JPH09275410A - Transmission amount controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid a state of network-down in advance by controlling a data transmission interval according to a data transmission load of a network between host terminals. SOLUTION: Plural host computers and terminal equipments are connected by a common transmission medium and each of the host computers and terminal equipments is provided with a transmission amount controller 211 that detect a load of a network to vary a transmission interval of data. A load measurement discrimination module 2111 and a transmission amount control module 2112 provided to the transmission amount controller 211 refers to a transmission time storage table 41, a result table 42, a reply time reference table 43 and a transmission interval reference table 44 to discriminate the amount of transmission load based on a data reply time thereby revising the data transmission interval.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmission amount control device in a network system in which a plurality of host computers and terminal devices are connected to the same communication path, and avoids network system down due to an increase in network load. The present invention relates to a control device of a data transmission amount suitable for.

[0002]

2. Description of the Related Art As a method for monitoring and controlling a network load state in a network in which a plurality of host computers and terminals are connected to the same communication path, there is a conventional method for monitoring the network load according to Japanese Patent Laid-Open No. 5-316120. Monitor by detecting the amount of data that flows periodically,
A method is known in which the transmission of specific data is suppressed when the load increases or the transmission of data is suppressed according to the priority of data. That is, these conventional techniques prevent transmission of predetermined data or low-priority data when the network load increases, suppress the increase of the network load, and avoid the network system down.

[0003]

The network load state monitoring and control method according to the prior art as described above is a method of detecting the amount of periodically flowing data in order to monitor the network load. However, in the case of this method, each device connected to the network needs to constantly monitor the amount of data communication, which slightly reduces the capacity of each device, and a complicated mechanism for realizing this method. It needs to be made. In the prior art, when the data flowing on the network cannot be given priority (for example, online connection between the host computer and the terminal).
, It becomes impossible to suppress the data transmission.

The present invention has been made to solve the above-mentioned problems of the prior art, and an object of the present invention is to obtain a transmission amount control apparatus that suppresses an increase in network load and avoids a network system down. To do. That is, an object of the present invention is to obtain a transmission amount control device that determines the data transmission load on a communication path based on the response time of data, controls the data transmission interval according to the load state, and suppresses the load on the network. Another object of the present invention is to obtain a transmission amount control device capable of flexibly changing a reference value for determining a data transmission load on a communication path according to a change in the status of a network system by a learning function. Another object of the present invention is to obtain a transmission amount control device capable of changing the reference value for determining the data transmission load on the communication path and the reference value of the data transmission interval for the data transmission load for each individual device.

[0005]

A transmission amount control apparatus according to the present invention is a network system in which a computer and a terminal device are connected to the same communication path, and data is transmitted between the computer and the terminal device. The terminal device controls the transmission interval of data to be communicated according to the data transmission load on the communication path.

The transmission amount control device according to the present invention is characterized in that the data transmission load on the communication path is judged by a response time which is a time difference between data transmission and its response.

The transmission amount control device according to the present invention is characterized by comprising a response time reference value table in which a load coefficient is determined by the response time in order to judge the data transmission load on the communication path.

The transmission amount control apparatus according to the present invention is characterized by having a learning function for changing the value of the response time set in the response time reference value table based on the load coefficient.

The transmission amount control device according to the present invention is characterized in that the value of the response time set in the response time reference value table can be changed at any time.

The transmission amount control device according to the present invention is characterized by including a transmission interval reference value table which defines data transmission intervals corresponding to the above load coefficients.

The transmission amount control device according to the present invention is characterized by having a learning function for changing the value of the data transmission interval set in the transmission interval reference value table based on the response time.

The transmission amount control device according to the present invention is characterized in that the value of the data transmission interval set in the transmission interval reference value table can be changed at any time.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1. FIG. 1 shows the configuration of a network system according to the embodiment. In the figure, 1 is a common transmission medium which is a common network medium such as a LAN and a frame relay network. A plurality of host computers 21-22 and a plurality of terminal devices 31-33 are connected to the common transmission medium 1,
Make up the network system. In the figure, there are two host computers and three terminal devices, but more than one may be connected.

