JP3634489B2 - Congestion control system and congestion control method in cell switching system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a congestion control technique in cell switching such as an ATM switching system.
[0002]
[Prior art and problems to be solved by the invention]
In B-ISDN (broadband service integrated digital network), it is possible to provide services related to information of various speeds and forms in one network. Currently, an ATM (asynchronous transfer mode) exchange method is realized as B-ISDN.
[0003]
In the ATM switching method, congestion control is generally performed in order to effectively use resources in the network. As one method of such congestion control, a congestion control method in an ABR (variable bit rate) service is known. In this method, the congestion state of a cell using the ABR service is monitored by a buffer in the network, and when a congestion is detected, a specific bit (EFCI bit) in the cell is turned on. When the destination subscriber terminal receives the cell in which the EFCI bit is set, the destination subscriber terminal notifies the calling subscriber terminal of the congestion state using a cell called a resource management cell. When the calling subscriber terminal receives the congestion notification, the calling subscriber terminal decreases the band used for transmission data according to a predetermined algorithm.
[0004]
Here, congestion control in the ABR service is defined as control between subscriber terminals. For example, when the above-described congestion occurs in a relay exchange, the occurrence is notified from the destination subscriber terminal to the calling subscriber terminal. It takes a considerable amount of time, and it may be too late for the calling subscriber terminal to perform congestion control after receiving the congestion notification. In such a case, the occurrence of congestion at one location in the network is likely to cause congestion at other locations one after another. Therefore, autonomous congestion control is desired in each exchange in the network.
[0005]
The occurrence of congestion in the exchange is related to the performance of the buffers in each part in the exchange.
Now, in a general ATM switching system, information received from the line 301 via the line individual unit 302 is multiplexed by the multiplexing unit in the multiplexing / demultiplexing unit 303 in order to reduce the size and economy of the system. After that, the signal is input to the switch unit 304, where it is switched in units of cells, and then separated for each target line 301 by the demultiplexing unit in the multiplexing / demultiplexing unit 303 and output to the line 301 via the line individual unit 302. Has a configuration. In an ATM switching system having such a configuration, in order to integrate and process services related to information of various speeds and forms, it is desirable to increase the processing speed of the system. It is desirable to increase the data transfer speed of the highway that is input to the switch unit 304 and the highway that is output from the switch unit 304 to the separation unit as much as possible. In addition, such an increase in speed also brings about an effect that the switch unit 304 is reduced in size.
[0006]
However, as the highway speed increases, sufficient capacity is required for each buffer in the multiplexing / demultiplexing unit 303 and the switch unit 304, and the cost for the memory for configuring them increases. Problems arise. In particular, in order to efficiently process highly bursty information such as communication data between computers, it is necessary to secure a sufficient capacity of these buffers, which increases the system cost.
[0007]
Therefore, conventionally, a buffer is provided at the input unit from each line individual unit 302 to the multiplexing / demultiplexing unit 303, and the multiplexing / demultiplexing unit 303 is absorbed by absorbing the difference in the frequency of occurrence of cells by the buffer corresponding to each line. In addition, a system for reducing the capacity required for each buffer in the switch unit 304 and reducing the size and economy of the system is realized.
[0008]
However, in order to efficiently process highly bursty information such as communication data between computers, it is better that the buffer capacity of the line input unit is as large as possible. There is a problem in that delay of information such as voice that has a strong demand for immediacy increases.
[0009]
To deal with such problems, conventionally, the capacity of the buffer in the line input unit is set to a capacity that can tolerate delays in information that requires immediacy, and limits the use band of information with strong burstiness. As a result, information with strong burstiness and information with strong demand for immediacy were mixedly used.
[0010]
However, as a matter of course, such a method has its limitations.
In addition to the above-described mixed method, the state of congestion is monitored in the buffer in the demultiplexing unit in the multiplexing / demultiplexing unit 303. When congestion due to the input of strong burst information is detected, all line inputs are detected. Until the congestion state in the buffer in the demultiplexing unit in the multiplexing / demultiplexing unit 303 is resolved, the notification from the buffers in all the line input units is performed. A method has been proposed in which cell output is stopped. In this case, the input of cells to the buffers of all the line input units is eventually restricted, and cell discard occurs in all the line input units.
