JP3504491B2 - Packet communication method - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a packet communication system. The present invention particularly relates to a retransmission control technique in broadcast packet communication in which data such as a file is broadcast from one center station to a plurality of user stations by one transmission, and retransmission due to reception failure is also broadcast.

[0002]

2. Description of the Related Art In the case of a communication method in which all data is reliably transmitted from a center station to a plurality of user stations such as file transfer, when the user station succeeds or fails in receiving a packet, the user station confirms its response (completion of reception). , A retransmission request) is transmitted to the center station, and the center station receives the acknowledgment and then retransmits or newly transmits the next packet. Further, since the retransmission is also carried out by the broadcast, a method is adopted in which the retransmission requests from the user stations are once aggregated in the center station, processed so that the retransmissions do not overlap, and only the packets necessary for the retransmission are transmitted.

However, when collecting the response confirmation from the user stations, if there are many user stations, the response confirmation is concentrated on the center station. In this case, the center station processes a large number of response confirmations in a short time and determines whether to resend or to send a new packet. Also, since a large number of response confirmations are transmitted on the network, the traffic increases and the network cannot be used efficiently.

Conventionally, the following method has been carried out so that such a problem does not occur. 1. Response confirmation is distributed by delaying the timing of issuing response confirmation at each user station. 2. In each user station, the retransmission confirmation signal is transmitted only when the packet reception fails, and the reception completion signal is not transmitted, thereby reducing the response confirmation.

[0005]

In the above method 1, the total throughput is reduced because the transmission timing of the response confirmation is delayed by the user station. Further, even when distributed, when the number of user stations increases, concentration of response confirmation occurs at the center station. Also, with the method such as the above-mentioned method 2, the concentration of response confirmation can be reduced, but when a plurality of user stations fail to receive the same packet, the same retransmission request signal is transmitted on the network. For this reason, it is not possible to reduce the number of these duplicated retransmission requests, so that when a large number of user stations that have failed in reception occur at the same time, retransmission requests concentrate. As described above, it is necessary to reduce the number of duplicate retransmission requests, reduce the processing load on the center station, and reduce the traffic to use the transmission line efficiently.

The present invention solves such a problem, and an object of the present invention is to provide a packet communication system which reduces the number of retransmission requests transmitted to a center station and reduces the processing load of the center station. Another object of the present invention is to provide a packet communication system that can reduce the traffic of a retransmission request signal and can efficiently use a transmission line.

[0007]

In SUMMARY OF to the present invention, and a single central station and a plurality of user stations, said central station was with means for broadcast transmission of packets to a plurality of user stations of the retransmission request packet In the packet communication method, the user station comprises means for making a retransmission request for a packet that has failed to be received. retransmission request intends row a retransmission request for unsuccessfully received packets to said central station with a probability which does not overlap.

In the present invention, the user station makes a retransmission request to the center station only when reception fails, but at this time, the retransmission request from a plurality of user stations is controlled so as to have a certain probability that the retransmission requests do not overlap. To be done. As a result, the number of retransmission requests from the user station is reduced, so the processing load on the center station is reduced. Further, since the increase in traffic for the retransmission request is suppressed, it is possible to efficiently use the transmission path.

There are two methods for setting the probability of the user station making a retransmission request: one for notifying the user station of the probability from the center station and one for setting at the user station.

In order to notify the probability to all users from the center station, the center station obtains the probability that only one station among the user stations that fails to receive after transmitting one packet will make a retransmission request, and broadcast this to the user stations. Means for notifying may be included.

Of the resend request signals received within the unit time at the center station, the total N of the duplicated packet numbers is used to derive the probability 1 / N that the resend request signals transmitted from the next user station will not overlap. . In the center station, the probability in this case is the probability that only one station among the user stations that fails to receive one packet when the center station transmits one packet transmits the retransmission request signal. As a result, the retransmission request signal is transmitted with a probability that one of the user stations that fails in reception at the same time makes a retransmission request, and thus the number of retransmission request signals is reduced as compared with the conventional case. In addition, since the retransmission packet is retransmitted to a plurality of user stations by broadcast, the user station that failed in reception and did not make a retransmission request also receives the reception failure packet, so that the reception failure can be recovered.

Next, as a first method for setting the probability that the user station makes a retransmission request, the first is that the user station sets 1
It is possible to include means for estimating the number of user stations that fail to receive the same packet at the same time when the reception fails at the time of packet reception, and calculating the probability that one station will make a retransmission request. As this method, the center station notifies all user stations of the total number m of user stations. The user station derives the probability of reception failure when receiving one packet at each station. The probability set by the user station is assumed that all user stations have the same packet reception status as that of the user station, and if the user station fails in reception, the number of user stations that fail to receive the same packet at the same time is estimated. The probability is that the user station makes a retransmission request.

