JPH11284642A - Data transmission system, polling method, and polling frequency setting method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To speed up a data transfer process by dynamically varying the frequencies of polling to respective secondary stations. SOLUTION: A process for determining a polling frequency is activated in certain cycles (S1). In a cycle wherein the polling frequency is determined (Yes in S1), a control part reads data transmission/reception frequencies of the respective secondary stations out of a data transmission/reception table (S2) and finds the data transmission/reception rate of the respective frequencies (S3). The control part determines the polling frequencies of the respective secondary stations by referring to a transmission/reception ratio polling frequency table together with the obtained transmission/reception ratio (S4). Lastly, the control part stores (sets) the determined polling frequencies in the polling frequency table (S5).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a polling frequency setting method in a polling type data transmission system, and more particularly to a polling frequency setting method applied to a packet switching device.

[0002]

2. Description of the Related Art A packet switching apparatus is a packet assembling / disassembling apparatus (PAD: Packet Assembler / D).
isassembler). There are two types of terminals connected to the packet switching network, and they handle data in a packet format (X.
25) can and cannot be sent and received.

The latter is a non-packet type terminal (NP
T: Non-Packet mode Termina
l). This non-packet type terminal is either non-procedure or 25 (for example, SDLC /
BSC procedure).

In some cases, it is desired to accommodate this non-packet type terminal in a packet network. In this case, it is necessary to convert a non-packet protocol to a packet protocol. The above-described packet assembling / disassembling apparatus accommodates a non-packet type terminal and has a function of performing conversion from a non-packet protocol to a packet protocol and conversion from a packet protocol to a non-packet protocol.

In some cases, this non-packet type terminal is accommodated in a polling type data transmission system.

Conventionally, there has been known a data transmission system in which a center (primary station) transmits and receives data to and from a plurality of terminals (secondary stations) in a polling rig system. One of them is, for example, the “communication system” disclosed in Japanese Patent Application Laid-Open No. 61-35644 (hereinafter referred to as prior art). In the communication system disclosed in this prior art, in a data transmission system of a polling system, a transmission / reception number N setting unit for setting the number of polling times in advance or each time, and a terminal having a large amount of data as a designated terminal in advance or each time. Terminal / non-designated terminal setting and control unit for setting.

Next, an outline of the operation disclosed in the prior art will be described. In a polling type data transmission system, the number of polling times N
Is set. Also, a terminal having a large amount of data to be transmitted and received is designated as a designated terminal in the designated terminal / undesignated terminal setting and control section. When the designated terminal is called, data transmission / reception is performed N times continuously. As described above, data transmission / reception is performed continuously N times, thereby shortening the data processing time.

[0008]

However, the above-mentioned prior art has the following problems.

A first problem is that when the number of polling is set, polling is continuously performed for the set number N even when no data is transmitted / received. As a result, when there is no transmission / reception of data of the designated terminal, useless polling is performed. In addition, transmission and reception of data to and from a terminal other than the designated terminal is delayed due to useless polling to the designated terminal, resulting in a decrease in data response. The reason is that the N
This is because, when polling is performed once, regardless of the presence or absence of data, if the terminal is a designated terminal, polling is performed the number of times specified by the number of transmissions / receptions N.

A second problem is that the setting of the number of polling times N and the designation of the designated terminal / undesignated terminal cannot be changed in real time in accordance with increase / decrease of data. As a result, for example, even if the data amount of the terminal designated as the unspecified terminal increases, the number of polls cannot be changed in real time, and the data processing of the unspecified terminal takes time. The reason is that, in the setting of the number of polling times N and the designation of the designated terminal / undesignated terminal, the designation is not changed in real time in accordance with the increase or decrease of the data.

It is therefore an object of the present invention to shorten the data transfer process by dynamically changing the number of polls to each secondary station.

