JPH06205040A - Congestion control system - Google Patents

Abstract

PURPOSE:To suppress the deterioration of throughput by performing reactive peak rate control when the disposal of a cell or the block of a packet occurs. CONSTITUTION:An original of call 80 sets VC in a band 0 at the time of setting a call. Afterwards, the band is reserved at the peak rate of a burst just before the burst is transmitted, the burst is transmitted, and the band is released after the transmission is ended. At that time, when a link to which the peak rate is not assigned is present, the reserved band is released, and an NACK is returned to the origin of transmission. The origin of transmission receives the NACK, and assigns the band again after a certain back-off time. At that time, the band is assigned at the smaller peak rate than the peak rate requested at first so that the probability of the block at the time of retransmission can be decreased, and the peak rate is decreased each time the number of times of transmission is increased, so that the probability of the block can be reduced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a congestion control system in an asynchronous transfer system.

[0002]

2. Description of the Related Art Conventionally, a congestion control method has been used for the purpose of detecting a congestion state of a network and preventing deterioration of the quality of the network. For example, in the 1992 Institute of Electronics, Information and Communication Engineers Exchange Study Group SSE92-21 "Consideration of Congestion Control Method in ATM Band Non-Allocation Method", the switch in the network detects the cell discard rate to detect the congestion state of the network. If the congestion is detected and the congestion is light according to the congestion state, the path is switched to another path without congestion, and if the congestion is heavy, the UPC of each exchange at the entrance of the network is regulated to flow into the network. Techniques for limiting traffic and recovering the cell loss rate in the network are described.

[0003]

In this conventional congestion control method, since the exchange detects the congestion state by detecting the cell discard rate, the exchange must have means for detecting the congestion state, Further, it must be provided with means for determining which exchange UPC is regulated and for controlling the exchange.

Further, in order to recover the cell discard rate in the network, the UPC of the exchange at the entrance of the network is regulated, so the result of the UPC is not fed back to the terminal, and the traffic from the terminal is dropped at the entrance of the network. It will be.

An object of the present invention is to provide a congestion control method that solves such a problem.

[0006]

According to the congestion control method of the present invention, a calling terminal and a called terminal are connected via a plurality of nodes, and a route is set between a calling node and a calling node at the time of call setting. Prior to the transmission of the burst, the bandwidth for transmitting the burst is reserved in each link on the route, the burst is transferred, and the reserved bandwidth is released after the burst is transmitted. In the reservation method, when the band reservation on the path fails, the calling terminal changes the requested band, a unit that repeats the band re-reservation until the band reservation is successful, a unit that counts the number of consecutive band reservation failures. And reducing the required bandwidth at the time of re-bandwidth allocation for the burst transmission according to the number of times of failure in bandwidth reservation.

Further, the congestion control method of the present invention connects the calling terminal and the called terminal through a plurality of nodes, sets a route between the calling and called nodes at the time of call setting, and sends a burst from the calling terminal. In the burst bandwidth reservation method in the asynchronous transfer network, which reserves the bandwidth for transmitting the burst in each link on the path, transfers the burst, and releases the reserved bandwidth after the burst transmission is completed. The terminal, when bandwidth reservation on the path fails, means for repeating bandwidth re-reservation until the bandwidth reservation succeeds, means for counting the number of consecutive successes of the bandwidth reservation, and counting the number of consecutive failures of the bandwidth reservation. And a means for changing the required bandwidth, the required bandwidth for burst transmission from the transmitting terminal is reduced according to the number of times of failure in bandwidth reservation, and the bandwidth is reduced. Characterized in that it greatly depending on about Succ.

In the congestion control method of the present invention, the source terminal and the destination terminal are connected via a plurality of nodes, a route is set between the source node and the destination node at the time of call setting, and a burst is transmitted from the source terminal. In the burst bandwidth reservation method in the asynchronous transfer network, which reserves the bandwidth for transmitting the burst in each link on the path, transfers the burst, and releases the reserved bandwidth after the burst transmission is completed. When the bandwidth reservation on the path fails, the terminal repeats bandwidth re-reservation until the bandwidth reservation succeeds, counts the number of consecutive successes of the bandwidth reservation, and counts the number of consecutive failures of the bandwidth reservation. And a means for changing the backoff time for reserving the bandwidth when the bandwidth reservation fails, and lengthening the backoff time according to the number of times of the bandwidth reservation failure. And wherein the door.

