JPH06276230A - Asynchronous information communication control method and device - Google Patents

Abstract

PURPOSE:To reduce the processing load of routing and the congestion of a traffic by distributing and transmitting packets to plural logical channels in the transmission system of asynchronous information. CONSTITUTION:In a packet terminal 1, the information is divided into the plural packets and transmitted. In a switching node 2, the destination terminal information of the packets is read by a destination node reading part 3, the logical channels are assigned corresponding to the destination node number by a logical channel assigning part 5 by referring to a logical channel assignment table 4, the packets are outputted to physical links corresponding to the logical channels by a routing part 6, outputted through a buffer 7 to the other switching node. Then, the destination packet terminal is identified by a terminal identifying part 8, the sequence of the packets is controlled by a sequence control part 9, and the packets are outputted to a packet terminal 10. Thus, the transmission information of the terminal is distributed to the plural logical channels, transmitted to the other switching node, the plural packets from the other switching node are synthesized and outputted to the destination terminal, and the packets from the other switching node are repeated to the other switching node.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an information transmission system in an asynchronous information communication network such as a packet switching network, and more particularly to an asynchronous transmission system in which packets are distributed and transmitted by a plurality of logical channels set in advance between nodes. The present invention relates to an information communication control method and device.

[0002] In an asynchronous information communication network such as a packet switching network, a method is adopted in which information is packetized and destination information is held in the packet so that a communication path is autonomously set and transmitted in the network.

In such an asynchronous information communication control system, it is possible to reduce the burden of routing on each node, eliminate the risk of packet loss, and suppress the concentration of traffic to a specific node. desirable.

[0004]

2. Description of the Related Art Conventionally, a datagram method and a virtual circuit method are known as communication path setting methods in a packet network. In the datagram method,
Routing is performed from the destination information held in the packet for each node, and the communication path to be sent is set.

Further, in the virtual circuit system, a logical communication path is set from the information of the originating and terminating ends,
A communication path is set up by holding a packet with a logical communication channel number with the destination node defined on the source node side.

[0006]

In the datagram method, since each node through which the packet passes is routed and the communication path between the terminals is not designated, the packet may be lost on the way. In addition, the processing time of the processor for routing is required in the node, which causes a decrease in the throughput of the entire network.

In the virtual circuit method, the communication path is fixed, but in a section with a large amount of traffic, traffic tends to concentrate on a specific node or a specific link, which causes a problem that congestion is likely to occur. .

The present invention is intended to solve such a problem of the prior art, and in an asynchronous information communication network, by setting a communication path in advance, it is optimal for each node like a datagram method. Eliminates the overhead of selecting the output route, eliminates the risk of packet loss, and distributes the packets to multiple communication routes, thus concentrating traffic to specific nodes like the virtual circuit method. It is an object of the present invention to provide an asynchronous information communication control method and apparatus that can avoid the above.

[0009]

[Means for Solving the Problems] (1) In the method of the present invention, a logic for designating a communication path between arbitrary two nodes in an asynchronous information communication network including a network in which a plurality of nodes are connected via a transmission path. Packets that have been set with multiple channels, the transmission information is divided into multiple packets on the source node side and distributed over multiple logical channels, and transmitted on the destination node side over multiple logical channels. Are combined to restore the original transmission information.

(2) In the case of (1), the source node side assigns a sequence number to each packet obtained by dividing the transmission information in the order of occurrence and sends the packets, and the destination node side receives each packet according to the sequence number. The original transmission information is restored by correcting the packet inversion.

(3) In the case of (1) or (2), a plurality of logical channels are given priorities, and the source node side sends each packet to a plurality of logical channels in accordance with this priority. Weight and disperse.

In (4) and (3), the weight for distributing packets to a plurality of packets is changed according to the number of packets stored in the buffer for each outgoing route corresponding to a plurality of logical channels.

