JPH0761084B2 - Storage and exchange device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a store-and-forward device.

[Prior Art] For example, when a data transmission network is prepared by using a line network such as a public telephone line network, a center having a function larger than that of a data terminal device rather than operating each data terminal device independently. It is better to install a station device and use the function of this center station device for each data terminal device.
Since it is possible to use each data terminal device having a small function, when looking at the entire data transmission network,
Economically advantageous.

A storage exchange device is one of such center station devices.

This storage and switching device pulls in a large number of lines,
It has a function to store transmission information and a function to process in parallel for each line. For example, transmission information from one terminal device can be sent to multiple terminal devices specified at a specified time. It is possible to realize a transmission function such as time-specified broadcast transmission.

By the way, the number of lines drawn into the storage switching apparatus is set to an appropriate value depending on the traffic volume with the data terminal equipment which constitutes the data transmission network. In addition, whether each line is for transmission only or reception only,
Alternatively, whether to use for transmission and reception is fixedly set according to the breakdown of the traffic, that is, the ratio of transmission traffic and reception traffic.

However, since the traffic volume and the breakdown of the traffic fluctuate depending on the time of day, etc., the usage classification of each line (that is, whether the line is dedicated for transmission,
Depending on the time of day, if the terminal device calls the store-and-forward device, the store-and-forward device cannot call or the store-and-forward device does not call. This causes the inconvenience that a free line is not found when trying to call.

Therefore, conventionally, the usage classification of each line has been changed to a preset mode depending on the time zone, or manually by an operator as necessary.

However, such a conventional method has a disadvantage that it cannot appropriately cope with dynamically changing traffic.

[Purpose] The present invention has been made in order to eliminate the disadvantages of the prior art, and an object thereof is to provide a storage and switching apparatus that can appropriately cope with dynamically changing traffic.

[Structure] In order to achieve this object, the present invention has a traffic measuring means for measuring traffic in each time zone of a day, and a traffic storing means for storing a measurement result of the traffic measuring means for a predetermined period in a day unit. A traffic predicting means for predicting traffic in the next hour based on the information stored in the traffic storing means, and a control means for controlling the usage classification of each line based on the prediction result of the traffic predicting means. I have it.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 shows a data transmission network constructed by using the storage and switching apparatus according to the present invention.

In the figure, this data transmission network is connected to a line network NW such as a public telephone line network, n data terminal devices TM1 to TMn connected to this line network NW, and a line network NW and m lines. It is composed of the storage and exchange device SC.

An example of the storage and exchange device SC is shown in FIG.

In the figure, the system control unit 1 is the storage exchange device.
The data transmission to the line control units LC1 to LCn, which controls the entire SC and also controls m lines connected to the line network NW, is performed in a time division manner.

The operation display unit 2 is composed of an input device such as a keyboard and a display device such as a screen display device necessary for operating the storage and exchange device SC, and the printer 3 records and outputs logs and the like of the storage and exchange device SC. The magnetic storage device 4 is for storing various information such as transmission information and transmission condition information received from the data terminal devices TM1 to TMn.

The traffic measurement control unit 5 includes system control units 1 to 1
Based on the communication start time information, communication end time information, communication distinction information that is notified each time one data transmission is completed,
Every hour from the hour on the hour, the traffic of the entire storage and switching device SC is measured, the result is stored in the memory 6, and the traffic on the hour from the next hour is predicted. Set the number of lines to be allocated to each line, the number of lines to be exclusively used for reception, and the number of lines to be allotted for transmission / reception, and the results are
To notify.

The traffic measurement control unit 5 stores the following two tables in the memory 6 in order to determine the number of lines to be allocated for transmission only, reception only and transmission / reception in correspondence with traffic.

Here, Table 1 is a table referred to when the transmission traffic is larger than the reception traffic, and Table 2 is a table referred to when the reception traffic is larger than the transmission traffic. Also, the traffic is classified in stages, and increases in the order of td ₁ , td ₂ , td ₃ , ..., td _K , ..., td _I. That is, the size of the traffic td is td
_{When 1} <td <td ₂ , the data in the column of traffic td ₁ is used. Also in this case, the traffic value is the sum of the transmitted traffic and the received traffic. Also,
The number of dedicated transmission lines, the number of dedicated reception lines, and the number of transmission / reception lines in the same traffic are set empirically, and the total number of these lines is equal to the number of lines m.
However, in Table 1, the number of dedicated transmission lines for the same traffic is set to a value larger than the number of dedicated reception lines, and in Table 2, the number of dedicated reception lines for the same traffic is larger than the number of dedicated transmission lines. Is set to.

