JP2000341320A - Path selection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To select a shortest path by avoiding a communication path disabled due to installation work or the occurrence of a fault or in a congesting state in the path. SOLUTION: All nodes have a means that sequentially measures a state of a transmission line (execution transmission rate, congestion state and relay node number or the like) among all nodes 201-205 in a packet communication network and a means that grasps in advance a shortest path among a plurality of relay paths in the packet communication network tying terminals 101, 102 on the basis of an obtained transmission line state. Thus, the packet data are relayed through the shortest path in the network by referring to the information in the case of relaying packet data.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a route selection system, and more particularly to a route selection system that selects a shortest route while avoiding a route that is in a congested state or a route that cannot be communicated due to a construction failure or the like, thereby improving the packet data throughput. It relates to a road selection system.

[0002]

2. Description of the Related Art A plurality of packet switches are installed in a packet communication network, and each is connected by various transmission media. Each packet switch has a function of accumulating the received packet data and relaying it to the next packet switch. That is, when transmitting packet data from terminal to terminal via a packet communication network, there are a plurality of routes in the network. Here, each packet switch is called a node. Each node has a function of recognizing the state of the transmission path connecting the opposing node and selecting a transmission path (route) that is not a congestion state or a construction or failure.

[0003]

However, in the prior art, in a packet communication network connecting terminals, an optimal detour is not known, so that packet data transmission delay occurs. The first reason is that, in each node in the packet communication network, the state of the transmission path connecting the adjacent node can be confirmed, but the state of the transmission path ahead of the adjacent node cannot be confirmed in advance. . The second reason is that when there are a plurality of non-congested routes among a plurality of routes in the packet communication network, the shortest route having the smallest number of relay nodes cannot be confirmed in advance. Each node accumulates packet data as needed, causing a transmission delay. Therefore, the transmission delay increases as the number of relaying nodes increases.

Accordingly, the present invention provides a route selection system for a packet communication network connecting terminals, which avoids a route in a congested state or a route that cannot be communicated due to construction work or a failure, and has a shortest route in a short time. The challenge is to select

[0005]

According to the present invention, there is provided a route selection system for a packet communication network including a plurality of nodes of a packet switch, wherein each of the nodes is connected to its own node. Storage means for storing a transmission rate between adjacent nodes; and means for generating path information based on the transmission rate, wherein each of the nodes shares the path information, and stores packet data from a terminal. The first receiving node searches for a relay route based on the destination information in the packet data, adds the search result to the packet data and relays the packet to the next node, and the next node performs the search , And adds the result to the packet data, and relays the result to the next node.

That is, in the present invention, transmission rate information is provided to all terminals and nodes in a broadcast format, rather than the transmission rate information being collected by the node, and the transmission rate information obtained at the terminal side is obtained. The shortest path selection information is generated from the destination information of the packet data to be transmitted, the shortest path is searched, and the searched path information is added to the packet data to be transmitted in advance and transmitted to the node. Therefore, in the present invention, each node or each terminal in the packet communication network shares the latest state of all transmission line conditions in the network, and the terminal itself performs route selection to distribute the load. . The latest state of all transmission line conditions in the network is shared, for example, via a satellite line.

[0007]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a relay route diagram showing an example of route selection in a packet communication network. As shown in FIG. 1, one end of the relay path is a terminal 101 that transmits packet data, the other end is a target terminal 102, and the received packet data is
Nodes 201 to 205 in the packet communication network relaying to
It is included.

FIG. 2 is a block diagram of a node, that is, a packet switch. As shown in FIG. 2, this node
Transmission / reception means 411 for transmitting / receiving packet data to / from each route 401, and transmission rate measurement means 421 for measuring the transmission rate of packet data transmitted / received by each transmission / reception means
A storage unit 432 for sequentially storing transmission rate information measured by each transmission rate measuring unit for each route, and a timer for operating a timer for periodically collecting the transmission rate information from all surrounding nodes. Timer means 431
And signal processing means 422 for relaying the received packet data on the shortest path based on the collected transmission rate information.

