JPH01241243A - Packet switching equipment - Google Patents

Abstract

PURPOSE:To reduce the packet traffic by adding a header to each short packet sending one and same relay packet switching equipment for each packet, and clarifying the presence location so as to send/receive it as one multiplex packet. CONSTITUTION:When a packet switching equipment 7 receives a packet from a terminal equipment 8, an inter-terminal communication processing means 11 applies processing a protocol and sends it to a relay switching equipment header processing means 23. On the other hand, an inter-network control packet generating means 26 generates periodically an inter-network control packet. A multiple packet transmission means 24 sends the user packet and the inter- network packet with a header added thereto respectively with the same number of the destination packet switching equipment or a relay destination packet switching equipment among the packet as one multiple packet to a relay line 10. A packet extraction means 25 receiving the multiple packet sends the number of its own packets switching equipment to a long packet decomposing means 16, reassembles the multiple packet and sends the result to the multiple packet transmission means 24.

Description

[Detailed Description of the Invention] [Field of Industrial Application] This invention uses the CCITT Recommendation x, 25 protocol to convert messages into packets.
The present invention relates to a packet switching device in a packet switching network that organizes packets into packets and switches them.

[Prior art] Figure 4 shows a patent application filed in 1982 by the same applicant as the present applicant.
This is a block diagram showing the configuration of a conventional device of this kind described in No. 30107, in which (7a) is a packet switching device, (8) is a terminal, (9) is a terminal line, and the packet switching device (7a) is a terminal line. and terminal (8) are connected. (10
) is a relay line that connects the packet switching device (7a) and other packet switching devices (not shown). (11)
is a terminal-to-terminal communication processing means, which forms an interface between the terminal (8) and the packet switching device (7a) in accordance with the CCITT Recommendation X, 25 protocol.

(12) is a short packet creation means that divides the packet data from the terminal (8) and the network control packet created by the packet switching device (7a) into packets of a certain length, and creates short packets. It is for creating (13
) is the long packet creation means, and the short packet creation means (12
) is used to organize the short packets created in step 1 into one long packet in a format compatible with the destination packet switching device. (14) is a routing processing means for selecting one of the plurality of relay lines (10) when transmitting a long packet to another packet switching device. (15) is a relay packet determining means that determines whether a packet sent from another packet switching device to the packet switching device W (7a) via the relay line (10) is addressed to its own packet switching device W (7a). or to another packet switching device.

FIG. 5 is a format diagram showing the structure of a long packet created by the long packet creation means (13) shown in FIG. The field to fill in (2) is the caller's area code,
An area to write the number of the own packet switching device (7a), (
3) is the total data length, an area where the length of all data included in this packet is written + (4-1) is the data length, an area where the length of the first data is written, (4 -n)
is the data length, an area where the length of the nth data is written, (5-1) is data (message), an area where the first data is written, (5-n) is the data, and the area where the length of the nth data is written. n
The area (6) in which the th data is written is the end, and is the area in which an identifier indicating the end of this packet is written.

Next, the operation of transmitting a packet from the terminal (8) shown in FIG. 4 to the trunk line (10) via the terminal line (9) and the packet switching device (7a) will be described.

Packets transmitted from the terminal (8) via the terminal line (9) are received by the terminal-to-terminal communication processing means (11), processed according to the protocol, and sent to the short packet creation means (12). The short packet creation means (12) disassembles the packet into packets of about 256 bytes, for example, and sends them to the long packet creation means (13).
In step 13), short packets are grouped together for each packet whose destination packet switching device is the same, and one long packet as shown in FIG. 5 is created.

The method for creating this long packet is to add and write the individual data lengths to the total data length, and write the first data length in (4-1>) and the first data length in (5-1). write the nth data length to (4-n), (5-n)
The n-th data is written to , and long packets are repeatedly created so that the length of the long packet does not exceed a predetermined range. After that, writing is completed to the destination station number (1) and caller station number (2), and the routing processing means (14
) sends a long packet to

The routing processing means (14) selects a relay line (10>) to be used for transmitting the created long packet to another packet switching device, and sends the long packet to that relay line.