Further, according to the congestion control method of the present invention, in an asynchronous transfer network in which a source terminal and a destination terminal are connected via a plurality of nodes and a burst is transferred, the source terminal transmits when burst cell discard occurs. Means to determine failure,
A unit for counting the number of times of burst transmission failure, a unit for determining successful transmission when a burst can be transmitted without discarding cells, a unit for counting the number of times of successful burst transmission, and a peak rate defined by a transmission cell interval of the burst By changing the burst transmission failure frequency, the transmission terminal, by opening the cell transmission interval, to reduce the peak rate, by closing the cell transmission interval according to the burst success frequency. It is characterized by increasing the peak rate.

[0010]

1 shows an example of an ATM network (asynchronous transfer network) in which the present invention is implemented. A virtual circuit (V) for burst transfer from the source terminal 80 to the destination terminal 90.
The setting of C) is shown. 10, 20, 30, 40,
Reference numerals 60 and 70 are ATM nodes. Between each adjacent node 10
-20, 20-30, 30-40, 10-70, 60-
70, 40-60 have links 1, 2, 3, respectively.
4, 5, 6 are connected. Here, in this VC,
The paths of 10-20-30-40 and the links of 1, 2, 3 are set.

FIG. 2 shows an operation example of congestion control at the time of bandwidth reservation and re-reservation at the time of transmitting each burst according to the first embodiment of the present invention. Prior to the burst transmission, a reserved cell is sent from the node 10 to the node 40 to perform a bandwidth reservation request operation. The bandwidth requested here is the maximum bandwidth (peak speed) P thereof. If the remaining bandwidth of the path is insufficient and the reservation is blocked, a NACK will be returned to the sender. Along with this, the bandwidth of the relay link that has already been reserved is released to avoid deadlock. The calling side performs the re-reservation operation after the backoff time has elapsed. At this time, if N preset NACKs are received in order to reduce the probability of blocking at the time of re-reservation,
The terminal reduces the requested bandwidth to P / k. This behavior is
It is repeated until the bandwidth reservation is successful. In FIG. 2, N = 1
The case of is shown. That is, when one NACK is received, the peak rate at the time of re-reservation is changed from P to P / k. k is a preset value. If bandwidth reservation is successful, ACK is returned to the sender,
A burst is transmitted, and after the burst transmission ends, a cell indicating the end of burst transmission is transmitted, and the reserved band is released.

FIG. 3 shows an example of a state transition diagram for changing the peak rate according to the second embodiment. The peak rate is a binary value of P1 and P2. Here, N1 = 1, N2 = 5
Suppose

Prior to the burst transmission, reserved cells are transmitted from the node 10 to the node 40 in order to perform a bandwidth reservation request operation.
Send to. It is assumed that the requested bandwidth is the maximum bandwidth (peak speed) P1. If the remaining bandwidth of the path is insufficient and the reservation is blocked, a NACK will be returned to the sender. Along with this, the bandwidth of the relay link that has already been reserved is released to avoid deadlock. Since the NACK is received once, the originating terminal reduces the peak rate from P1 to P2. After that, all transmission bursts from the originating terminal are performed at the peak rate P2 regardless of the re-reservation burst. When the ACK is received five times in succession, the peak rate is returned from P2 to P1. Three
When NACK is received after continuously receiving ACK, ACK is re-counted from 1 and returned to P1 for the first time when 5 times are received in succession.

FIG. 3 shows the case where the peak rate is binary, while FIG. 4 shows the case where the peak rate is multivalued. In this case, N1 NACKs are continuously received, the peak rate is changed from P1 to P2, and then N1 NACKs are received again.
When the ACK is continuously received, the peak rate is changed from P2 to P3. Until the ACK is continuously received N2 times, the peak rate decrease is continued to the minimum value Pn of the peak rate.

FIG. 4 shows that, for each peak rate Pn, the number N1 of ACKs for making a transition to the peak rate Pn-1 that is one higher and the number N2 of NACKs for making a transition to the peak rate Pn + 1 that is one less are all N1. The case of equality is shown. A method of changing these values for each peak rate is also conceivable. For example, change from P1 to P2 is N2 = 1
0, and the change from P2 to P3 has a different value for each peak rate such that N2 = 5.