[0009] The congestion state is determined, for example, by a line utilization rate, that is, a value obtained by dividing the obtained transmission rate information by the maximum line capacity of the route.

When the transmission rate monitoring timer for all nodes operated by the timer means 431 times out, a transmission rate information request signal is transmitted to all nodes to collect transmission rate information.

Subsequently, the collected transmission rate information is classified for each path between two points connecting the own node and all the other nodes, and the number of relay nodes out of a plurality of paths connecting these two points is small. In addition, the shortest path selection information rearranged in the order from the earliest transmission rate between nodes is created and stored in the storage unit 432.

Next, in the signal processing means 422 which has received the packet data from the terminal, the shortest path selection information stored in the storage means 432 is searched from the destination information in the received packet data to determine the shortest path. The retrieved packet data is added to the retrieved route information and relayed to the next node.

The next node refers to the route information in the received packet data and relays the packet to the next node.
The packet data is relayed to the target terminal.

In the transmission rate measuring means 421, the number and size (bi) of packet data transmitted and received from each route 401 (for the nodes 202, 203, and 204)
t) is sequentially added to the transmission rate of the transmission rate information 601 in the storage means 431, and the transmission rate added for each route within a fixed time is set by the timeout of the transmission rate measurement timer operated by the timer means 431. The transmission rate per unit time (Kbps) is calculated by dividing by a predetermined time, and is stored in the transmission rate information 601.

Further, the result obtained by dividing the calculated transmission rate by the maximum line capacity (bps) of the route and multiplying by 100% is stored in the transmission rate information 601 as the line utilization rate (%) of the route. When this usage rate exceeds a required value (assuming it is 60%), it is regarded as a congestion state. If the route is under construction or trouble, the line utilization rate is set to 100%. The transmission rate, maximum line capacity,
The line usage rate is stored in the transmission rate information 601.

Subsequently, when the transmission rate monitoring timer for all nodes operated by the timer means 431 times out, a transmission rate information request signal is transmitted to all nodes, and the transmission rate information report signal received from each node is transmitted. The transmission rate information is extracted and the transmission rate information 601 is extracted for each node.
To store. The transmission rate information 60 stored when the reception of the transmission rate information report signal from all the nodes is completed.
Then, the shortest path selection information 603 is generated from “1”.

FIG. 3 is a conceptual diagram showing an example of packet data. As shown in FIG. 3, the route information 50
1 and the route information 501 includes a source node number and a plurality of destination node numbers.

FIG. 4 is a table showing an example of transmission rate information 601 storing the transmission rate (bps) for each route connecting the opposing node in each node in the packet communication network. The information in the own node 201 that first receives packet data from the terminal 101 and selects a route is shown.

FIG. 5 is a table showing the relay route candidates 602 by the nodes 201 to 205.

FIG. 6 is a table showing an example of the shortest path selection information 603 for relaying packet data through the shortest path from a plurality of paths connecting the source node and the final destination node.

Hereinafter, the route selection will be described in accordance with a specific example.

According to the relay route candidate 602, the node 2
There are nine routes connecting the node 01 and the node 205. For example, when examining the route 1 from the nodes 201 to 202 to 205, it is found that the line utilization rate in the section from the nodes 202 to 205 is 100% (under construction). Also, node 201 → 202
When examining the route 3 from → 203 → 204 → 205, the line utilization rate in the section from node 203 to 204 is 70% and the congestion exceeds the required value (60%), and the number of relay nodes is the largest 4 You can see that it is a node. On the other hand, when examining the route 7 of the nodes 201 → 204 → 205, the line utilization rates in the sections from the nodes 201 → 204 and the nodes 204 → 205 are low at 41% and 20%, respectively (non-congestion state).
Also, it can be seen that the number of relay nodes is as small as 2 nodes. Here, the maximum line capacity of the node 201 → 204 is 56 Kb.
ps, the maximum line capacity of the node 204 → 205 is 64Kb
ps or the lower maximum line capacity (in this case, 56
Kbps) is defined as the effective transmission rate of the relay path 7.