[0012]

According to a first aspect of the present invention, there is provided a data transmission system in which a primary station transmits and receives data to and from a plurality of secondary stations by a polling method.
A polling frequency table for setting the number of polling times performed by the primary station at a time for each secondary station; and the plurality of secondary clocks after starting polling according to the polling frequency set in the polling frequency table. A transmission / reception monitoring timer table for monitoring transmission / reception data with a station for a certain period of time; and a data transmission / reception number table for counting the number of data transmissions / receptions between the primary station and each secondary station and storing the data. And a transmission / reception ratio polling frequency table storing the number of polling times corresponding to the data transmission / reception ratio, and a data transmission / reception ratio between each secondary station based on the data transmission / reception ratio for each secondary station stored in the data transmission / reception frequency table. The data transmission / reception ratio is calculated, and the data transmission / reception ratio obtained by the calculation is referred to the transmission / reception ratio polling frequency table to determine the po Control means for determining the number of rings and storing the determined number of polls in the polling number table, wherein the number of polling is dynamically determined from a data transmission / reception ratio with each secondary station. Is obtained.

[0013] According to a second aspect of the present invention, in a data transmission system in which a primary station transmits and receives data to and from a plurality of secondary stations in a polling manner, the primary station can control each secondary station. In the polling method, when data is not transmitted / received to / from all the secondary stations, polling is normally performed once for each secondary station, and the polling is performed with a specific secondary station. When data is transmitted and received, polling is performed only for the specific secondary station for the number of polls set in the polling frequency table, and for the remaining secondary stations, polling is performed only once. The polling method is characterized in that the polling method is performed.

Further, according to a third aspect of the present invention, in a data transmission system in which a primary station transmits and receives data to and from a plurality of secondary stations in a polling manner, the primary station can control each secondary station. In the polling method, when data is not transmitted / received to / from all the secondary stations, polling is normally performed once for each secondary station, and the polling is performed with a specific secondary station. If data is sent or received,
Only for the specific secondary station, during the time specified by the timer value stored in the transmission / reception monitoring timer table, polling is performed for the polling number set in the polling number table, and the remaining secondary stations are polled. A polling method characterized by performing ordinary one-time polling for a station is obtained.

Still further, according to a fourth aspect of the present invention, in a data transmission system in which a primary station transmits and receives data to and from a plurality of secondary stations by a polling method, each secondary station of the primary station Is a method of setting the number of times of polling for each secondary station, wherein the number of times of polling once corresponding to the data transmission / reception ratio with each secondary station is stored in a transmission / reception ratio polling number table, and The data transmission / reception count is counted, the count value is stored in a data transmission / reception count table, the data transmission / reception count with each secondary station is read from the data transmission / reception count table, and each secondary station is read from the read data transmission / reception count. The data transmission / reception ratio in each secondary station is calculated, and the data transmission / reception ratio in each secondary station obtained by the calculation is referred to the transmission / reception ratio polling frequency table, and once for each secondary station. Determining the number of polls, a polling number setting method comprising the step of storing the polling frequency of once for each secondary station having the determined polling count table is obtained.

As characterized by these methods, the present invention solves the above-mentioned first problem in the prior art as follows. That is, when there is no data transmission / reception, polling is not performed at the set number of times, and polling is performed at the set number of times when data transmission / reception occurs. In order to realize this, according to the present invention, a timer is started immediately after the start of polling at a set number of times, and the presence or absence of data is monitored. Normal polling is performed.

In the ordinary polling method, since polling is performed equally to all the secondary stations, the secondary station having a large number of data transfers has to wait for data transfer more frequently, which causes a decrease in terminal response. I was Also, there is a technology that can change the number of polls for each terminal as in the above-mentioned prior art, but polling is performed a preset number of times regardless of the presence or absence of data transmission, so data transfer is performed. When there is no polling operation, the response of the other secondary stations is reduced.