FIG. 5 shows an operation example of congestion control at the time of bandwidth reservation and re-reservation at the time of sending each burst according to the third embodiment. As in the first invention, it is assumed that the remaining bandwidth of the path is insufficient, the reservation is blocked, and NACK is returned to the transmission side. The originating side performs the re-reservation operation after the backoff time T has elapsed. If the reservation cannot be made in the first re-reservation and N preset NACKs are received, the backoff time is lengthened to T ^* k. This operation is repeated until the bandwidth reservation is successful.

FIG. 5 shows the case where N = 1. That is, after the first re-reservation fails, one NACK
Is received, the backoff time is lengthened to T ^* k. k is a preset value.

When the bandwidth reservation is successful, ACK is returned to the transmitting side, the burst is transmitted, and after the burst transmission is completed, a cell indicating the end of burst transmission is transmitted and the reserved bandwidth is released.

FIG. 6 shows an operation example of congestion control according to the fourth embodiment. The present invention is a method for changing the peak rate as in the second embodiment in a network in which band allocation is not performed for each burst. In the present invention, if there is cell loss in the middle and burst transmission fails, the NA is
When CK is returned, there is no cell loss, and burst transmission is successful, ACK is returned. N1 NAC
When K is continuously received, the peak transmission rate is reduced by decreasing the cell transmission interval, and when N2 ACKs are continuously received, the peak transmission rate is increased by shortening the cell transmission interval.

FIG. 6 shows the case where N1 = 1 and N2 = 2. When one NACK is received, the cell transmission interval from the terminal is multiplied by k to reduce the peak rate to P / k. After that, when two ACKs are received, the cell transmission interval is reduced to 1 /. Close to k and return the peak rate to P.

Also in the present invention, as in the second embodiment,
It may be considered to be multi-valued or to change the values of N1 and N2 for each peak rate.

[0022]

As described above, according to the present invention, the terminal detects the congestion state of the network by using the means for detecting the bandwidth reserved cell and the packet discard, and suppresses the peak rate by itself. It is possible to realize congestion control between terminals without depending on.

[Brief description of drawings]

FIG. 1 is a network diagram targeted by the present invention.

FIG. 2 is a diagram for explaining a congestion control operation at the time of bandwidth reservation and re-reservation in the first embodiment.

FIG. 3 is a state transition diagram showing transition of a peak rate in the second embodiment.

FIG. 4 is a state transition diagram showing transition of a peak rate in the second embodiment.

FIG. 5 is a diagram explaining a congestion control operation at the time of bandwidth reservation and re-reservation in the third embodiment.

FIG. 6 is a diagram illustrating a congestion control operation according to a fourth embodiment.

[Explanation of symbols]

 1,2,3,4,5,6 link 10,20,30,40,60,70 node 80,90 terminal

Claims (8)