As a result, since the retransmission request signal is transmitted from the user station with a probability that the retransmission requests from a plurality of user stations do not overlap, the traffic of the retransmission request signal is reduced,
The processing load on the center station is reduced. In the user station that has failed in reception, the reception failure packet is retransmitted including the user station that does not make a retransmission request, so that the reception failure can be recovered.

As a second means for setting the probability that the user station makes a retransmission request, the user station includes means for setting the probability that the received packet is a retransmission packet when the own station receives one packet. You can

As a third aspect, the user station may include means for setting the proportion of the retransmission request packets of the own station in the retransmission packets as the retransmission request probability.

Similar to the first and second ones, it is possible to make a retransmission request with a probability that retransmission requests from a plurality of user stations do not overlap.

The user station may include means for making a retransmission request to the center station immediately after detecting the reception failure.
It may also include means for making a retransmission request after a predetermined period of time has elapsed after detecting the reception failure. Even if the retransmission request is made immediately after the reception fails, the traffic does not increase as a whole, and the retransmission request may be made to be distributed after a predetermined period as in the conventional case.

The user station can make a retransmission request immediately after reception failure with a set probability. Also, after reception failure, a timer for waiting for retransmission can be activated to wait for retransmission. However, if the requested packet is not sent and times out, as a method of requesting retransmission to the center station,
There are two methods: The first is to make a retransmission request to the center station without fail when the timer times out.
The second is a method of making a retransmission request to the center station with the probability that a timeout will occur within the number of reception failures at the local station.

In the case of time-out, it is preferable to change the probability of making a retransmission request to a higher probability than before, depending on the next reception failure at the user station. As a result, it is possible to increase the probability of recovery of reception failure due to packet retransmission.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a packet communication system according to an embodiment of the present invention. One center station 1 and a plurality of user stations 2 are provided, and packet transmission from the center station 1 to the user station 2 is performed via the communication satellite 3 and the user station 2
In this example, the signal transmission from the center station 1 to the center station 1 is performed via the terrestrial public telephone network. The center station 1 is provided with a computer 4 for storing file data to be transmitted to the user station 2 and a transmitter 5 for transmitting the data from the computer 4 to the communication satellite 3. The user station 2 includes a receiving device 6 that receives data transmitted from the communication satellite 3 and a terminal 7 that stores the received data.

The computer 4 packetizes the data, adds consecutive numbers to each packet, and transmits the data to the transmitter 5.
Is transmitted to the communication satellite 3. Further, when the retransmission request signal is received from the user station 2, the packet number added in the retransmission request signal is detected and the packets after that number are retransmitted. In the receiving device of the user station 2, the packet is normally received for each number added to each packet, data is constructed if the packet is normally received, and if the packet is not normally received, the packet number of the packet that has failed to be received by the center station 1. The re-transmission request signal added with is transmitted through the public network.

The center station 1 divides a series of data such as file data into a plurality of packets, and adds consecutive numbers to each packet for transmission. When one packet is sent to all users by broadcast, it is checked whether or not a resend request signal is received before sending the next packet (or while sending a batch of packets sent at a certain unit time), If the retransmission request signal is not received, the packet of the next number (or the packet of the next transmission group) is transmitted. If a retransmission request signal is received, the number of the packet to be transmitted is returned to the packet with the number attached to the retransmission request signal, and the packet is transmitted again (this is called Go Back N).

The user station 2 takes out the data from the normally received packet and assembles it into the original format data (for example, data like a file). Whenever one packet is received, if it is normally received, the reception completion signal is not transmitted to the center station 1 and data is assembled to wait for the next packet, but if it is not normally received, the center station 1 A retransmission request signal with the number of the packet that could not be received is added at the probability P. Here, the present invention is
The user station 2 is characterized by setting, as the probability P of transmitting the retransmission request signal in the case of not normally receiving, a certain probability such that the retransmission requests do not overlap when a plurality of user stations fail to receive at the same time. And This probability is set by the center station 1 for each user station, or set by each user station.

Some examples of the retransmission control in the above embodiment will be described below.

(First Embodiment) FIG. 2 shows a flow of retransmission control of the first embodiment, and FIG. 3 shows a sequence.
In the first embodiment, the probability derived by the center station 1 is set in each user station 2. Among the resend request signals received by the center station 1, those having duplicate packet numbers are measured for a certain period of time, and a total N of duplicated resend request signals within a unit time is derived. The center station 1 adds this probability to the transmission packet and notifies all the user stations. When the user station 2 receives the packet with the probability P = (1 / N),
When the probability 1 / N is set in the own station and the retransmission request signal is transmitted next time, the retransmission request signal is transmitted according to this probability.