In the present invention, the second problem in the prior art described above is solved as follows. That is, the number of data transmission / reception for each secondary station is counted and stored, the data reception ratio of each secondary station is calculated from the count value, and the number of polls is set based on the ratio. In the above-mentioned prior art, setting of the number of polling times is described, but no detailed description is given of a method of setting the number of polling times.

[0019]

Embodiments of the present invention will be described below in detail with reference to the drawings.

Referring to FIG. 2, a description will be given of a polling type data transmission system to which a polling number setting method according to an embodiment of the present invention is applied.

The illustrated data transmission system comprises a primary station 10.
And first to third secondary stations 21, 22 and 23. First to third secondary stations 21 to 23 are connected to the primary station 10 in a branch manner via a bus-like transmission line. Note that the primary station 10 is also called a master station, and the secondary station is also called a slave station. Alternatively, the primary station 10 is also called a center, and the secondary station is also called a terminal. The primary station (master station) 10 is composed of these first to third secondary stations (slave stations).
Data transmission / reception is performed by the polling method with 21 to 23.

FIG. 3 shows components included in the primary station 10. The primary station 10 includes a polling number table 11,
It includes a transmission / reception monitoring timer table 12, a data transmission / reception number table 13, and a transmission / reception ratio polling number table 14.

The polling count table 11 is a table for setting the polling count to be transmitted at one time for each secondary station. In the polling count table 11, c ₁ is the number of polls which corresponds to the first secondary station 21, c ₂ is the number of polls corresponding to the second secondary station 22, c ₃ is the third secondary station 23 Represents the number of polls corresponding to.

The transmission / reception monitoring timer table 12 is a table having, for each secondary station, a timer value for monitoring data transmission / reception with the secondary station for a certain period of time to determine whether data transmission / reception continues. In the transmission / reception monitoring timer table 12, t ₁ represents a timer value corresponding to the first secondary station 21, and t _{2 represents} a timer value corresponding to the first secondary station 21.
Is the timer value corresponding to the second secondary station 22, and t ₃ is the third timer value.
, Respectively, represents the timer value corresponding to the secondary station 23.

The data transmission / reception number table 13 is a table having the data transmission / reception number with the secondary station for each secondary station.
In the data transmission / reception number table 13, m ₁ denotes the number of transmission / reception of data corresponding to the first secondary station 21, m ₂ denotes the number of transmission / reception of data corresponding to the second secondary station 22, and m ₃ denotes the third number of data.
Represents the number of times of data transmission / reception corresponding to the secondary station 23.

The transmission / reception ratio polling number table 14 is
This is a table for determining the number of polls from the transmission / reception ratio of each secondary station obtained from the number of data transmission / receptions of each secondary station, and the number of polls is set for each transmission / reception ratio.
In the illustrated example, the polling frequency is set for each transmission / reception ratio in the transmission / reception ratio polling frequency table 14 as described below.

That is, when the transmission / reception ratio is 0.8 or more, the number of polls n ₁ is 6; when the transmission / reception ratio is less than 0.8 and 0.7 or more, the number of polls n ₂ is 5
However, when the transmission / reception ratio is less than 0.7 and 0.6 or more, 4 is used as the number of polling n ₃ , and when the transmission / reception ratio is less than 0.6 and 0.5 or more, 3 is used as the number of polling n ₄ ,
When transmission and reception ratio is 0.4 or more less than 0.5 2 as polling number n ₅ are set respectively.

FIG. 1 is a flowchart for explaining a polling setting method according to the present invention. The illustrated flowchart shows the process up to the determination of the number of polls from the transmission / reception ratio. Although not shown, the primary station 10 includes a control unit as means for determining the number of times of polling according to the flowchart shown in FIG. In other words, the control unit determines the number of times of polling according to the flowchart shown in FIG.

Next, a method of setting the number of times of polling will be described with reference to FIGS.

First, referring to FIG. 3, the primary station 10 increments the counter value of the data transmission / reception table 13 every time data is transmitted / received to / from the secondary station.