Next, the operation of transmitting a packet received from the relay line (10) to the terminal (8) via the packet switching device (7a) and the terminal line (9) will be described.

Relay packet determination means (15) for packets received from other packet switching devices via the relay line (1o)
determines whether the received packet is addressed to the own packet switching device (7a) or another packet switching device based on the destination station number (1), and if the received packet is addressed to the own packet switching device (7a). It is sent to the long packet disassembly means (16), and if it is addressed to another packet switching device, it is sent to the routing processing means (14) and sent back to the trunk line (10).

The long packet disassembly means (16) disassembles the sent long packet addressed to its own packet switching device (7a) into short packets, sends them to the terminal-to-terminal communication processing means (11), and sends them to the terminal-to-terminal communication processing means (11). After processing according to the protocol in step 11), the data is transmitted to the terminal (8).

[Problems to be Solved by the Invention] In the conventional packet switching device as described above, short packets are collected for each packet whose destination is the same packet switching device and sent and received as a long packet. To the switching device: If the number of short packets to be sent is small, they are sent as one unified packet even if there are many short packets to be sent to the same relay packet switching device using the same relay line. Therefore, there was a problem in that it was not possible to perform routing processing or reduce packet traffic in such cases.

The invention 3 was made to solve this problem, and even when there are multiple short packets to be sent to the same relay packet switching device using the same relay line, the long packets to be sent to the same packet switching device are The object of the present invention is to obtain a packet switching device that can transmit and receive packets together as a single packet (hereinafter referred to as multiple packet).

[Means for Solving the Problem] A packet switching device according to the present invention attaches a necessary header to each packet of a plurality of short packets to be transmitted to the same relay packet switching device using the same relay line,
In addition, the location of each packet was clarified, and it was decided to transmit and receive it as one multiplexed packet.

[Operation] In the present invention, a plurality of short packets to be transmitted to the same relay packet switching device using the same relay line are attached with a necessary header for each packet, and after clarifying the location of each packet, Since the data is transmitted and received as one multiple baggage 1-, it is possible to further reduce routing processing and packet traffic.

[Example] Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of a packet switching device according to the present invention. In the figure, the same reference numerals as in FIG. ) Inter-terminal communication processing means (11)
A header and a packet in which the number of the destination or source packet switching device is written in the packet that has been processed according to the protocol, or the packet that the packet switching device (7) periodically sends from itself for controlling the packet switching network. (24) is a multiplex packet transmitting means which sends packets sent from the relay exchange header processing means (23) to packets whose destination packet switching device is the same,
Alternatively, means (25) is a packet extracting means for making multiple packets for each item routed to the same relay line (1o) and transmitting them to the same relay line (10). extracts the packet addressed to its own packet switching device (7) from the packet switching device (7), stores it in its own extraction packet storage buffer to make a long packet, and simultaneously sends this long packet to the long packet decomposition means (16). , means (26) for reassembling the multiplexed packets and transmitting the multiplexed packets to the multiplexed packet transmitting means (24);
) is a means for creating control packets within the network, and is used to generate status information, failure information, call connection information, etc. of the own packet switching device (7).
(hereinafter referred to as intra-network control information) to other packet switching devices; (27) is an in-stream control packet analysis means for other packets written in intra-network control packets received from other packet switching devices; This is a means for analyzing network control information of a switching device and determining the status of other packet switching devices and call connection status.

FIG. 2 is a format diagram showing the configuration of a multiplexed packet according to the present invention. In the figure, the same reference numerals as in FIG. 5 indicate the same or corresponding areas, and (17) indicates how many packets are multiplexed into this control packet. The packet multiplicity display area (18) is a multiplex destination number area where the number of each destination packet switching device for each multiplexed packet is entered. In this example, up to 9 packets are It can be multiplexed. Among these (18
1) is an area where the number of the destination packet switching device of the first packet is written, (182) is an area where the number of the destination packet switching device of the second packet is written.
89) is an area where the number of the destination packet exchange plane of the ninth packet is written.