An example will be described. It is assumed that there is one center station 1 and two user stations A and B. Center stations 1 to 1
Send 0 packets. It is assumed that the user station A has a worse reception status than the user station B. Consider a case where the user stations A and B fail to receive the packet with the number 3. The center station 1 receives two packet 3 retransmission request signals. Center station 1
Is added to the retransmission packet with a probability P = 1/2 so that the user station 2 will not transmit a duplicate retransmission request next time.
Retransmit from the packet. The user stations A and B receive the retransmission packet, extract the probability P = 1/2, and set it as the probability at the time of transmitting the next retransmission request signal. After this, consider a case where the slave stations A and B have failed to receive the packet with the number 7. In this case, each user station A, B transmits a retransmission request signal with a probability of 1/2. Here, it is assumed that the user station A transmits the retransmission request signal and the user station B does not transmit the retransmission request signal. After receiving the resend request signal, the center station 1 resends the packet of number 7. In this case, the reception failure packet is retransmitted also for the user station B that has not transmitted the retransmission request signal, and the reception failure can be recovered for both the user stations A and B.

(Second Embodiment) Next, a second embodiment will be described. FIG. 4 shows the flow of retransmission control of the second embodiment, and FIG. 5 shows the sequence. The second embodiment differs from the first embodiment in that the probability is set in each user station. Here, the center station 1 sends all user stations to all user stations m
I will notify you. The user station 2 receives the number N of packets transmitted from the center station 1 when the user station fails to receive the packet.
p and the number N1 of reception failures at the local station so far are measured, and the probability of reception failure when one packet is received Q = (N1 /
Np) is derived. Here, the probability set by the user station 2 is assumed to be the same as the packet reception status of all the user stations, and the number of user stations that fail to receive the same packet when the own station fails to receive (m * Q) and the probability P = {1- (1-Q) ^m } that the retransmission request signals do not overlap.
/ (M * Q)

One center station 1 and two user stations A and B
There is. The center station 1 transmits 10 packets. Before data transmission, the center station 1 notifies each user station A and B of the total number of users of 2. User stations A and B are number 7
Consider the case where the reception of the packet has failed. at this point,
Since the user stations A and B have failed to receive two packets, the user stations A and B derive Q = 1/4 as the probability of failure to receive within a unit time. Therefore, at this time, the probability P of transmitting the retransmission request of the user stations A and B is 7/8. Here, it is assumed that the user station A transmits the retransmission request signal and the user station B does not transmit the retransmission request signal. After receiving the resend request signal, the center station 1 resends the packet of number 7. In this case, the reception failure packet is retransmitted also for the user station B that has not transmitted the retransmission request signal, and the reception failure can be recovered for both the user stations A and B.

(Third Embodiment) Next, a third embodiment of the present invention will be described with reference to FIGS. FIG. 6 shows a flow of retransmission control, and FIG. 7 shows a sequence.

This third embodiment also sets the probability of making a retransmission request at each user station. In the third embodiment, the user station 2 measures the number of transmitted packets Np and the number of retransmitted packets Ns of the retransmitted packets transmitted from the center station 1 which the local station has not requested to retransmit at the time of unsuccessful reception, When one packet is transmitted from the center station 1, the probability (Ns / Np) that it is a retransmission packet is derived, and this probability is set by the user station 2. As described above, the third embodiment is different from the second embodiment in that the setting probability is the probability that a retransmission packet will be transmitted when the local station fails to receive (Ns
/ Np) is used.

One center station 1 and two user stations A and B
There is. The center station 1 transmits 10 packets. It is assumed that the user station A has a worse reception status than the user station B. Consider a case where the user station A fails to receive the packet with the number 3. After the reception failure, the user station A activates a timer and waits for a retransmission packet, and at the same time, the user station A transmits a retransmission request signal for the packet of number 3. The center station 1 receives the retransmission request signal for packet 3, is retransmitted from packet 3, and both user stations A and B receive the retransmission packet. At this time, since the user station B has not transmitted the retransmission request,
Measure the number of retransmitted packets.

After this, consider a case where the user stations A and B have failed to receive the packet of number 7. In this case, user station B
Since the number of packets Np transmitted to the center station 1 is 8 and the number of retransmission packets Ns that the local station has not requested to retransmit is 3 among the retransmissions transmitted from the center station 1, the user station B has a probability of 3
A retransmission request signal is transmitted at / 8. Also, the user station A is N
Ns = 0 for p = 8. When Ns = 0, the retransmission request signal is always transmitted. Here, it is assumed that the user station A transmits the retransmission request signal and the user station B does not transmit the retransmission request signal. After receiving the retransmission request signal, the center station 1
The packet with the number 7 is retransmitted. In this case, the reception failure packet is also retransmitted for B that did not transmit the retransmission request signal, and the reception failure can be recovered for both user stations A and B.