[0011]
In this case, it is ideal to stop only the cell output from the buffer of the line input unit that is actually causing congestion. However, in the buffer control method described above, the communication path set for the switch unit 304 cannot be recognized by the buffer in the demultiplexing unit in the multiplexing / demultiplexing unit 303. The cell output must be stopped. As a result, there is a problem in that all communication information including information with a strong immediacy requirement is affected by congestion.
[0012]
Further, in the above-described buffer control method, only the on / off control of whether to stop the output of cells from the buffers of all the line input units is performed, so that the use efficiency of the switch unit 304 is necessarily improved. It has the problem that it cannot be done.
[0013]
The object of the present invention is to realize appropriate congestion control for highly bursty information while maintaining the miniaturization and economy of the system, and to efficiently use both highly bursty information and immediacy required information. It is to be able to process well.
[0014]
[Means for Solving the Problems]
The first aspect of the present invention is based on a cell switching system having a switch device for switching a cell such as an ATM cell.
[0015]
First, the cell has an immediacy request information adding device (IVCC 103) for adding immediacy request information (SI bit) indicating whether or not the cell is a service cell requesting immediacy.
[0016]
Next, it has a buffer device (I-BUF 105) that temporarily holds a cell of a service that does not require immediacy, reads the cell in a predetermined read band, and outputs it to the switch device.
[0017]
If the immediacy request information added to the cell indicates that the cell is a service cell that does not require immediacy, the cell is distributed to the route toward the buffer device and added to the cell. If the immediacy request information being processed indicates that the cell is a cell of a service that requires immediacy, the route for the cell of the service that requests immediacy toward the switch device. A distribution device (distribution unit 104) that distributes to (a route including the R-BUF 106) is included.
[0018]
With the configuration of the first aspect of the present invention, it is possible to efficiently process highly bursty information such as communication data between computers without increasing the buffer size in the switch device, It is possible to prevent an increase in delay of information having a strong demand for immediacy.
[0019]
Next, according to the second aspect of the present invention, a cell on the uplink is temporarily stored, the buffer device (I-BUF 105) for reading the cell in a predetermined read band, and the cell from the buffer device are switched. Assume a cell switching system having a switch device and a separation device (DMUX 112) that outputs a cell from the switch device to each downlink directed to each subscriber terminal.
[0020]
First, the separation device includes a congestion state monitoring device (DMUX CTL 113) that detects a congestion state for each downlink directed to each subscriber terminal.
Next, when the congestion state monitoring device detects the congestion state, the congestion information is set for the congestion information corresponding to the congestion state in the cell transferred on the uplink paired with the downlink where the congestion state is detected. It has setting devices (DMUX CTL 113 and INS 108).
[0021]
In addition, it has a congestion information setting cell detection device (O-CELL EXT110) that detects a cell in which congestion information is set on each downlink.
Then, in the buffer device provided on the uplink corresponding to the downlink corresponding to the congestion information setting cell detection device according to the detection state of the cell in which the congestion information is set in the congestion information setting cell detection device And a buffer control device (I-BUF CTL 109) for controlling the cell read band therefrom.
[0022]
In the second aspect of the present invention described above, the congestion state monitored by the congestion state monitoring device is composed of a plurality of levels, and the congestion information setting device sets the congestion information according to the level of the congestion state. Can be configured to control the cell read band in the buffer device according to the level of congestion state indicated by the congestion information set in the cell detected by the congestion information setting cell detection device.
[0023]
Further in this case, the congestion state monitoring device detects each of the congestion states composed of a plurality of levels by monitoring changes in the amount of cells remaining in each buffer of each downlink directed to each subscriber terminal in the separation device. Can be configured to.
[0024]
Further, the buffer control device is configured to control a decrease amount of the cell read bandwidth in the buffer device in accordance with a congestion state level indicated by the congestion information set in the cell detected by the congestion information setting cell detection device. can do.
[0025]
Alternatively, the buffer control device may stop reading the cell in the buffer device when the congestion state level indicated by the congestion information set in the cell detected by the congestion information setting cell detection device indicates a predetermined level. Can be configured.
[0026]
Furthermore, the buffer control device can be configured to increase the cell read bandwidth in the buffer device at a predetermined rate when the congestion information setting cell detection device does not detect the cell for which the congestion information is set. .
[0027]
In the second aspect of the present invention described above, the congestion information can be configured to be set in a header portion used only in a cell switching system added to a cell.
