, the routing information processing unit 31 in the certain node 30 performs a failure based on the routing information received from the other node 40. And the failure information 202 is transmitted to the path management processing unit 33 (step S2).
The path management processing unit 33 specifies that the path having the failure is the path 113 based on the received failure information 202, and changes the number R of working paths from 3 to 2 (step S4).
Next, it is confirmed whether or not the number of working paths R is 0 (no normal path having no failure) (step S6). Since the number of working paths is R = 2, the number of paths D to be secured is determined. A determination process is performed (step S8).
The path management processing unit 33 holds the minimum number of paths T (T ≦ M) to be secured, where M is the maximum number of paths that can be secured. The minimum number of paths T to be secured and the number of working paths R are compared. If R falls below T, that is, if R <T, path switching is determined and the number D of newly secured paths is determined. decide. In the case of R ≧ T, D = 0.
For example, if the minimum number of paths to be secured is T = 1 or 2, R = 2, so R ≧ T, and the number of newly secured paths is D = 0. However, when T = 3, since R <T, the number D of newly reserved paths is determined.
Further, by setting the maximum number of paths that can be secured as M and setting a fixed value D satisfying T ≦ R + D ≦ M as the number of paths to be newly secured, the number of paths to be newly secured is limited, and R When <T, it is possible to secure at least D paths. For example, when M = 5 and T = 3 are set, the number D of newly reserved paths is set to an arbitrary fixed value in the range of 1 to 3, and a maximum of three paths are newly secured (maximum 3). Can be switched). At this time, for example, if D = 2 is set, if R <T, that is, if R is 0, 1, or 2, then it always operates to ensure two new paths, and R ≧ T Until it becomes, a new one-by-one pass is secured (switching one by one).
Referring to FIG. 7, there is shown a communication control device 200 ′ according to a second embodiment of the present invention. This communication control apparatus 200 ′ includes similar parts denoted by like reference numerals. In this communication control device 200 ′, T and D set in the path management device 33 are set by an external device 500 that is, for example, an NMS (Network Management System), or, for example, the external device 500 that is an input device. It is set by the user and can be changed from an arbitrary time and an arbitrary place.
Returning to FIG. 6, the continuation of the operation of the communication control apparatus 200 (FIG. 4) provided in a certain node 30 of the network 100 of FIG. 5 will be described.
As described above, the path management processing unit 33 determines whether or not D is 0 after the number D of paths to be newly secured is determined in step S8 by comparing R and T (step S10). When D = 0, no new path is set. However, when D is not 0, for example, when D = 2, new path setting (path switching) is performed to set two backup paths as working paths, and the path setting contents (path switching contents) 203 are routed. The information processing unit 31 is notified (step S12). The routing information processing unit 31 notified of the path setting contents (path switching contents) 203 transmits the routing information 201 including the path setting contents (path switching contents) to the other nodes 40 and, if necessary, the routing table. Is updated (step S14).
The path management processing unit 33 that has determined the new path setting (path switching) selects a newly reserved path and transmits a path setting command 204 to the signal processor 32. For example, when D = 2, the path management processing unit 33 selects the path 211 and the path 212 from the backup paths in FIG. 5 as the paths to be newly secured, and secures the paths 211 and 212 in the signaling processor. A path setting command 204 is transmitted. The signaling processor 32 performs signaling with the signaling processors of the nodes on the paths 211 and 212, and secures a new path (step S16). In this way, the signaling processor 32 secures D backup paths as new working paths.
As described above, by setting the minimum number T of paths to be secured when a failure occurs in the working path, path setting (path switching) is performed until the number R of working paths becomes R <T. It is no longer necessary to send and receive routing information that occurs each time a path is set (path switching), and it is not necessary to frequently perform signaling to secure a path. , It is possible to reduce a load caused by signaling for securing a path.
In step S6 described above, when a failure occurs in all the working paths and the number of working paths is lost (R = 0), the path management processing unit 33 checks the remaining number of backup paths and secures a new path. It is determined whether it is possible (step S9). If a backup path exists and a path can be secured, the process proceeds to step S8 for determining the number D of paths to be newly secured.
In addition to FIG. 6, referring again to FIG. 7, the communication control device 200 ′ includes the data buffer 36, and when a new path cannot be secured, the data reception unit 38 from the other communication control device 300 of another node. The received data 301 is stored in the temporary data buffer 36 (step S11).
When the routing information 201 from another node notifies the routing information processing unit 31 of a failure recovery or a new link, and then notifies the path management processing unit 33 that a new path can be secured (step S13). ), The process proceeds to step S8 for determining the number D of paths to be newly secured.
In FIG. 7, in the communication control device 200 ′, when a new path is secured, the data stored in the data buffer 36 is transferred from the data transmission unit 37 to the other communication control device of another node on the newly secured path. 400 is transmitted as data 302.
The communication control device 200 ′ includes a routing table 35 for routing data. At the time of path setting due to a line failure, the routing information processing unit 31 rewrites the routing table 35 as necessary by the path setting content 203 transmitted from the path management processing unit 33 to the routing information processing unit 31, The included routing information 201 is transmitted to the other node 40.
Referring to FIG. 8, there is shown a communication control apparatus 200 "according to a third embodiment of the present invention. This communication control apparatus 200" includes similar parts denoted by like reference numerals. The communication control device 200 ′ includes a history storage unit 34. The path management processing unit 33 records, in the history storage unit 34, the accumulated total duration, the total failure occurrence time, and the failure occurrence probability that have been secured for each path in the past as history information. The path management processing unit 33 calculates the required number D of newly secured paths from the history information and performs path setting. For example, in a network having a path where failures frequently occur, the path management processing unit 33 sets a larger value for the number D of newly secured paths and secures a large number of paths at a time to improve reliability. be able to. In a network having a path with few failures, the path management processing unit 33 sets D to a small value in order to minimize the exchange of signaling and the like.
Further, the history storage unit 34 records the duration and failure time secured for each path received from the path management processing unit 33 in a time series, calculates a failure probability therefrom, and stores them in a time series. Record as history. The path management processing unit 33 sets the number of paths to be secured D that changes in time series from the failure history and sets the paths. Thus, D can be determined based on the characteristics of the failure rate of the day. For example, since there are few failures during the day, D is set to a small value, and many failures occur at night. By increasing D, the number of paths to be secured can be increased, and a highly reliable network can be obtained.
The communication control apparatus for realizing the communication control method according to the present invention may be an apparatus or a program.
The communication control apparatus, the communication control method, and the communication control program according to the present invention are used in a case where the network form is frequently changed depending on a node that easily causes a failure or a node that uses a mobile body, in addition to a network that is likely to cause a line failure. In this case, it is possible to provide highly reliable communication that can reliably transmit packet data including important voices and images to the partner node.