The number of lines corresponding to the traffic is empirically determined, and in this case, the number of lines P _k corresponding to the traffic td _k is the number m of lines connected to the storage and switching device SC. In such a case, there may be one or more data terminal devices that cannot be connected even if the storage and switching device SC is called, or there is no free line when the storage and switching device SC attempts to make a call. There is a possibility that In order to prevent the number of receive-only lines or the number of send-only lines from becoming 0 in such a large traffic that the value of the number of lines P exceeds m, the minimum value of each is set to 1. There is.

The contents of these Tables 1 and 2 are preset when the storage and switching device SC is started to operate. Depending on the time, it will be updated at appropriate times.

Now, with the above configuration, the storage exchange device SC becomes the data terminal device.
When providing the data transmission service to TM1 to TMn, when the system control unit 1 finishes the data transmission with one data terminal device, the start time, the end time of the data transmission, and the transmission or reception. Is sequentially notified to the traffic measurement control unit 5.

The traffic measurement control unit 5 receives one hour (for example, 13:00 to 13:00 59) from each hour notified by the system control unit 1.
Minute) data, transmission traffic td _T , reception traffic td _R, and transmission / reception traffic in the relevant time period
The td _TR is calculated according to the following formula.

td _T = (x _T / 3600) (Ehlang) td _R = (x _R / 3600) (Ehran) td _TR = (x _TR / 3600) (Ehlang) where x _T is the transmission line usage time at that time The cumulative total (unit is second), x _R is the cumulative total of receiving line usage time (unit is second) at that time, and x _TR is the cumulative total line usage time (unit is second) at that time. Therefore, x _TR corresponds to the sum of x _T and x _R.

In this way, when the transmission traffic td _T , the reception traffic td _R, and the transmission / reception traffic td _TR in each time zone are calculated, the traffic measurement control unit 5 converts the data for one day into the format shown in Table 3 below. Is stored in the memory 6. Further, in this case, the memory 6 stores data for 30 days from the previous day.

Here, the month, day, and day of the week are the measured date and the day of the week.

In addition, the traffic measurement control unit 5 predicts the traffic within one hour from the next hour in parallel with the process of calculating and storing the traffic in this way, and based on the prediction result, the above-mentioned Table 1 and Table 2 are shown. Refer to the number of transmission dedicated lines,
The number of dedicated reception lines and the number of transmission / reception lines are determined, and the result is returned to the system control unit 1.

That is, as shown in FIG. 3, first, simple average values d, e, f of the transmission traffic td _T , the reception traffic td _R, and the transmission / reception traffic td _TR for the past 30 days in the predicted time period
And the traffic that is expected to be transmitted on the same day of the week as td _T , inbound traffic td _R, and inbound and outbound traffic
A simple average value g, h, i of td _TR is calculated (processing 101, 102).

Next, which of the simple average value f and the simple average value i has a larger value is identified. First, the simple average value f and the simple average value i are directly compared (decision 103), and when the simple average value f is large (including equal cases), it is checked whether the transmission / reception traffic tends to increase (decision 104). For example,
The simple average value f _-1 of the transmitted and received traffic td _TR for the past 30 days 1 hour before the predicted time period and the simple average value f _-2 of 2 hours before are compared, and the simple average value f _-1 is f _-2 If it is larger than this, it is determined that the transmission / reception traffic is on the increase.

When the simple average values f ₋₁ and f ₋₂ are equal, the same determination process is performed one hour back. If they are still equal, the same determination process is repeated until the difference is traced back one hour at a time.

When the result of judgment 104 is YES, it is predicted that the value of the transmission / reception traffic in the predicted time zone is the simple average value f, and it is judged whether the simple average value e is equal to or more than the simple average value d (decision 10).
Five).

If the result of determination 105 is YES, the received traffic is larger than the transmitted traffic, and therefore the number of dedicated transmission lines, the number of dedicated reception lines, and the number of transmission / reception lines are obtained with reference to Table 2 using the simple average value f. (Process 106).