Devices constituting this network system, that is, host computers 21 to 22 and terminal devices 31 to 3
3 is transmitting data to and from multiple devices,
All of these data are transmitted via the common transmission medium 1. Host computer 21 on this network
2 to 22 and terminal devices 31 to 33 are shown in FIG.

In FIG. 2, reference numeral 1 is a common transmission medium.
Reference numeral 21 is a host computer, and 211 is a transmission amount control device.
The transmission amount control device 211 is incorporated in the host computer 21. The transmission amount control device 211 includes a load measurement / determination module 2111, a transmission amount control module 2112, a transmission time storage table 41, a performance table 42, a response time reference value table 43, and a transmission interval reference value table 44. The load measurement / judgment module 2111 measures the load of the common transmission medium 1 and calculates the load coefficient. The transmission amount control module 2112 includes a load measurement / determination module 21.
11, the transmission interval of the transmission data is controlled based on the calculated load coefficient. Transmission time storage table 41
Is a table that stores the time when the transmission amount control module 2112 transmitted the transmission data. Achievement table 42
As shown in FIG. 3, is a table for storing the response time of the previously transmitted data and the load coefficient corresponding to the response time adopted at that time. The response time is the difference between the time when data is transmitted and the time when response data for the data is received. An example of the response time reference value table 43 is shown in FIG. The response time reference value table 43 is a table that stores the response time reference value and the reference load coefficient corresponding thereto. The response time reference value may be fixed data, but as will be described later, the value of the response time reference value can be increased or decreased depending on the actual value of the data transmission load. An example of the transmission interval reference value table is shown in FIG. The transmission interval reference value table 44 is a table that stores reference transmission intervals corresponding to load factors. The reference transmission interval can be changed according to the load of data transmission on the common transmission medium 1.
However, the reference transmission interval may be fixed data for the load coefficient.

FIG. 6 shows a load measuring / determining module 211.
It is a flowchart showing the flow of the process of 1. After the transmission data i is transmitted, the load measurement / judgment module 2111 starts processing when the response data i to the transmission data i is received. In step S31, the load measurement / judgment module 2111 takes in the response time at which the response data i was received from the system timer. In step S32, the time when the data i is transmitted is read from the transmission time storage table 41. In step S33, the time difference between the response time and the transmission time is calculated and used as the response time, and the response time is recorded in the actual result table 42. In step S34, the response time reference value is read from the response time reference value table 43. In step S35, the load coefficient is calculated. The load coefficient is calculated by comparing the response time reference value with the previously calculated response time to obtain the load coefficient. The calculation of the load coefficient will be described later in detail. In step S36, the load coefficient corresponding to the response time previously stored in the performance table 42 is stored in the performance table 42. Step S
At 37, the response time reference value is learned. Learning the response time reference value means that the actual value of the data transmission load
This is to increase or decrease the value of the response time reference value in the response time reference value table 43.

Next, the method of calculating the load coefficient in step S35 will be described in more detail with reference to the flowchart of FIG. In steps S41 to S44, the response time is the response time reference value table 43 shown in FIG.
Check the range of the response time reference value of. In step S45, the reference load coefficient corresponding to the response time reference value to which the response time applies is set as the load coefficient used this time. For example, when the calculated response time is 2500 ms, the load coefficient is 0, as can be seen from FIG. When the response time is 40,000 ms, the load coefficient is 9. In this way, the load coefficient is calculated from the response time and the response time reference value table 43.

Next, FIG. 8 shows a processing flow of learning the response time reference value in step S37 of FIG. In the transmission amount control device 211, the learning function can be enabled or can be set by turning the learning flag on / off. In step S61, it is determined whether the learning flag is on, and n
If it is o, the process ends without performing any processing. If yes,
Then, the process proceeds to step S62. In step S62, the previous and present load coefficients stored in the performance table 42 are compared. If the previous and current load factors are equal,
The value of the response time reference value table 43 is not changed, and the process ends. If the current load coefficient is large, step S63
In, the response time reference value corresponding to the previous load coefficient is reduced by 1%, and the value of the response time reference value table 43 is updated. In step S62, if the load coefficient this time is smaller than the last time, the process of step S64 is performed. In step S64, the response time reference value corresponding to the previous load coefficient is increased by 1%, and the response time reference value table 43 is updated.