Next, referring to FIG. 1, the process of determining the number of polls is started at a fixed cycle (step S).
1). If it is the cycle for determining the number of times of polling (Yes in step S1), the control unit reads the number of times of data transmission / reception m _{1 to} m ₃ of the _{first to third} secondary stations 21 to 23 from the number of times of data transmission / reception table 13 ( Step S2), the respective data transmission / reception ratios are obtained (step S3). Data transmission and reception ratio in this _{case, m x / (m 1 +} m 2 + m 3) is obtained by {x = 1,2,3}. For example, the case of obtaining the transmission and reception ratio of the second secondary station 21, is determined by the equation _{m 1 / (m 1 + m} 2 + m 3). Similarly, the transmission / reception ratio is determined for the second and third secondary stations 22 and 23 as well.

The control unit determines the number of polls of each secondary station from the transmission / reception ratio thus obtained by referring to the transmission / reception ratio polling number table 14 (step S).
4). Finally, the control unit stores (sets) the determined polling count in the polling count table 11 (step S5).

There are two methods for calculating the transmission / reception ratio, namely, a method for obtaining from the number of data transmission / reception and a method for obtaining from the total number of data transmission / reception bytes. These two
In the present embodiment, the transmission / reception ratio is determined from the number of data transmission / reception. The reason is that the number of times of data transmission / reception has a stronger relationship with the number of times of polling.
On the other hand, in the case of the total number of bytes, even if the data processing is completed by one polling, if the data amount is large, the counting is large.

The polling frequency for the transmission / reception ratio in the transmission / reception ratio polling frequency table 15 shown in FIG.
The value can be changed depending on the state of each secondary station connected to the primary station (for example, the number of connected secondary stations, data processing type, etc.).

FIG. 4 is a diagram showing an example of a data sequence from the primary station (master station) 10 to the first to third secondary stations (substations) 21 to 23.

Next, the operation of the data transmission system of the present invention will be described with reference to FIG. 4 and FIG.

It is assumed that there is no transmission / reception of data as indicated by T1 in FIG. In this case, the master station 10 transmits polling, and the first to third slave stations 21 to 23 each return a response response with no data. Polling at this time is performed once for each slave station equally.

It is assumed that data has been received from the first slave station 21 as indicated by T2 in FIG. In this case, the control unit of the main station 10 sets m _{1 in the} data transmission / reception number table 13 to m _1.
Is added to +1. The control unit of the master station 10 starts the timer having the timer value t ₁ of the first slave station 21 set in the transmission / reception monitoring timer table 12 (hereinafter referred to as t ₁ timer), and at the same time, starts the polling count table. The polling count c ₁ for the first slave station 21 set to 11
Only poll.

It is assumed that data is received from the first slave station 21 as indicated by T3 in FIG. In this case, the main station 10
Restarts the t ₁ timer. This timer value can be changed.

[0040] While doing the polls _once c to the first slave station 21, the second and third slave stations 22 and 23
Is not polled, and c ₁ to the first slave station 21 is not polled.
When the first polling is completed, polling operations for the second and third slave stations 22 and 23 are sequentially performed.

Thereafter, only during the t ₁ timer, the first slave station 2
The polling to 1 is c ₁ times polling referring to the polling number table 11. When there is no data transmission / reception with the first slave station 21 for a period set by the t ₁ timer, the control unit of the master station 10 stops polling with reference to the polling count table 11 and performs normal one-time polling. Become like

It should be noted that the present invention is not limited to the above-described embodiment, and various modifications and changes can be made without departing from the spirit of the present invention. For example, in the above description, the case where data is received from the first slave station 21 has been described, but the same applies to the case of data transmission and the case of the second and third slave stations 22 and 23. Although the number of slave stations is three in the above operation example, the number of slave stations is of course not limited to three.