[0028]
Furthermore, in the second aspect of the present invention described above, the buffer control device sets the cell read bandwidth in the buffer device based on the sum of the average values of the used bandwidths assigned to the paths using the buffer device. As a result, it can be configured to control so as to guarantee the sum of the average values as the minimum bandwidth.
[0029]
With the above-described configuration of the second aspect of the present invention and the modified configuration thereof, it is possible to transfer information with strong burst characteristics such as communication data between computers with maximum efficiency.
[0030]
Also, the congestion control according to the second aspect of the present invention is used in combination with other congestion control outside the exchange by setting the congestion information in the header part used only in the cell switching system added to the cell. Therefore, more precise congestion control can be realized.
[0031]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail.
In the embodiment of the present invention, information (SI bit) indicating whether or not the cell is a service cell requiring immediacy is added to the input cell. Based on this information, the input cell of the bursty service that does not require immediacy is input to the switch unit via the first buffer (I-BUF) having a large capacity, and the service cell that requires immediacy is input. The input cell is input to the switch unit via the second buffer (R-BUF) having the necessary minimum capacity (about several cells). As a result, it is possible to efficiently process highly bursty information such as communication data between computers without increasing the buffer size in the switch unit, and to increase delay of information that is demanding immediacy such as telephone voice. Can be prevented.
[0032]
Further, in the embodiment of the present invention, the state of congestion is monitored in a buffer in the separation unit that outputs a cell to each downlink directed from the switch unit to each subscriber terminal. When congestion due to the input of information with strong burstiness is detected here, it is input toward the switch unit on the uplink (line from the subscriber terminal to the switch unit) paired with the downlink where the congestion was detected. A congestion notification (an EFCI level display) corresponding to the degree of congestion is set in the incoming cell. The cells on this uplink are switched by the switch unit, then transferred to the downlink returning to the subscriber terminal that is transmitting the cell toward the downlink where congestion is detected, and the downlink is terminated. It is detected in the terminating device (individual corresponding unit). The individual handling unit determines whether the first buffer (immediateness) provided on the uplink paired with the downlink according to a predetermined algorithm depending on whether the cell for which the congestion notification is set is detected or not. In a cell buffer that does not require a cell), the read bandwidth (speed) of the cell from there is controlled. As a result, the amount of cells transferred to the downlink where congestion is detected is controlled, and the cells are transferred with maximum efficiency. In this case, the amount of cell transfer is not restricted on the uplink other than the uplink connected to the subscriber terminal that is transmitting the cell toward the downlink where congestion is detected. . In addition, since information with a strong demand for immediacy is input to the switch unit via the second buffer, there is a feature that the information is not affected by the restriction in the first buffer.
[0033]
FIG. 1 is a system configuration diagram of an embodiment of the present invention for realizing the above-described characteristic functions. In FIG. 1, the switch interface unit 102 corresponds to the multiplexing / demultiplexing unit 303 in FIG. The individual correspondence unit 101 is provided for each line correspondence unit 302 (each line 301) in the interface unit of the line correspondence unit 302 and the multiplexing / demultiplexing unit 303 in FIG. FIG. 2 is a data configuration diagram of a cell (ATM cell) flowing in the switch unit in the embodiment of the present invention.
[0034]
In FIG. 1, the IVCC 103 in the individual correspondence unit 101 is configured to add VPI (virtual path identifier) and VCI (virtual channel identifier) (both shown in the figure) added to the ATM header portion of the cell input from the line individual unit. 2), the VPI / VCI in the ATM header of the input cell is replaced with the VPI / VCI corresponding to the output route by referring to an internal table (not shown). An SI bit value indicating whether or not the input cell is a service cell that requires immediacy, and the input cell for autonomously switching in the switch unit subsequent to the switch interface unit 102 After the switch tag and the input cell are output from the switch unit, DMUX ( A switching header (see FIG. 2) including a DMUX tag to be independently separated by the separation unit 112 and dummy data for a field of one octet including a field for displaying an EFCI level is added. The EFCI level display is inserted by INS 108 described later.