As described above, the individual paths connecting the nodes 201 and 205 are checked, and the effective transmission rate is the fastest.
In addition, those which are rearranged in order from a relay route having a low line utilization rate (non-congestion state) and a smaller number of relay nodes are stored in the storage means 432 as the shortest route selection information 603.

In the node 201 that has received the packet data from the terminal 101, the destination of the received packet data is the node 205. Therefore, the shortest path among the plurality of paths connecting the nodes 201 to 205 is determined by the shortest path selection information 603. When searched, route 3 of nodes 201 → 204 → 205
02 is the shortest path. Therefore, these relay node numbers are added to the received packet data as route information 501. That is, the source node number in FIG. 3 is set to the node 201, the destination node number is set to two nodes, the first destination node number is set to the node 204, and the second destination node number is set to the node 205, and relayed to the next node, the node 204. In the node 204, the route information 50 of the received packet data
When 1 is read out, it is determined that the next node number of the own node (node 204) is the node 205, and the received packet data is relayed to the node 205.

[0025]

According to the present invention described above, it is possible to suppress a transmission delay of packet data relayed in a packet communication network connecting terminals and improve throughput. The reason is that means for sequentially measuring the transmission path state (execution transmission rate, congestion state, number of relay nodes, etc.) between all nodes in the packet communication network, and the packet connecting the terminals from the obtained transmission path state This is because all nodes have a means for previously grasping the shortest route from a plurality of relay routes in the communication network.

Further, according to the present invention, even when a sudden transmission path failure or the like occurs during relaying in a packet communication network connecting terminals, transmission delay can be minimized and reduced. The reason is that all nodes have means for preparing in advance the next candidate in the order of the shortest route and the next shortest route from among a plurality of relay routes in the packet communication network.

[Brief description of the drawings]

FIG. 1 is a relay route diagram showing an example of route selection in a packet communication network.

FIG. 2 is a block diagram illustrating a device configuration of a packet switch (node).

FIG. 3 is a conceptual diagram illustrating an example of packet data.

FIG. 4 is a table showing an example of transmission rate information for storing a transmission rate (bps) for each route connecting an own node and an opposite node.

FIG. 5 is a table showing relay route candidates.

FIG. 6 is a table showing an example of shortest path selection information.

[Explanation of symbols]

 101, 102 Terminal 201-205 Packet switch (node) 301, 302 Relay route 401 Each route in node 411 Intra-node transmitting / receiving means 421 Transmission rate measuring means in node 422 Signal processing means in node 431 Timer means in node 432 Storage means in node 501 Route information 601 Transmission rate information 602 Candidate for relay route 603 Shortest route selection information

Claims (4)

[Claims] 1. A packet communication network route selection system including a plurality of packet switching nodes, wherein each of the nodes stores a transmission rate between the node and a node adjacent thereto. Means for generating path information based on the transmission rate, wherein each of the nodes shares the path information, and a node that first receives packet data from a terminal,
A relay route is searched based on destination information in the packet data, the search result is added to the packet data and relayed to a next node, and the next node searches for route information based on the search result And adding the result to the packet data and relaying the result to the next node. 2. The route selection of a packet communication network according to claim 1, wherein when a failed node occurs, a node adjacent thereto generates route information excluding the failed node. system. 3. Each of the nodes transmits the route information generated by the own node to a satellite communication network, transmits the route information from the satellite communication network to the node, and shares the route information. Claim 1 characterized by the following:
Route selection system as described. 4. The satellite communication network transmits the transmission rate to the terminal, the terminal generates path information based on the transmission rate and destination information of packet data,
2. The route selection system according to claim 1, wherein the route information is added to the packet data and transmitted to the packet communication network.