Claims (15)

A routing information processing unit connected to at least one other node via a communication network;
A signaling processor connected to the other node via the communication network;
A path management processing unit connected to the routing information processing unit and the signaling processor;
The routing information processing unit transmits / receives routing information for routing data to / from the other node, and detects a path failure based on the received routing information, the failure information is sent to the path management processing unit. Send
The path management processing unit holds the minimum number T of paths to be reserved, calculates the number R of currently reserved paths taking into account the received failure information, and calculates the R as the number Compared with T, when R <T, it decides to secure a new path, performs path setting for newly securing the path, and notifies the routing information processing section of the contents of the path setting A path setting command based on the contents of the path setting is sent to the signaling processor;
The routing information processing unit transmits routing information based on the contents of the path setting to the other node,
The communication control apparatus, wherein the signaling processor performs signaling with the other node based on the received path setting command, and newly secures a path set in the path management processing unit. The communication control device according to claim 1,
The number of paths to be newly secured is D,
If the number of paths that can be secured to the maximum is M,
The path management processing unit holds D which is an arbitrary fixed value satisfying T ≦ R + D ≦ M, and performs path setting for newly securing the D paths when R <T. A communication control apparatus characterized by newly securing D paths. The communication control device according to claim 2, wherein
The path management processing unit is connected to an external device, receives an arbitrary D satisfying T ≦ R + D ≦ M from the external device, and a path for newly securing the D paths when R <T. A communication control apparatus that performs setting and newly secures the D paths. The communication control device according to claim 2,
A history storage unit,
The history storage unit records the secured duration of the path in the past and the probability that the path has failed,
The path control processing unit calculates the D from the duration and the probability. The communication control device according to claim 4,
The history storage unit records, in a time series, a time duration during which a path is secured and a probability that a failure has occurred in the path,
The path control processing unit calculates the D from the duration and the probability. The communication control device according to claim 1,
A routing table connected to the routing information processing unit;
In the routing table, routing information for routing data received from the other node is recorded, and the routing information processing unit includes the path setting content received from the path management processing unit. A communication control device that rewrites a routing table based on the routing information and transmits the routing information based on the contents of the path setting to the other node. The communication control device according to claim 1,
A data buffer, a data reception unit connected to the other node via a network, and a data transmission unit,
The data buffer is connected to the data receiving unit and the data transmitting unit, and when R is 0, records data received by the data receiving unit,
When the path is newly secured and 0 <R, the data transmission unit transmits the data stored in the data buffer to the other node. In a communication network in which a link is formed by a plurality of nodes,
A communication control method that is implemented in the node and sets a path to be used for data transmission,
Detecting a failure of the path having a failure;
Calculating the number R of currently reserved paths, taking into account the detected fault information;
Comparing with the minimum number T of paths to be secured, and when R <T, setting a path for newly securing a path; and
Sending routing information based on the contents of the path setting to the other nodes;
A communication control method comprising: performing signaling with the other node based on the contents of the path setting and newly securing the path. The communication control method according to claim 8, wherein
The number of paths to be newly secured is D,
If the number of paths that can be secured to the maximum is M,
Holding D that satisfies T ≦ R + D ≦ M, and setting a path for newly securing the D paths when R <T;
And a step of newly securing the D paths based on the path setting. The communication control method according to claim 9, wherein
Receiving D satisfying T ≦ R + D ≦ M from the outside;
A path setting for newly securing the D paths when R <T, and a step of newly securing the D paths based on the path settings. Control method. The communication control method according to claim 9, comprising:
Recording the duration that the path was secured in the past and the probability that the path has failed;
And a step of calculating the D from the duration and the probability. The communication control method according to claim 9, comprising:
Recording the secured duration of the path and the probability of failure of the path in time series;
And a step of calculating the D from the duration and the probability. The communication control method according to claim 8, comprising:
Rewriting a routing table for routing data received by the node based on routing information including contents of the path setting;
And a step of transmitting the routing information to another node. The communication control method according to claim 8, comprising:
If R is 0, recording data received at the node;
A communication control method comprising: securing the path and transmitting data to the other node when 0 <R.   A communication control program for realizing the communication control method according to claim 8 by a computer.

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