A specific example of the response time reference value learning will be shown using the result table 42 of FIG. 3 and the response time reference value table 43 of FIG. In FIG. 3, the previous load coefficient is 0 and the current load coefficient is 1, so the current load coefficient is larger. Therefore, the process of step S63 of FIG. 8 is performed. That is, the value of the response time reference value 3000 ms corresponding to the load coefficient 0 of the previous time is reduced by 1% to obtain a new response time reference value. The updated response time reference value can be obtained by the following formula. 3000- (3000 × 0.01) = 2970 ms The calculated new response time reference value 2970 ms is set to the response time reference value 30 of the response time reference value table 43 shown in FIG.
Overwriting on 00 ms, response time reference value table 43
To update.

Next, the processing flow of the transmission amount control module 2112 will be described with reference to FIG. When a request for transmitting data is made, the transmission amount control module 2112 reads the latest load coefficient from the actual result table 42, determines the transmission interval corresponding to the load coefficient from the transmission interval reference value table 44, and transmits the transmission data. It is delayed by an interval and then transmitted. In step S81, the transmission amount control module 2112 calculates the transmission interval. That is, the latest load coefficient is read from the performance table 42, the reference transmission interval is read from the transmission interval reference value table 44, and the transmission interval of the data to be transmitted this time is determined by the load coefficient. In step S82, the transmission amount control module 2
If the transmission interval is other than 0, 112 opens the time interval. Thereby, the transmission data can be delayed by the time of the transmission interval. In step S83, the transmission data is transmitted. In step S84, the time when the transmission data is transmitted is stored in the transmission time storage table 41. In step S85, the transmission interval reference value is learned. The transmission interval reference value learning function will be described later in detail.

The transmission interval calculation process in step S81 will be described in more detail with reference to FIG. In step S91, the latest load coefficient is read from the performance table 42. As the latest load coefficient, the latest load coefficient written in the performance table 42 by the load measurement / judgment module 2111 is used. In step S92,
Assign the latest load factor value to i. Step S93
In this case, the current transmission interval = transmission interval (i). That is, the value of the i-th reference transmission interval from the transmission interval reference value table 44 is assigned as the value of the current transmission interval.
For example, in the performance table 42 of FIG. 3, the latest load coefficient is 1, and at this time, the transmission interval reference value table 44.
The transmission interval of this time obtained from is 100 ms.

Next, referring to FIG. 11, the above step S85
A flow of processing for the transmission interval reference value learning described in 1 will be described. The transmission interval reference value learning function is a function of changing the value of the reference transmission interval stored in the transmission interval reference value table 44 according to the actual value of the data transmission load on the common transmission medium 1. The transmission amount control module 2112 operates only when the learning function is turned on. Step S111
In, it is determined whether or not the learning flag is on, and if it is no, the process is ended without performing the process. If yes, the process of step S112 is performed. In step S112, the actual response table 42 is referred to and the current response time and the previous response time are compared. If the current response time is 10% or more longer than the previous response time, the process of step S113 is performed. In step S113, the reference transmission interval corresponding to the previous load coefficient is reduced by 1%, and the value of the reference transmission interval in the transmission interval reference value table 44 is rewritten. Then, the process proceeds to step S115. In step S112,
If the current response time is 10% or more shorter than the previous response time, the process of step S114 is performed. Step S
At 114, the value of the reference transmission interval corresponding to the previous load coefficient is increased by 1%, and the transmission interval reference value table 44 is updated. Then, the process proceeds to step S115. If the difference between the current response time and the previous response time is within ± 10% in step S112, no process is performed and the process proceeds to step S115. In step S115,
The current load coefficient and response time of the actual result table 42 are moved to the load coefficient and response time of the previous time, and the process ends.