(191) is a pointer indicating the storage position of the second packet, (201) is an area where the length of the first packet is written, and (211) is an area where the first packet is stored. Also, (192"t is a pointer indicating the n+1st packet storage position, but in this example, the nth packet is the last packet, so this pointer (192"t)
) is entered with a NULL code indicating that it is meaningless.

(202) is an area where the n-th packet length is written, (
(212) is an area for storing the n-th packet;
) is an area where the parakerat type is entered, and for packets from the terminal-to-terminal communication processing means (11), a code indicating the user parakerat is written to the intra-network control packet creation means (26).
For the parakerat from >, enter a code indicating an intra-network control packet.

FIG. 3 also shows the packet extraction means (25) shown in FIG.
28 is a format diagram showing the structure of a long packet stored in the extracted packet storage buffer of
) to (28n) are data length storage areas, (29
a) to (29n) each indicate a data storage area.

Next, the user bucket 1- from the terminal (8) and the own packet switching device (7) created by the packet switching device (7)
The operation of transmitting an intra-network control bucket containing intra-network control information from the packet switching device (7) to another packet switching device via the relay line (10) will be described.

When a packet is received from the terminal 8), the terminal-to-terminal communication processing means (11) performs protocol processing and sends the packet to the relay exchange header processing means (23). on the other hand,
The intra-network control packet creation means (26) periodically creates an intra-network control packet containing the intra-network control information of its own packet switching device, and sends it to the relay exchange header processing means (23).

In the relay exchange header processing means (23), the number of the destination packet switching device is entered in the destination station number (1a) in FIG. 2, and the number of the own packet switching device N (7) is entered in the originating station number (2a). Furthermore, for the packet sent from the terminal-to-terminal communication processing means (11) to bucket 1 in the culprit area (22), a code indicating a user packet is sent from the network control packet creation means (26). A code indicating an in-network control packet is written for each incoming packet, and the destination station number (la) and caller station number (2) are written in this packet.
a) Add a header containing the packet type (22) and send it to the multiplex packet transmission means (24). The next multiplex packet transmitting means (24) transmits the terminal-to-terminal communication processing means (11).
) packets with the same destination packet switching device number (hereinafter referred to as , the destination packet switching device is different, but the routed relay line (10
) are the same and have the same relay destination packet switching device number (hereinafter referred to as ■), or if there are multiple packets that satisfy both conditions ■ and ■, these packets are The packets are combined into one, creating a multiplexed packet shown in the format shown in FIG. 2, and transmitted to the trunk line (1o).

Therefore, there are three types of multiplex packets: a multiplex packet containing multiple buckets 1- consisting only of ■, a multiplex packet combining multiple packets consisting only of ■, and a multiplex packet containing a mixture of ■ and ■. It will exist.

Next, a method for creating multiplexed packets will be explained using FIG. 2. Enter the number of the destination packet switching device in the destination station number (1), enter the number of the source packet switching device (7) in the sender station number (2), and enter the number of the transmitter in the multiplicity (17). Enter a value indicating whether the packets are multiplexed.

Next, the first destination number (18) of the multiple destination number (18) is
Enter the number of the final destination packet switching device for the first packet in 1) and the number of the final destination packet switching device for the second packet in (182) to multiplex these operations. Repeat for the number of packets.

Next, the length of the first packet is written in the first packet length (201), and a short packet is written in the first packet (211), but this packet has the destination station number (1
In a), enter the number of the destination packet switching device and the caller area number (
A header storing the number of the source packet switching device (7) and the packet type (22) is added to 2a).

Next, in the pointer (191), the second packet storage position calculated from the packet length of the first packet and the length of the stored packet is written.

In this way, the second. 3rd... Write about the n-th packet, write the NVLL code indicating that this pointer is invalid in the pointer (192>), and write the NVLL code indicating that this pointer is invalid in the n-th packet length (202). The packet length of the n-th packet, which is the final short packet, and the n-th packet are entered in the n-th packet (212) to complete the creation of the multiplex packet.