(Fourth Embodiment) Next, a fourth embodiment of the present invention will be described with reference to FIGS. FIG. 8 shows the flow of retransmission control, and FIG. 9 shows the sequence. This fourth embodiment is different from the second and third embodiments in that
The user station 2 measures the number Nr of retransmission packets transmitted from the center station 1 and the number N1 of reception failures so far at the time of reception failure, and the probability (N1 / Nr) is set at the user station.

One center station 1 and two user stations A and B
There is. The center station 1 transmits 10 packets. It is assumed that the user station A has a poorer reception state than the user station B. After the reception failure, the user station A activates a timer and waits for a retransmission packet, and at the same time, the user station A transmits a retransmission request signal for the packet of number 3. The center station 1 receives the retransmission request signal of packet 3 and retransmits it from packet 3. Since both user stations A and B receive the retransmission packet, the number of retransmission packets Nr is measured. After this, consider a case where the user stations A and B have failed to receive the packet of number 7. In this case, since the user station B has the number of retransmitted packets Nr = 3 and the number of packets that the own station has failed to receive N1 = 1, the probability 1 /
At 3, the retransmission request signal is transmitted. The user station A receives the number of retransmitted packets Nr = 3, and the number of packets that the own station fails to receive N1
= 2, the retransmission request signal is transmitted with a probability of 2/3. Here, it is assumed that the user station A has transmitted the retransmission request signal and the user station B has not transmitted the retransmission request signal.
The center station 1 retransmits the packet of number 7 after being confident of the retransmission request signal. In this case, the reception failure packet is retransmitted also for the user station B that has not transmitted the retransmission request, and the reception failure can be recovered for both the user stations A and B.

(Fifth Embodiment) Next, a fifth embodiment of the present invention will be described with reference to FIGS. FIG. 10 shows the flow of retransmission control, and FIG. 11 shows the sequence. In the fifth embodiment, when the user station 2 fails to receive a packet, it activates a timer and waits for a resend packet. If the timer times out, the total number of timeout occurrences Nt and the total number of packet reception failures Nl result in a reception failure. Probability that timeout will occur within the number of times R = Nt /
The resend request signal is transmitted at Nl.

One center station 1 and two user stations A and B
There is. 10 packets are transmitted from the center station 1. It is assumed that the user station A has a worse reception status than the user station B. Consider a case where the user station A fails to receive the packet with the number 5. It is assumed that the user station A has once failed to receive the packet at this point, but has received the retransmitted packet by the time-out of the retransmit timer. When the user station A detects the reception failure of the packet with the number 5, the user station A
Does not transmit a resend request signal. Since user station B has not failed to receive, user station A will time out. In this case, the user station A transmits a retransmission request signal with a probability R = 1/2 from Nl = 2 and Nt = 1.

(Sixth Embodiment) Next, a sixth embodiment of the present invention will be described with reference to FIGS. FIG. 12 shows the flow of retransmission control, and FIG. 13 shows the sequence. In the sixth embodiment, when the user station 2 fails to receive a packet, it activates a timer and waits for a retransmission packet. If the timer times out, the user station 2 sends a retransmission request from the next reception failure at the user station. Use a higher probability than before. This probability is the number N of times the user station fails to receive at the time when the user station fails to receive.
1. Probability of using the number Nt of times out (Nt /
Nl) is set first (the second embodiment, the third embodiment,
This is added to the probabilities of the fourth and fifth embodiments.

One center station 1 and two user stations A and B
There is. 10 packets are transmitted from the center station 1. It is assumed that the user station A has a worse reception status than the user station B. Consider a case where the user station fails to receive the packet with number 3. At this time, the user station A does not transmit the retransmission request signal. Since user station B has not failed to receive, user station A will time out. Then, the user station A transmits a retransmission request signal, and the center station 1 starts the retransmission. After that, the probability of transmitting the retransmission request in the user station A is changed to the probability (P + Nt / Nl) larger than the previous probability P by Nt / Nl. Next, when the user station A fails to receive the packet with the number 6, Nt = 1, Nl =
2, the retransmission request signal is transmitted with a probability of P + 1/2.