For example, the case of the result table 42 shown in FIG. 3 will be taken as an example. In the actual result table 42, when the response times of the previous time and this time are compared, it becomes (3400-2992) / 3400 × 100 = 12, and since the response time of this time is 10% or more,
Decrease the reference transmission interval of the previous load factor by 1%. But,
Since the last load coefficient is 0 and the reference transmission interval is 0 ms, it cannot be further reduced, and therefore the transmission interval reference value table 44 is not updated. Next, the result table 42
The value of is shown in FIG. Comparing the response time between this time and the previous time, (3400-9500) / 3400 × 100 = -17
Since it becomes 9.4 and the previous response time is 10% or more longer, the previous response time of the load coefficient is increased by 1%. The last load factor is 4, and the corresponding reference transmission interval is 800m.
s. 800+ (800 × 0.01) = 808 ms 808 ms is the load factor 4 of the transmission interval reference value table 44
It is rewritten as the reference transmission interval corresponding to.

Here, the actual result table 42 may store the latest (current) response time and load coefficient and the previous response time and load coefficient. This is because the learning function in the load measurement / judgment module 2111 and the transmission amount control module 2112 uses only the response time of the previous time and this time or the value of the load coefficient. Further, the response time and the load coefficient obtained by the load measurement / judgment module 2111 indicate the data transmission load on the common transmission medium 1 at that time. Therefore, the transmission amount control module 2112 reads out the latest load coefficient from the performance table 42 and uses it when determining the transmission interval. If the learning function is not used, the latest response time and load coefficient may be stored in the performance table 42. In the response time reference value table 43 and the transmission interval reference value table 44, the system operator may change the response time reference value and the reference transmission interval for each device according to the characteristics of the network system.

If the transmission interval of the transmission data is determined according to the data transmission load, that is, the response time, the correspondence table shown in FIG. 13 is used instead of using the response time reference value table 43 and the transmission interval reference value table 44. May be. The correspondence table records the reference transmission interval corresponding to the response time reference value. The transmission interval can be obtained from the response time by referring to the correspondence table. However, the response time reference value table 43
The reason why the transmission interval reference value table 44 is provided is to have a learning function, and to cope with the case where the response time happens to protrude by one time and greatly shifts at a certain time. In the case of the correspondence table, if the response time happens to be largely deviated, the value of the response time reference value or the value of the reference transmission interval is significantly changed if there is a learning function. On the other hand, when the response time reference value table 43 and the transmission interval reference value table 44 are provided, the response time reference value learning function changes the response time reference value to roughly control the change of the reference value. Next, by changing the reference transmission interval of the transmission interval reference value table 44 by the transmission interval reference value learning function, it is possible to perform finer control.

If the learning function is not provided, the correspondence table is valid. In this case, the load measurement / judgment module 2
The response time is calculated at 111, the reference transmission interval corresponding to this response time is obtained from the correspondence table, and the response time and the transmission interval are stored in the actual result table. Transmission amount control module 21
12 reads the latest transmission interval from the performance table,
Transmission data is transmitted according to the read transmission interval. Even in the transmission volume control device that does not have the learning function described above and that has the correspondence table, when the network load is high, the next transmission is withheld, leading to a decrease in the network load, and as a result, stable operation of the entire network system. Can be derived.

The transmission amount control device can be installed in all the host computers and terminal devices that compose the network system. Alternatively, the device to be mounted may be selected from the host computer and the terminal device. It is desirable to install these transmission amount control devices in all devices, but when selected and installed, the effect is enhanced by installing them in a device with a large amount of transmitted / received data (for example, a host computer).

As described above, this transmission volume control device refrains from the next transmission when the network load is high, so that the network load is reduced and, as a result, the stable operation of the entire network system is derived. That is, by adjusting the network load, a failure such as a network down can be avoided, and as a result, a highly reliable network system can be constructed. Further, the intervention of the system operator can change the reference value of the transmission rate control for each individual device in accordance with the characteristics of the network system. Moreover, since the learning function can be selected, the transmission interval can be flexibly adjusted according to the load of the network system. Further, the transmission amount control device can obtain the effect even if it is not installed in all the devices constituting the network.