[Claims] 1. A transmitting terminal and a receiving terminal are connected via a plurality of nodes, a route is set between the originating and terminating nodes at the time of call setting, and the burst is transmitted prior to the transmission of the burst from the transmitting terminal. In the burst bandwidth reservation method in the asynchronous transfer network, in which the bandwidth for the reservation is reserved for each link on the path, the burst is transferred, and the reserved bandwidth is released after the transmission of the burst is completed. If the bandwidth reservation fails, it has means for repeating the bandwidth re-reservation until the bandwidth reservation succeeds, means for counting the number of consecutive failures of the bandwidth reservation, and means for changing the requested bandwidth, the number of bandwidth reservation failures According to the above, the congestion control method is characterized in that the required bandwidth at the time of re-bandwidth allocation for the burst transmission is reduced. 2. A transmitting terminal and a receiving terminal are connected via a plurality of nodes, a route is set between the originating and terminating nodes at the time of call setting, and the burst is transmitted prior to the transmission of the burst from the transmitting terminal. In the burst bandwidth reservation method in the asynchronous transfer network, in which the bandwidth for the reservation is reserved for each link on the path, the burst is transferred, and the reserved bandwidth is released after the transmission of the burst is completed. When the bandwidth reservation fails, a means for repeating the bandwidth re-reservation until the bandwidth reservation succeeds, a means for counting the number of consecutive successes of the bandwidth reservation, a means for counting the number of consecutive failures of the bandwidth reservation, and a requested bandwidth. And a means for changing the bandwidth required for burst transmission from the transmitting terminal to decrease in accordance with the number of times of failure in bandwidth reservation and increase in accordance with the number of times of successful bandwidth reservation. Congestion Control according to claim Rukoto. 3. A transmitting terminal and a receiving terminal are connected via a plurality of nodes, a route is set between the originating and terminating nodes at the time of call setting, and the burst is transmitted prior to the transmission of the burst from the transmitting terminal. In the burst bandwidth reservation method in the asynchronous transfer network, in which the bandwidth for the reservation is reserved for each link on the path, the burst is transferred, and the reserved bandwidth is released after the transmission of the burst is completed. When the bandwidth reservation fails, the bandwidth re-reservation is repeated until the bandwidth reservation succeeds, the means for counting the number of consecutive successes of the bandwidth reservation, the means for counting the number of consecutive failures of the bandwidth reservation, and the bandwidth when the bandwidth reservation fails. And a means for changing the back-off time for re-reservation, wherein the back-off time is lengthened according to the number of bandwidth reservation failures. . 4. An asynchronous transfer network for connecting a source terminal and a destination terminal via a plurality of nodes and transferring a burst, wherein the source terminal determines that transmission is unsuccessful when cell loss of the burst occurs. A unit for counting the number of times of burst transmission failure, a unit for determining successful transmission when a burst can be transmitted without discarding cells, a unit for counting the number of times of successful burst transmission, and a peak rate defined by a transmission cell interval of the burst And a means for changing, the originating terminal, according to the burst transmission failure frequency,
A congestion control method, wherein a peak rate is lowered by increasing a cell transmission interval, and a peak rate is increased by shortening a cell transmission interval according to the number of successful bursts. 5. A transmission terminal and a reception terminal are connected via a plurality of nodes, a route is set between the transmission and reception nodes at the time of call setting, and the burst is transmitted before the transmission of the burst from the transmission terminal. In the burst bandwidth reservation method in the asynchronous transfer network, in which the bandwidth for the reservation is reserved for each link on the path, the burst is transferred, and the reserved bandwidth is released after the transmission of the burst is completed. If the bandwidth reservation fails, the bandwidth re-reservation is repeated until the bandwidth reservation is successful, the number of consecutive failures of the bandwidth reservation is counted, and the number of consecutive failures of the bandwidth reservation is determined according to the number of failure of the bandwidth reservation. A congestion control method characterized by reducing the required bandwidth. 6. A source terminal and a destination terminal are connected via a plurality of nodes, a route is set between the source node and the destination node at the time of call setting, and the burst is transmitted prior to the burst transmission from the source terminal. In the burst bandwidth reservation method in the asynchronous transfer network, in which the bandwidth for the reservation is reserved for each link on the path, the burst is transferred, and the reserved bandwidth is released after the transmission of the burst is completed. If the bandwidth reservation fails, the bandwidth re-reservation is repeated until the bandwidth reservation succeeds, the number of consecutive successes of the bandwidth reservation is counted, the number of consecutive failures of the bandwidth reservation is counted, and the burst transmission from the transmitting terminal is performed. A congestion control method, wherein a requested bandwidth is reduced according to the number of times of failure in bandwidth reservation and increased according to the number of times of successful bandwidth reservation. 7. A source terminal and a destination terminal are connected via a plurality of nodes, a route is set between the source node and the destination node at the time of call setting, and the burst is transmitted prior to the transmission of the burst from the source terminal. In the burst bandwidth reservation method in the asynchronous transfer network, in which the bandwidth for the reservation is reserved for each link on the path, the burst is transferred, and the reserved bandwidth is released after the transmission of the burst is completed. When the bandwidth reservation fails, the bandwidth re-reservation is repeated until the bandwidth reservation succeeds, the number of consecutive successes of the bandwidth reservation is counted, the number of consecutive failures of the bandwidth reservation is counted, and depending on the number of times of the bandwidth reservation failure, A congestion control method characterized by extending the backoff time for re-reserving the bandwidth when the bandwidth reservation fails. 8. In an asynchronous transfer network for connecting a caller terminal and a callee terminal via a plurality of nodes and transferring a burst, the caller terminal determines that the burst cell is discarded and fails to transmit, and the burst The number of transmission failures is counted, it is determined that the transmission is successful if the burst can be transmitted without discarding cells, the number of successful burst transmissions is counted, and the cell transmission interval is set according to the number of failed burst transmissions. The congestion control method is characterized in that the peak rate defined by is reduced and the peak rate is increased by reducing the cell transmission interval according to the number of successful bursts.