(5) FIG. 1 shows the basic configuration of the device of the present invention. In the originating packet terminal 1 accommodated in the switching node of the asynchronous information communication network, the transmission information is divided into a plurality of packets, and a sequence number indicating the generation order of each packet and destination terminal information indicating the destination packet terminal are provided. Attach and send. Further, in the exchange node 2, the destination node reading unit 3 reads the destination terminal information of the packet.

In the logical channel allocation table 4, with the destination terminal information of the packet as a key, the destination node number indicating the node to which this terminal belongs, the logical channel identifier corresponding to a plurality of logical channels, and the physical channel corresponding to each logical channel. The combination of the link number and the weight information of the allocation for each logical channel is described in advance.

A logical channel allocation unit 5 allocates a logical channel to each packet in accordance with a combination of logical channels selected from the logical channel allocation table 4 according to a destination node number, and a routing unit 6 allocates a logical channel allocation table 4 to each packet. , The physical link corresponding to the logical channel is allocated to the input packet and output.

The buffer 7 holds the packet output to the physical link and sends it to another switching node. In addition, the terminal identification unit 8 identifies the destination packet terminal in the own node from the destination terminal information of the packet output to the physical link, and the order control unit 9 controls the order of each packet from the sequence number of the packet to determine the destination packet. Output to the terminal 10.

As a result, the transmission information from the packet terminal belonging to the own node is divided into a plurality of packets, distributed to a plurality of logical channels, sent to another switching node, and received from another switching node via a plurality of logical channels. Combined multiple packets to recover the original transmission information and send it to the packet terminal of its own node, relay the packet from another switching node and transfer it to another switching node

[0018]

FIG. 2 illustrates the operation of the present invention.
11 is the originating node, 12 is the destination node,
Thirteen₁ , 13₂ , 13₃ , 13_Four , 13_Five , 13₆ , 1
Three ₇ Is a transit node. Again 14₁ Is node 13₁ ，
Thirteen₂ , 13₇ Logical channels passing through₂ Is no
Do 13₁ , 13_Four , 13₆ , 13₇ Logical Cha that passes through
Flannel, 14₃ Is node 13₁ , 13_Five , 13₇ Pass through
Is a logical channel. 15 indicates transmission information on the transmitting side
16 indicates the transmission information on the called side.

Information is exchanged between any two nodes 11 and 12.
When attempting transmission, communication must be performed beforehand between the nodes 11 and 12.
Multiple logical channels 14 that specify only the routes₁ ，
14 ₂ , 14₃ To set. Transmission at the originating node 11
The information 15 is divided according to this logical channel,
Each packet with an identifier showing its logical channel number
create.

The generated plurality of packets are distributed and accommodated in a plurality of logical channels 14 ₁ , 14 ₂ and 14 ₃ , respectively, and at the destination node 12, from the packets transmitted by distributing the respective logical channels, The original transmission information is restored and output.

At this time, since the route that goes through differs for each packet of each logical channel, the difference in delay time causes
The packet order may be reversed at the destination node. Therefore, when setting a logical channel, a route with a small delay time difference is selected, a sequence number is given to each packet in the order of occurrence time, and the destination node 12 uses this to assign the packets in the correct order. The original transmission information is restored and output.

In this case, when the packets are distributed to a plurality of logical channels and transmitted, the probabilities of being selected may be different for each logical channel, whereby specific packets in a plurality of logical channels are selected. It is possible to avoid concentration of traffic on the logical channel.

Further, the probability that each logical channel is selected may be changed according to the utilization rate of the line,
This makes it possible to prevent traffic concentration on a specific logical channel more appropriately.

[0024]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 3 shows the configuration of a node in one embodiment of the present invention, in which 21 and 22 represent packet terminals and 23 is a switching node. The exchange node 23
, 31 is a destination node reading unit that reads out information of the destination terminal held in the packet, 32 is a logical channel assignment table that defines assignment of logical channels corresponding to the destination nodes, and 33 is a logical channel that assigns logical channels to the packets. Channel allocation unit, 34 ₁ , 3
4 ₂ and 34 ₃ are routing units that determine physical links corresponding to logical channels, 35 is physical links, and 36 ₁ and 36
₂ is a buffer for holding the output packet, 37 is a terminal identification section for identifying the one destined for the packet terminal of the own node based on the information of the destination terminal attached to the packet, and 38 is the order of the packets transmitted in a distributed manner. The sequence control unit controls and restores the original transmission information and outputs it.