[0029]

According to the present invention, the data transmission amount is controlled by the computer and the terminal device controlling the data transmission interval according to the data transmission load on the communication path respectively, and the network down due to the increase in network load is avoided. be able to. Therefore, a highly reliable network system can be constructed.

Further, according to the present invention, since the data transmission load on the communication path is determined based on the response time, the data transmission load on the communication path can be easily determined without using a special device.

Further, according to the present invention, since the response time reference value table is provided, the load judgment criterion with respect to the response time is changed by changing the relationship between the response time and the load coefficient stored in the response time reference value table. can do.

Further, according to the present invention, since the learning function is provided, it is possible to flexibly determine the data transmission load according to the change in the status of the network system.

Further, according to the present invention, the criterion for determining the data transmission load based on the response time can be changed for each individual device at an arbitrary time according to the characteristics of the network system.

Further, according to the present invention, since the transmission interval reference value table is provided, by changing the load coefficient and the data transmission interval stored in the transmission interval reference value table,
The data transmission interval for the data transmission load can be changed.

Further, according to the present invention, since the learning function is provided, the reference value of the data transmission interval can be changed according to the change of the situation of the network system.

Further, according to the present invention, the value of the data transmission interval with respect to the data transmission load can be changed for each individual device at an arbitrary time according to the characteristics of the network system.

[Brief description of drawings]

FIG. 1 is a diagram showing an overall configuration of a network system to which a transmission amount control device according to an embodiment of the present invention is applied.

FIG. 2 is a block diagram of a transmission amount control device according to an embodiment of the present invention.

FIG. 3 is a diagram showing the contents of a performance table in FIG.

FIG. 4 is a diagram showing an example of a response time reference value table in FIG.

5 is a diagram showing an example of a transmission interval reference value table in FIG.

6 is a flowchart showing a processing flow of a load measurement / judgment module in FIG.

7 is a more detailed flowchart for calculating the load coefficient in FIG.

FIG. 8 is a more detailed flowchart for learning the response time reference value in FIG.

FIG. 9 is a flowchart showing a processing flow of a transmission amount control module in FIG.

FIG. 10 is a more detailed flowchart for calculating the transmission interval in FIG.

11 is a more detailed flowchart for learning the transmission interval reference value in FIG.

FIG. 12 is a diagram showing another example of the result table in FIG.

FIG. 13 is a diagram showing an example of a correspondence table.

[Explanation of symbols]

1 common transmission medium 21,22 host computer, 31-
33 terminal device, 41 transmission time storage table, 42 performance table, 43 response time reference value table, 44 transmission interval reference value table, 211 transmission amount control device, 21
11 Load measurement / judgment module 2112 Transmission amount control module.

Claims (8)

[Claims] 1. In a network system in which a computer and a terminal device are connected to the same communication path and data is transmitted between the computer and the terminal device, the computer and the terminal device communicate according to a data transmission load on the communication path. A transmission amount control device for controlling a transmission interval of data to be transmitted. 2. The transmission amount control device according to claim 1, wherein the data transmission load on the communication path is judged by a response time which is a time difference between data transmission and its response. 3. The transmission amount control device according to claim 2, further comprising a response time reference value table in which a load coefficient is determined by the response time in order to determine a data transmission load on the communication path. Quantity control device. 4. The transmission amount control device according to claim 3, further comprising a learning function for changing the value of the response time set in the response time reference value table based on a load coefficient. apparatus. 5. The transmission amount control device according to claim 3, wherein the value of the response time set in the response time reference value table can be changed at any time. 6. The transmission amount control device according to claim 3, further comprising a transmission interval reference value table that defines a data transmission interval corresponding to the load coefficient. 7. The transmission amount control device according to claim 6, further comprising a learning function of changing a value of the data transmission interval set in the transmission interval reference value table based on a response time. Control device. 8. The transmission amount control device according to claim 6, wherein the value of the data transmission interval set in the transmission interval reference value table can be changed at any time. .