If the result of determination 105 is NO, the transmission traffic is larger than the reception traffic. Therefore, referring to Table 1 using the simple average value f, the transmission dedicated line number, the reception dedicated line number, and the transmission / reception line number are determined. Each is obtained (process 107).

When the result of the determination 104 is NO, it is predicted that the value of the transmission / reception traffic in the predicted time zone is the simple average value i, and it is determined whether the simple average value h is the simple average value g or more (determination
108).

If the result of decision 108 is YES, the received traffic is larger than the transmitted traffic, and therefore the number of transmission dedicated lines, the number of reception dedicated lines, and the number of transmission / reception lines are obtained with reference to Table 2 using the simple average value i. (Process 109).

If the result of determination 108 is NO, the transmission traffic is larger than the reception traffic. Therefore, referring to Table 1 using the simple average value i, the transmission dedicated line number, the reception dedicated line number, and the transmission / reception line number are determined. Obtain each (process 110).

Further, if the result of the judgment 103 is NO, it is judged by the same judgment 111 as the judgment 104 whether or not the transmission / reception traffic tends to increase. If the result of the judgment 111 is YES, the transmission / reception traffic in the predicted time zone is determined. Predict that the value of is the simple average value i and branch to decision 108, and the result of decision 111 is
In the case of NO, the value of the transmission / reception traffic in the predicted time zone is predicted to be the simple average value f, and the process branches to the determination 105.

In this way, the number of transmission dedicated lines, the number of reception dedicated lines, and the number of transmission / reception lines thus obtained are notified to the system control unit 1.

As a result, the system control unit 1 identifies the transmission / reception state of each line, and determines the number of transmission-dedicated lines, the number of reception-dedicated lines, and the number of transmission / reception lines in the predicted time zone to the values notified from the traffic measurement control unit 5. Therefore, the line use section is set in the line control units LC1 to LCn.

Therefore, the line control unit assigned to transmission only does not accept an incoming call from the connected line, and the line control unit assigned to reception only does not accept an outgoing call using the connected line. Also, the line control unit assigned for transmission and reception permits the call originating or the call receiving, whichever comes first.

In this way, the traffic in each time zone is predicted, and the use category of each line is assigned based on the prediction result, so that the traffic in that time zone can be appropriately processed.

By the way, in the above-mentioned embodiment, the traffic is predicted using the simple average value of the traffic for the past 30 days in the same time zone and the simple average value of the traffic in the same time zone on the same day of the week. The traffic data referred to for this purpose may use other data.

For example, as is well known, since traffic fluctuates on a monthly or yearly basis, it is possible to refer to the statistical value of traffic in each time zone on each day and the statistical value of traffic in each time zone on each month. it can. However, for that purpose, it is necessary to store more data.

Further, the data in Tables 1 and 2 are updated so as to eliminate them, for example, based on information such as the frequent occurrence of busy states sent from the user of each data terminal device. At this time,
This update can be realized by operating the operation input unit. In addition, the system control unit may appropriately update when a state in which a call cannot be made occurs.

[Effect] As described above, according to the present invention, traffic measuring means for measuring traffic in each time zone of the day, and traffic storing means for storing the measurement result of the traffic measuring means for a predetermined period on a daily basis. A traffic predicting means for predicting traffic in the next hour based on the information stored in the traffic storing means, and a control means for controlling the usage classification of each line based on the prediction result of the traffic predicting means. Since it is equipped, it is possible to appropriately deal with dynamically changing traffic.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a data transmission network according to an embodiment of the present invention, FIG. 2 is a block diagram showing an example of a storage switching device, and FIG. 3 is a flow chart showing an example of traffic prediction processing. 1 ... System control unit, 5 ... Traffic measurement control unit, 6 ... Memory, LC1 to LCn ... Line control unit, SC ... Storage and switching device, NW ... Line network, TM1 to TMn ... Data terminal device .

Claims (1)

[Claims] 1. A storage and switching device for drawing in a large number of lines, temporarily storing received information from a terminal device, and transmitting the stored information to another terminal device in a mode corresponding to a command from the terminal device. Traffic measuring means for measuring the traffic in each time zone, traffic storing means for storing the measurement result of the traffic measuring means for a predetermined period, and traffic in the predetermined time zone based on the information stored in the traffic storing means A storage and switching apparatus comprising: a traffic predicting means for predicting traffic, and a control means for controlling a use classification of each line based on a prediction result of the traffic predicting means.