[0035]
Here, the SI bit is information particularly relevant to the present invention, and its value is set to “1” if the input cell to which it is attached is a service cell that requires immediacy. If it is a cell of any other service, it is set to “0”. Then, the allocating unit 104 determines the value of the SI bit of the input cell, so that if the input cell is a service cell that does not require immediacy and the value of the SI bit is “0”. For example, if the input cell is written to the I-BUF 105, which is the first buffer having a large capacity, and the input cell is a service cell that requires immediacy and the value of the S-I bit is “1”, The input cell is written into the I-BUF 105, which is a first buffer having a large capacity, and is written into the R-BUF 106, which is a second buffer having a necessary minimum capacity (about several cells). The outputs of the I-BUF 105 and the R-BUF 106 are multiplexed by a MUX (multiplexing unit) 107 and then passed through an INS 108 (described later) and a MUX 111 in the switch interface unit 102 (see FIG. 3). Corresponding to the switch unit 304).
[0036]
In this way, only information with strong burstiness that does not require immediacy is input to the switch unit via the I-BUF 105 that is the first buffer having a large capacity, and an input cell for a service that requires immediacy is necessary. Since it is input to the switch unit via the R-BUF 106, which is the second buffer having the minimum capacity, information with strong burst characteristics such as communication data between computers without increasing the buffer size in the switch unit. Can be efficiently processed, and an increase in delay of information such as telephone voice that is demanding immediacy can be prevented.
[0037]
Next, a DMUX CTL (separation unit control unit) 113 in the switch interface unit 102 is a buffer (not shown) in the DMUX (separation unit) 112 that outputs a cell to each downlink directed from the switch unit to each subscriber terminal. The congestion state is monitored. More specifically, the DMUX CTL 113 compares the number of staying cells in each buffer corresponding to each downlink with a plurality of predetermined threshold values. When the DMUX CTL 113 detects congestion in any of the buffers, the DMUX CTL 113 in the individual corresponding unit 101 on the uplink corresponding to the buffer in which the congestion is detected (the line from the subscriber terminal to the switch unit) By controlling the INS (insertion unit) 108, an EFCI level display, which is a congestion notification having a value corresponding to the degree of congestion, is displayed in the switching header of the cell input from the MUX 107 to the switch unit (see FIG. 2). ) Is set.
[0038]
The cell on the above-described uplink output from the INS 108 is input to the switch unit via the MUX 111 in the switch interface unit 102, and after being switched there, the cell is directed toward the downlink in which congestion is detected. It is transferred to the downlink which returns to the transmitting subscriber terminal.
[0039]
On the other hand, when the O-CELL EXT (output cell detection unit) 110 in the individual correspondence unit 101 terminating the downlink returning to the subscriber terminal detects a cell in which the EFCI level display is set. The EFCI level display value is notified to the I-BUF CTL (input buffer control unit) 109. The I-BUF CTL 109 is provided with an I-BUF 105 provided on the uplink of a pair with the I-BUF CTL 109 according to a predetermined algorithm when the value of the EFCI level display is notified from the O-CELL EXT 110 and when the value is not notified. Controls the cell read bandwidth (speed). As a result, the amount of cells transferred to the downlink where congestion is detected is controlled, and the cells are transferred with maximum efficiency.
[0040]
Subsequently, a specific example of the above-described congestion control will be described below.
First, when a subscriber requests communication, the subscriber declares information on service attributes and used bandwidth in accordance with international recommendations. When the declared service attribute indicates an attribute of a service that requires immediacy, the call processing processor of the exchange system assigns the subscriber to a resource in the exchange using the declared use band as a peak band. On the other hand, if the declared service attribute indicates an attribute of a service that does not require immediacy, the subscriber is assumed to be the average bandwidth in the declared usage band and the usage band follows a Poisson distribution. Assign to resources.
[0041]
Next, the DMUX CTL 113 in the switch interface unit 102 detects the degree of change in the number of staying cells in each buffer by comparing the number of staying cells in each buffer corresponding to each downlink with a plurality of predetermined threshold values. Thus, the congestion state is detected. This congestion state consists of, for example, two levels. For example, in the first level, the increase in the number of staying cells in the buffer while inputting 100 cells is 50 cells or less, and in the second level, 100 cells are input. The increase in the number of staying cells in the buffer is 51 cells or more. When the DMUX CTL 113 detects each of the first level or second level congestion states, the DMUX CTL 113 controls the INS 108 in the individual correspondence unit 101 on the uplink corresponding to the downlink corresponding to the buffer in which the congestion is detected. Thus, for example, the EFCI level display of the value “1” or “2” is set in the switching header of the cell input from the MUX 107 toward the switch unit.