FIG. 4 shows an example of the structure of the logical channel allocation table. FIG. 5 shows an example of the structure of a packet transmitted to the network. Hereinafter, the asynchronous information communication control method and apparatus of the present invention will be described in detail with reference to FIGS.

The processing in the exchange node 23 is roughly divided into the following three cases. (1) When a packet is sent from the terminal to the network. (2) When a packet arrives at the terminal from the network. (3) When the packet input from the network is sent to the network again. Hereinafter, each case will be described in detail.

(1) When a packet is sent from the terminal to the network. In FIG. 3, in the terminal 21 on the transmission side,
The transmission information is divided into a plurality of packets, the information of the destination terminal and the sequence number are added to each packet, and the packet is output to the switching node 23. In the exchange node 23, the destination node reading unit 31 reads the information of the destination terminal added to the packet, and using this as a key, a plurality of nodes from the logical channel allocation table 32 to the node to which the destination terminal belongs are read as shown in (A). Select the logical channel combination of. Then, as shown in FIG. 5, an identifier indicating a logical channel is assigned to the header of each packet, and the header is distributed and output to the corresponding logical channels.

At this time, by selecting the logical channel allocation table, as shown in FIG. 4, for example, each logical channel 110, 052, 36 is associated with the destination node number 1.
By selecting a combination of logical channels having an even weight w of 2, each logical channel may be selected with equal probability to output a packet, and different weight w may be assigned to each logical channel. _11, w _12, …
By selecting a combination of logical channels marked with, each logical channel may be selected with a different probability and a packet may be output.

Further, as shown in (C), the buffer 36
By referring to the current usage at ₁ , 36 ₂ and selecting from a combination of logical channels with different weights (w _11, w _12, ...), (w _21, w _22, ...) ,. , Each logical channel may be selected with different probabilities to output a packet.

After that, each packet is sequentially sent from the logical channel allocation unit 33 to the routing unit 34 ₁ . At this time, if the selection of each logical channel is weighted, each packet is sent to the routing unit 34 ₁ with a different probability depending on the weight.

The routing unit 34 ₁ obtains a physical link number corresponding to each packet from the logical channel identifier attached to each packet by referring to the logical channel assignment table 32 as shown in FIG. The packet is output to the buffers 36 ₁ and 36 ₂ connected to the physical link via the physical link, and the packet is further sent from this buffer to the corresponding other switching node.

(2) When a packet arrives at the terminal from the network. In each of the routing units 34 _{2 and} 34 ₃ , the logical channel identifier in the packet from the corresponding other exchange node is read out, and the logical channel assignment table 32 is read.
To obtain the physical link number corresponding to each packet. When the corresponding physical link corresponds to its own node, the packet is sent to the terminal identifying unit 37.

In the terminal identifying section 37, from the destination terminal identifier attached to the packet, for example, the corresponding packet terminal 22
The packet is transmitted to the order control unit 3 at this time.
At 8, the control is performed so as to normalize the inversion of the order based on the difference in the transmission delays of the logical channels that have passed in the divided and transmitted packets, and the original transmission information is restored and output.

(3) When the packet input from the network is sent to the network again. In this case, the switching node 23 functions simply as a relay node. Each of the routing units 34 _{2 and} 34 ₃ reads out the logical channel identifier in the packet from the corresponding other exchange node, refers to the logical channel allocation table 32, and obtains the physical link number corresponding to each packet. Then, the data is output from the corresponding physical link to the other exchange node via the buffers 36 _{1 and} 36 ₂ .