[0040]

EFFECT OF THE INVENTION The probability that a user station is set to make a retransmission request is such that one of the user stations that is erroneous at the same time so that the retransmission requests received at the center station do not overlap, sends a retransmission request to the center station. It is a probability to do. Due to this probability, a user station that frequently fails to receive requests sends a retransmission request to the center station with a higher probability than a user station that rarely fails to receive, so it is possible for a user station to receive a retransmission packet without sending a retransmission request to the center station. You can Also, since the number of retransmission request signals transmitted to the center station is reduced, the processing load on the center station can be reduced and the traffic can be used efficiently.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of an embodiment of a packet communication system of the present invention.

FIG. 2 is a flowchart showing a flow of transfer control according to the first embodiment.

FIG. 3 is a diagram showing a sequence of transfer control according to the first embodiment.

FIG. 4 is a flowchart showing the flow of transfer control according to the second embodiment.

FIG. 5 is a diagram showing a sequence of transfer control of the second embodiment.

FIG. 6 is a flowchart showing the flow of transfer control according to the third embodiment.

FIG. 7 is a diagram showing a transfer control sequence of a third embodiment.

FIG. 8 is a flowchart showing the flow of transfer control according to the fourth embodiment.

FIG. 9 is a diagram showing a sequence of transfer control according to a fourth embodiment.

FIG. 10 is a flowchart showing the flow of transfer control of the fifth embodiment.

FIG. 11 is a diagram showing a transfer control sequence of the fifth embodiment.

FIG. 12 is a flowchart showing the flow of transfer control according to the sixth embodiment.

FIG. 13 is a diagram showing a sequence of transfer control according to the sixth embodiment.

[Explanation of symbols]

1 Center station 2 user stations 3 communication satellites 4 computers 5 transmitter 6 Receiver 7 terminals

Continuation of the front page (56) Reference JP-A-11-187017 (JP, A) JP-A-10-200577 (JP, A) JP-A-11-17737 (JP, A) (58) Fields investigated (Int .Cl. ⁷ , DB name) H04L 12/18 H04L 1/16 H04L 12/56

Claims (8)

(57) [Claims] 1. A center station and a plurality of user stations are provided, and the center station includes means for transmitting packets to a plurality of user stations by broadcast and means for retransmitting packets for which retransmission is requested by broadcast. In the packet communication method, wherein the user station includes means for requesting retransmission of a packet that has failed to be received, the center station fails to receive after transmitting one packet.
Before calculating the probability that only one of the user stations will make a retransmission request
Comprising means for notifying at broadcasting the serial user stations, the user station, packet communication, characterized in that it comprises means for performing a retransmission request for unsuccessfully received packets to said central station at the notified probabilities from said center station method. 2. A center station and a plurality of user stations are provided.
The center station broadcasts packets to multiple user stations.
A means for sending and a packet for which a resend request has been made
The user station is provided with
Packet communication system equipped with a means for requesting retransmission of
If the user station fails to receive one packet,
The number of user stations that fail to receive the same packet at the same time
And means to calculate the probability that one station will make a retransmission request
With this calculated probability, the center station will fail to receive a packet.
A packet communication system comprising means for making a packet retransmission request . 3. A center station and a plurality of user stations are provided.
The center station broadcasts packets to multiple user stations.
A means for sending and a packet for which a resend request has been made
The user station is provided with
Packet communication system equipped with a means for requesting retransmission of
Then, when the user station receives one packet,
Means for setting the probability that a received packet is a retransmitted packet
And the reception failure at the center station with this set probability
And a means for making a packet retransmission request.
That packet communication system. 4. A center station and a plurality of user stations are provided.
The center station broadcasts packets to multiple user stations.
A means for sending and a packet for which a resend request has been made
The user station is provided with
Packet communication system equipped with a means for requesting retransmission of
Then, the user station selects the retransmission request packet of its own station in the retransmission packet.
The percentage occupied by the packet is set as the retransmission request probability.
Means and reception failure at the center station with this set probability
And a means for making a retransmission request for the completed packet.
And packet communication method. 5. The user station immediately after detecting the reception failure.
Claims 1 including means for performing a retransmission request by the probability 4
The packet communication method according to any one of 1 . 6. The user station sets a predetermined value after detecting a reception failure.
It claims 1 to packet communication method according to any one of 4 including means for performing a retransmission request after the lapse of time the probabilities. 7. The user station fails to receive a timer and
If an out occurs, the next reception failure at the user station
The packet communication system according to claim 6 , further comprising: means for changing the transmission probability of the retransmission request to a high one . 8. The user station, if reception fails and a timer times out, waits within the number of times reception failure occurs in the user station.
7. The packet communication system according to claim 6 , further comprising means for making a retransmission request with a probability that a muting will occur .