[0042]
The I-BUF CTL 109 in the individual corresponding unit 101 corresponds to the sum of the average values of the used bandwidths assigned to each path using the line terminated by the individual corresponding unit 101 by the call processor in the switching system. The reading of the cell from the I-BUF 105 in the individual corresponding unit 101 is started at the read band (speed) to be performed. When the I-BUF CTL 109 is not notified of the value of the EFCI level display from the O-CELL EXT 110 in the individual corresponding unit 101, the reading band (speed) in the I-BUF 105 is provided every predetermined period. Is increased by 20%.
[0043]
On the other hand, when the I-BUF CTL 109 is notified of the value “1” of the EFCI level display indicating the first level congestion state from the O-CELL EXT 110 in the individual corresponding unit 101, the I-BUF 105 The reading band (speed) at is reduced to ½ of the current value, with the value corresponding to the total sum of the aforementioned average values being the lowest value.
[0044]
When the I-BUF CTL 109 is notified of the value “2” of the EFCI level display indicating the second level congestion state from the O-CELL EXT 110 in the individual corresponding unit 101, the I-BUF 105 Reading of cells from is stopped.
[0045]
As described above, it is possible to transfer highly bursty information such as communication data between computers with maximum efficiency while preventing an increase in delay of information that is demanding immediacy such as telephone voice. It becomes.
[0046]
In the embodiment described above, as shown in FIG. 2, the EFCI level display is set in a switching header used only inside the exchange. As a result, it can be distinguished from the EFCI information used for congestion control between subscriber terminals in the ABR service, and the congestion control using both is performed, so that the entire network including the subscriber terminals is more precise. Congestion control can be realized.
[0047]
【The invention's effect】
According to the first aspect of the present invention, it is possible to efficiently process highly bursty information such as communication data between computers without increasing the buffer size in the switch device, and to improve immediacy such as telephone voice. It is possible to prevent an increase in delay of highly demanded information.
[0048]
According to the second aspect of the present invention and its modification, it is possible to transfer information having strong burst characteristics such as communication data between computers with maximum efficiency.
In addition, the congestion control according to the second aspect of the present invention is used in combination with other congestion control outside the exchange by setting the congestion information in the header part used only in the cell switching system added to the cell. Therefore, more precise congestion control can be realized.
[Brief description of the drawings]
FIG. 1 is a system configuration diagram of an embodiment of the present invention.
FIG. 2 is a data configuration diagram of an ATM cell according to the embodiment of the present invention.
FIG. 3 is a block diagram of a general ATM switching system.
[Explanation of symbols]
101 Individual Corresponding Unit 102 Switch Interface Unit 103 IVCC
104 Distribution unit 105 I-BUF
106 R-BUF
107, 111 MUX
108 INS
109 I-BUF CTL
110 O-CELL EXT
112 DMUX
113 DMUX CTL

Claims (12)

In a cell switching system having a switching device for switching cells,
An immediacy request information adding device for adding immediacy request information indicating whether or not the cell is a service cell requesting immediacy;
A high-capacity first buffer device that temporarily holds a cell of a service that does not require immediacy, reads the cell in a predetermined read band, and outputs the cell to the switch device;
A second buffer device having a necessary minimum capacity for a cell of service requiring immediacy and outputting the cell to the switch device;
When the immediacy request information added to the cell indicates that the cell is a service cell that does not require immediacy, the cell is distributed to a route toward the first buffer device, When the immediacy request information added to the cell indicates that the cell is a service cell that requires immediacy, the distribution of the cell to the route toward the second buffer device is performed. A dispensing device;
A congestion control system in a cell switching system, comprising: A buffer device that temporarily holds a cell on the uplink and reads the cell in a predetermined read bandwidth;
A switching device for switching cells from the buffer device;
In a cell switching system having a separation device that outputs a cell from the switch device to each downlink directed to each subscriber terminal,
In the separation device,
A congestion state monitoring device for detecting a congestion state for each downlink directed to each subscriber terminal;
When the congestion state monitoring device detects a congestion state, a congestion information setting device that sets congestion information corresponding to the congestion state in a cell transferred on an uplink paired with the downlink where the congestion state is detected When,
A congestion information setting cell detection device for detecting a cell in which the congestion information is set on each downlink;
In the buffer device provided on the uplink corresponding to the downlink corresponding to the congestion information setting cell detection device according to the detection state of the cell in which the congestion information is set in the congestion information setting cell detection device , possess a buffer controller for controlling the reading band of cells therefrom,
The congestion status monitored by the congestion status monitoring device consists of a plurality of levels.