[0035]

As described above, according to the present invention, in an asynchronous information communication network, a plurality of logical channels are set in advance and divided packets are transmitted, so that each node selects an optimum outgoing route. By doing so, it is possible to eliminate the overhead and eliminate the risk of packet loss.

Further, since the packets are distributed and transmitted to a plurality of logical channels, it is possible to prevent the traffic from being concentrated on a specific node, and it is possible to weight the selection of the logical channels, so that the traffic is concentrated. Can be prevented more effectively.

[Brief description of drawings]

FIG. 1 is a diagram showing a principle configuration of the present invention.

FIG. 2 is a diagram illustrating the operation of the present invention.

FIG. 3 is a diagram showing a configuration of a node according to an embodiment of the present invention.

FIG. 4 is a diagram showing a configuration example of a logical channel allocation table.

FIG. 5 is a diagram showing an example of a structure of a packet transmitted to a network.

[Explanation of symbols]

 1 Packet Terminal 2 Switching Node 3 Destination Node Readout Section 4 Logical Channel Assignment Table 5 Logical Channel Assignment Section 6 Routing Section 7 Buffer 8 Terminal Identification Section 9 Sequence Control Section 10 Packet Terminal

Claims (5)

[Claims] 1. An asynchronous information communication network comprising a network in which a plurality of nodes are connected via a transmission line, wherein a plurality of logical channels for designating a communication path are set between any two nodes, and the transmission information is set on the source node side. Is divided into a plurality of packets and distributed to the plurality of logical channels for transmission, and the destination node side synthesizes the packets distributed and transmitted to the plurality of logical channels to restore the original transmission information. A characteristic asynchronous communication control method. 2. The asynchronous information communication control method according to claim 1, wherein the source node side assigns a sequence number to each packet obtained by dividing the transmission information in the order of occurrence and transmits the packet, and the destination node side transmits the sequence number. An asynchronous information communication control method, wherein the original transmission information is restored by correcting the inversion of the order of each received packet according to. 3. The asynchronous information communication control method according to claim 1, wherein a plurality of logical channels are given a priority order, and each packet is assigned to a plurality of logical channels on the source node side in accordance with the priority order. An asynchronous information communication control method characterized by weighting and distributing each. 4. The asynchronous information communication control method according to claim 3, wherein a weight for distributing to a plurality of logical channels is set according to the number of packets stored in the buffer for each outgoing route corresponding to the plurality of logical channels. An asynchronous information communication control method characterized by changing. 5. A packet terminal (1) on the originating side accommodated in a switching node of an asynchronous information communication network divides transmission information into a plurality of packets, and a sequence number and a destination packet terminal indicating the generation order of each packet. The destination node information is added to the destination node information, and the destination node information is read from the destination node information of the packet in the exchange node (2). The destination node information of the packet is used as a key to which the terminal belongs. A logical channel in which a destination node number indicating a node, a logical channel identifier corresponding to a plurality of logical channels, a physical link number corresponding to each logical channel, and a combination of allocation weight information for each logical channel are described in advance. The allocation table (4) and the logical channel allocation table (4) are selected according to the destination node number. A logical channel assigning unit (5) that assigns a logical channel to each packet according to the selected combination of logical channels, and assigns a physical link corresponding to the logical channel to the input packet by referring to the logical channel assignment table (4). A routing unit (6) that outputs the packet, a buffer (7) that holds the packet output to the physical link and sends it to another switching node, and a destination at the own node based on the destination terminal information of the packet output to the physical link. A packet belonging to its own node is provided with a terminal identification unit (8) for identifying a packet terminal, and an order control unit (9) for controlling the order of each packet based on the sequence number of the packet and outputting it to the destination packet terminal (10). Transmission information from the terminal is divided into multiple packets and distributed to multiple logical channels to other switching nodes. Outgoing, combining multiple packets received from other switching nodes via multiple logical channels, recovering the original transmission information and sending it to the packet terminal of the own node, relaying packets from other switching nodes and performing another switching An asynchronous information communication control device characterized by transferring to a node.