JPS6397040A - Communication method for packet switching communication network - Google Patents

Abstract

PURPOSE:To reduce the capacity of a packet storage device in a switching device without any delay due to order-control by executing the order-control only by the switching device to which the destination terminal of a packet is connected in case the selection and the re-transmission of a lost packet is requested. CONSTITUTION:The reception sequence of the switch device B3 finds the lose of a packet Pal by receiving a packet Pa2, and transmits a selection retransmission request. Since the packets Pa2, Pb1, Pb2 are not such ones as designated to use terminals connected to the switching device B3 as destination, the order-control is not executed for these packets, but these packets are directly transmitted to switch devices C4, C5. Since the packets Pal and Pa2 are designated to use a terminal 8 connected to the device C4 as destination, the order-control is executed by the device C4, after the reception of the packet Pa1, an original data is formed then transmitted to the terminal 8. The destination of the packets Pb1, Pb2 is a terminal that is connected to a switching device D5, therefore, the device D5, after receiving the Pb1, Pb2 by other transmission/reception sequence, forms an original data and transmits the result to a terminal 9.

Description

[Detailed Description of the Invention] [Industrial Application Field] This invention is applicable to a packet-switched communication network that packetizes and communicates data from data terminals, facsimiles, etc. This relates to a communication method when a transmission path that requires .

[Conventional method]

FIG. 1 is a block diagram showing an example of the configuration of a packet-switched communication network. In the figure, (1) is a communication satellite, and (2) is a switching device A.
, +31 is switching device B, +41 is switching device C, f51 is switching device, +61 is terminal a%, +71 is terminal S, +81
is terminal c, f91 is terminal d, (10) is switching device B (3
) to switching device C (4), and (11) is the terrestrial line running from switching device B [31 to switching device D +51.

In the packet communication network shown in FIG.
Communication satellite 11 is between +21 and switching device B +31.
) is connected by a satellite line. Hereinafter, between terminal a (6) and terminal C (8), and between terminal b (7)
) and terminal d(9) will be explained.

FIG. 2 is an explanatory diagram showing an example of a communication sequence according to a conventional communication method, in which (20) is a transmission sequence of terminal b (7), (21) is a transmission sequence of terminal a (6),
(22) , (23) , (24) p (25)
are the transmission and reception sequences of switching devices A, B, C, and D, respectively, (26) is the reception sequence of terminal C (8),
(27) is the reception sequence of terminal d(9). Also, (30) is the transmission data from terminal a (6), (31)
is transmission data from terminal b (7), (35) is packet a1, (36) is packet a2, (37) )t packet b1, (38) is bucket) b2, (39) is selected retransmission request (packet ).

Data (30) from terminal a (6:) is exchange device A +
21, where it is divided into blocks of a certain length or less, and a header containing necessary information such as a destination address is added to each block to create a packet. In the example shown in the figure, data (30) to packet al (35)
Assume that packet a2 (36) is created. Switching device fit A [2] transmits packet al (35) and packet a2 (36) to switching device B (3) via communication satellite (1). The example shown in FIG. 2 shows a case where packet al (35) is lost due to poor satellite line conditions. In the transmission/reception sequence (23) of exchange [11B +31, bucket) a2 (36) is received, so at this point, packet al (35) is lost due to packet a of bucket) a2 (36). Know.

Since the packet serial number is included in the packet header described above, it can be seen from the packet number of packet a2 (36) that packet a1 (35) has been lost.

Switching device B +31, which learned that bucket) al (35) was lost, at that point selected a retransmission request for only bucket) al (35) and set the retransmission request (39) to bucket) al
Exchange device A (transfer bucket to 21) which is the sending source of (35) notifies the loss of al (35).

In the example shown in Figure 2, data (31) is sent from terminal b (7).
is sent to exchange device 1 A 12+, where bucket)
bl (37) and packet 1-b2 (38) are created,
sent to switching device B (3), switching device t B +31
Now, the bucket)al(
Before packet bl (35) is received, packet bl (37) and packet b2 (38) are received. Exchange device B +3
1, until the retransmitted packet al (35) is received, the previously received packet a2 (36) and packet b
1 (37) and packet b2 (38) are stored in the storage device.

Switching device A (2) that received the selective retransmission request (39) knows that it is a retransmission request for packet al (35),
When packet al (35) is created first, i2 exchange device A
(The bucket stored in 21) is read from the memory of al (35) and sent to exchange device B +31.

Switching device B (3), which received the retransmitted packet al (35) in this way, has packets a1 (35) to packet bl (3B) in order of packet numbers, so packets al (35) , packet a2 (36) is sent to the switching device c (4) which is the destination, and packet bl (37) and packet b2 (3B) are sent to the switching device D (5) which is the destination. Exchange device 1
B [At 31, packet a2 (36), packet bl (37), and packet b2 (35) are sent as packets)
The process of storing the packets in the storage device until al(35) is received and transmitting the packets from the switching device B13) in the order of the packet numbers is called sequence control.

The above is an explanation of the transmission control procedure conventionally used in satellite links, but the transmission control procedure used in terrestrial links is slightly different. In other words, the receiving switching device detects the loss of a packet transmitted over the land line, sends a request to the sending switching device to retransmit all packets including the lost packet, and receives the packets in response to this retransmission request. Even if a packet with a packet number after the lost packet is received earlier, it is discarded.

In lines with long propagation times, such as satellite lines, retransmitting all packets including the lost packet, as in the transmission control procedure for terrestrial lines, would reduce communication efficiency and waste valuable resources within the packet switching network. Therefore, a transmission procedure of selective retransmission and sequence control is used.