The congestion information setting device sets congestion information according to the level of the congestion state,
The buffer control device controls the read bandwidth of the cell in the buffer device according to the level of congestion state indicated by the congestion information set in the cell detected by the congestion information setting cell detection device,
A congestion control system in a cell switching system. The congestion state monitoring device monitors each change in the amount of retention of the cells in each buffer of each downlink directed to each subscriber terminal in the separation device, thereby detecting each of the congestion states composed of the plurality of levels. The congestion control system in the cell switching system according to claim 2 , wherein the congestion control system is detected. The buffer control device controls the amount of decrease in the read bandwidth of the cell in the buffer device according to the level of congestion state indicated by the congestion information set in the cell detected by the congestion information setting cell detection device, congestion control system in cell switching system according to any one of claims 2 or 3, characterized in that. The buffer control device stops reading the cell in the buffer device when a congestion state level indicated by the congestion information set in the cell detected by the congestion information setting cell detection device indicates a predetermined level. The congestion control system in the cell switching system according to any one of claims 2 to 4 , characterized in that: The buffer control device increases the read bandwidth of the cell in the buffer device at a predetermined rate when the congestion information setting cell detection device does not detect the cell in which the congestion information is set. The congestion control system in the cell switching system according to any one of claims 2 to 5 . It said congestion information, the cell switching system according to any one of claims 2 to 6 wherein is set in the header portion to be used only within the cell switching system to be added to the cell, it is characterized by Congestion control system. The buffer control device uses the sum of the average values of the read bandwidths of the cells in the buffer device as the lowest bandwidth based on the sum of the average values of the used bandwidths assigned to each path using the buffer device. The congestion control system in the cell switching system according to any one of claims 2 to 7 , characterized in that control is performed so as to guarantee as follows. A congestion control method in a cell switching system in which a cell is switched by a switch device,
A congestion state detection step for detecting a congestion state for each downlink directed to each subscriber terminal;
A congestion state setting step for setting congestion information according to the congestion state in a cell transferred on an uplink paired with the downlink in which the congestion state is detected when the congestion state is detected;
A congestion information setting cell detection step for detecting a cell in which the congestion information is set on each downlink;
In accordance with the congestion information set in the cell detected in the congestion information setting cell detection step on the downlink, the inflow amount of the cell to the switch device is controlled in the uplink paired with the downlink A cell inflow control step,
Have
The congestion state detected in the congestion state detection step consists of a plurality of levels.
The congestion state setting step sets congestion information according to the level of the congestion state,
The cell inflow amount control step controls the inflow amount of the cell to the switch device according to a congestion state level indicated by the congestion information set in the cell detected in the congestion information setting cell detection step. ,
A congestion control method in a cell switching system. A buffer device that temporarily holds a cell on the uplink and reads the cell in a predetermined read bandwidth;
A switching device for switching cells from the buffer device;
A separation device for outputting a cell from the switch device to each downlink directed to each subscriber terminal;
In a cell switching system having
In the separation device,
A congestion state monitoring device for detecting a congestion state for each downlink directed to each subscriber terminal;
When the congestion state monitoring device detects a congestion state, a congestion information setting device that sets congestion information corresponding to the congestion state in a cell transferred on the uplink paired with the downlink where the congestion state is detected When,
A congestion information setting cell detection device for detecting a cell in which the congestion information is set on each downlink;
In the buffer device provided on the uplink corresponding to the downlink corresponding to the congestion information setting cell detection device according to the detection state of the cell in which the congestion information is set in the congestion information setting cell detection device A buffer controller for controlling the read bandwidth of the cell therefrom,
The buffer control device, when the congestion information setting cell detection device does not detect the cell for which the congestion information is set, increases the read bandwidth of the cell in the buffer device at a predetermined rate,
A congestion control system in a cell switching system. The cell exchange system according to claim 10, wherein the congestion information is set in a header part used only in the cell exchange system added to the cell. Congestion control system in the system. The buffer control device sets the sum of the average values to the lowest bandwidth based on the sum of the average values of the used bandwidths assigned to the paths using the buffer device as the cell read bandwidth in the buffer device. The congestion control system in the cell switching system according to any one of claims 10 and 11, characterized in that control is performed so as to guarantee.

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