Next, processing of multiplexed packets received from other packet switching devices via the relay line (10) will be explained.

The packet extraction means (25) which received the multiplexed packets,
The number of the destination packet switching device of each multiplexed packet written in the multiple destination number (18) is compared with the number of its own packet switching device (7), and the number of the matching packet is checked. Pointer to storage location (1
91) and store each extracted packet in extraction bucket 1 to storage buffer, respectively. Repeat this operation for the number of times the multiplexed packet is multiplexed,
All packets addressed to the own packet switching device (7) are extracted from the multiple packets and transferred to the buffer. After completing the extraction, the packet extraction means <25) sends the contents of the extracted packet storage buffer to the long packet decomposition means (16), and at the same time, reassembles the multiple packets and sends them to the multiple packet transmission means (24).

The long packet decomposition means (16) refers to the packet type entry area (22) included in the header of each packet data from the contents of the extracted packet/storage buffer, and
- is a user packet, the terminal-to-terminal communication processing means (1
1>, and if the packet is a local control packet, the operation of sending the packet to the internal network control packet analysis means (27) is repeated for the number of times the packet is multiplexed.

On the other hand, the multiplex packet transmitting means (24) receives and receives the multiplexed packets reassembled by the packet extracting means (25).
The - line of the relay line (10) is selected while referring to the number of the destination packet switching device having the destination station number (1), and the multiplexed packet is transmitted to the relay line (10>).

On the other hand, the inter-terminal communication processing means (11) which receives the user packet from the long packet disassembly means (16) performs processing according to the protocol and then transmits it to the terminal 8).

Further, the intra-network control packet analysis means (27) which receives the intra-network control packet from the long packet disassembly means (16) analyzes the intra-network control information of other packet switching devices installed in the packet. , determine the status of other packet switching devices and the status of call connections.

[Effects of the Invention] As explained above, the present invention attaches a necessary header to each packet of a plurality of short packets to be transmitted to the same relay packet switching device using the same relay line, and Since we decided to clarify the location of the packet before sending and receiving it as one multiplexed packet, if there are many short packets to be sent to the same relay packet switching device using the same relay line, it is possible to send and receive them as one multiplexed packet. In such a case, it is also possible to reduce routing processing and packet traffic.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of a packet switching device according to the invention, FIG. 2 is a format diagram showing the configuration of a multiplexed packet according to the invention, and FIG. 3 is a diagram showing the configuration of a long packet stored in the extracted packet storage buffer. FIG. 4 is a block diagram showing the configuration of a conventional device, and FIG. 5 is a format diagram showing the configuration of a conventional long packet. (7) is a packet switching device according to the present invention, (8) is a terminal, (9) is a terminal line, (10) is a trunk line, (11)
is an inter-terminal communication processing means, (16) is a long packet decomposition means, (23) is a relay exchange header processing means, (24) is a multiplex packet transmission means, (25) is a packet extraction means, (
26) is an intra-network control bucket 1 creation means, and (27) is an intra-network control packet analysis means. Note that the same reference numerals in each figure indicate the same or corresponding parts. Agent Masuo Oiwa Figure 2 Figure 5

Claims (1)

[Scope of Claims] Messages addressed from a terminal belonging to one's own station to a terminal belonging to another station are transmitted in the form of packets to a packet switching network, and among packets received from the packet switching network, those addressed to the own station are In a packet switching device that performs terminal-to-terminal communication processing for the terminal specified by the packet, the destination packet switching device out of the packets generated within the packet switching device or received from the packet switching network within a predetermined period of time is The same or the destination packet switching device is different but the relay destination packet switching device is the same.
If there are multiple packets that satisfy at least one of the following conditions, these packets are combined into a multiple packet with the number of each destination packet switching device added as a multiple destination number, and this multiple packet is subjected to routing processing. If the multiplex destination number of the multiplexed packet received from the packet switching network includes the number of the packet switching device, the received multiplexed packet is disassembled into packets addressed to the packet switching device. A packet switching device comprising: means for inserting.