Exchange f C (41 is packet al (35 packet a
2 (36), it returns to the original data (30) and sends it to terminal c (8). Similarly, when switching device D (5) receives bucket) bl (37) and packet b2 (3B), it restores it to the original data (31) and sends it to terminal d (9).

[Problem that the invention seeks to solve]

The conventional method described above has a problem in that packet bl (37) and packet b2 (38) are forced to wait an inappropriately long time in switching device B (3) due to order control. That is, packet bl (37), packet b2
(3B) has no relation to the lost packet al (35), so packet bl (37) and packet b2 (38
) should have been sent to switching device D (5) immediately upon arrival at switching device B +31, but due to the -regular order control, it is forced to wait as shown in Figure 2. . During this waiting time, data is stored in the storage device, so there is also a problem in that the storage device must have a large capacity.

This invention was made to solve the above-mentioned problems, and reduces the capacity of a storage device for storing packets accumulated in a switching device without causing inappropriate delays due to packet order control. The purpose of the present invention is to obtain a packet-switched communication method that can perform

[Means for solving problems]

In this invention, for a packet that is lost while propagating through a satellite line, a selective retransmission request is made at the switching device that detected the loss, and the order control required by this selective retransmission request is performed by the switching device that is the destination of the packet. carried out in
We decided not to perform order control in the switching equipment that relays packets.

[Effect]

Since the switching device that relays packets does not perform order control, packets unrelated to the lost packet are no longer unduly delayed.

〔Example〕

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

FIG. 3 is a communication sequence diagram showing an embodiment of the present invention. In the diagram, the same reference numerals as in FIG. 2 indicate the same or corresponding parts, and the reception sequence ((wing)
The left side) shows the same example as the example shown in 2-. Therefore, the explanation up to the reception sequence of switching device t B +31 will be omitted. Upon receiving packet a2 (36), it learns that packet al (35) is lost and requests selective retransmission (3
9) is also similar to the conventional method. Packet a2 (36), packet bl (37), packet b2
(39) is not a packet whose destination is the terminal connected to switching device ftB+31, so these packets are immediately sent to switching device C(4) and switching device ftD+51 without performing order control. Send. Packets al(35) and packets a2(36) are destined for terminal C(8) connected to switching device C+41, so the ordering is controlled by switching device C(4) and packets) al(35) ) and wait for the reception of the original data (30)
are assembled and sent to terminal C (8).

Also, packet bl (37), packet b2 (38
) is terminal d (9) connected to switching device D15).
) is the destination, so in the transmission/reception sequence (25) in Figure 3, the exchange @ D [51 is the packet bl (37
) and packet b2 (38) are received, the original data (
31) and sends it to terminal d(9).

As is clear from comparing FIG. 3 and FIG. 2, when using the method of this invention, terminal d (9) of data (31)
(sequence (27)) is packet al(3
5) and is not delayed due to loss of packet a2 (36) in sequence (23).

There is no need for a storage device to store packet bl (37) and packet b2 (38).

By the way, in the above embodiment, the present invention was explained for the case where a packet is lost on a satellite line, but the present invention is not limited to such a case, but can be applied to all communication lines that make selective retransmission requests. can do. However, in some packet-switched communication networks, there are communication lines that request retransmission of all packets following the lost packet, so it is necessary to determine in advance that the communication line is the one that requests selective retransmission. It is. Furthermore, it is clear that the present invention can be applied to any configuration of a packet-switched communication network.

〔Effect of the invention〕

As described above, according to the present invention, when a packet is lost on a communication line and selective retransmission is requested, the order of the packet is controlled only by the switching device to which the destination terminal of the packet is connected. This has the effect that unrelated packets are not unnecessarily delayed at the relay station, and the capacity of a storage device for temporarily storing packets in a switching device or the like can be reduced.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an example of the configuration of a packet-switched communication network, FIG. 2 is a sequence diagram showing a conventional method, and FIG. 3 is a sequence diagram showing an embodiment of the present invention. fil is a communication satellite, (2) is a replacement mA, +31 is a replacement device B, +4) is a replacement device C, and +53 is a replacement device! D.1
6) is terminal a1 (7) is terminal bi81 is terminal C%191
is terminal d, (30). (31) is data, (35) is packet a1,
(36) is packet a2, (37) is packet b1, (
38) is bucket) b2, and (39) is a selective retransmission request. Note that the same reference numerals in each figure indicate the same or corresponding parts.

Claims (1)

[Claims] The switching device receives data to be transmitted from a terminal connected to the switching device to a terminal connected to another switching device, puts part or all of the data into a data ring, and sends the data into a packet. The step of creating a packet containing necessary information such as a number and destination name in the header and sending this packet to the packet switching communication network in the order of the packet number, the switching equipment in the packet switching communication network receiving the packet,
When the existence of a lost packet is detected from the packet number of the received packet, and the communication line that received the packet is the communication line specified in advance as the communication line for the selective retransmission request, the selection for the lost packet is performed. a step of transmitting a retransmission request packet to the source of the lost packet, and having the source switching device that received the selective retransmission request packet resend the packet for which selective retransmission was requested; When a switching device receives a packet destined for a terminal that does not have a
The step of sending each packet to the next switching device in the order in which the packets are received, and the switching device that receives the packet destined for the terminal connected to the switching device performs order control and breaks down the received packets in order of packet number. A communication method in a packet-switched communication network, comprising the steps of: creating original data by processing the data, and transmitting the created original data to a destination terminal.