[0043]

As described above, according to the present invention, the number of polls can be changed only when data is transmitted / received, so that unnecessary polling is not performed. Therefore, the data processing time can be reduced. In addition, according to the present invention, the number of polls can be changed in real time according to the increase / decrease of traffic according to the ratio of the number of data transmission / reception for each terminal. Therefore, the data processing time can be reduced even for traffic generated in bursts. Can be achieved.

[Brief description of the drawings]

FIG. 1 is a flowchart illustrating a polling frequency setting method according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a data transmission system to which the polling number setting method shown in FIG. 1 is applied.

FIG. 3 is a block diagram showing components included in a primary station used in the data transmission system shown in FIG. 2;

FIG. 4 is a sequence diagram showing an example of a data sequence from a primary station to each secondary station in the data transmission system shown in FIG.

[Explanation of symbols]

 Reference Signs List 10 Primary station (master station) 11 Polling count table 12 Transmission / reception monitoring timer table 13 Data transmission / reception count table 14 Transmission / reception ratio polling count table 21 to 23 Secondary station (slave station)

Claims (5)

[Claims] In a data transmission system in which a primary station transmits and receives data to and from a plurality of secondary stations by a polling method, the primary station sets the number of times of polling performed once for each secondary station. A polling count table for transmitting and receiving a transmission / reception monitoring timer for monitoring transmission / reception data between the plurality of secondary stations after starting polling according to the polling count set in the polling count table for a predetermined time; A data transmission / reception table that counts the number of times data is transmitted / received between each of the secondary stations in the primary station and stores the count, and a transmission / reception ratio polling frequency table that stores the number of polls corresponding to the data transmission / reception ratio. , Based on the data transmission / reception ratio of each secondary station stored in the data transmission / reception number table, Data transmission / reception ratio is calculated, the polling frequency for each secondary station is determined by referring to the transmission / reception ratio polling frequency table from the data transmission / reception ratio obtained by the calculation, and the determined polling frequency is referred to as the polling frequency table. A data transmission system, wherein the number of polls is dynamically determined from a data transmission / reception ratio with each secondary station. 2. A polling method for each secondary station by said primary station in a data transmission system in which a primary station transmits and receives data to and from a plurality of secondary stations by a polling method, wherein all secondary stations are provided. If there is no data exchange with
The normal polling is performed once for each secondary station, and when data is transmitted / received to / from a specific secondary station, the polling count table is displayed only for the specific secondary station. A polling method characterized in that polling is performed a set number of times and polling is performed only once for the remaining secondary stations. 3. A polling method for each secondary station by said primary station in a data transmission system in which a primary station transmits and receives data to and from a plurality of secondary stations by a polling method, wherein: If there is no data exchange with
A normal one-time polling is performed for each secondary station, and when data is transmitted / received to / from a specific secondary station, a transmission / reception monitoring timer is applied only to the specific secondary station. During the time specified in the timer value stored in the table, poll the number of polls set in the poll count table, and poll the remaining secondary stations only once. A polling method characterized by the following. 4. A method for setting a single polling count for each secondary station of said primary station in a data transmission system in which a primary station transmits and receives data to and from a plurality of secondary stations by a polling method. Then, the number of times of polling corresponding to the data transmission / reception ratio with each secondary station is stored in the transmission / reception ratio polling frequency table, and the number of data transmissions / receptions with each secondary station is counted. Is stored in the data transmission / reception number table, the data transmission / reception number with each secondary station is read from the data transmission / reception number table, and the data transmission / reception ratio in each secondary station is calculated from the read data transmission / reception number. Referring to the transmission / reception ratio polling frequency table from the obtained data transmission / reception ratio in each secondary station, determine the number of polling times of each secondary station once, A polling frequency setting method including a step of storing the determined polling frequency of each secondary station in a polling frequency table. 5. A method for setting a single polling count for each secondary station of said primary station in a data transmission system in which a primary station transmits and receives data to and from a plurality of secondary stations by a polling method. A polling frequency setting method, wherein the number of polling times is dynamically determined from a data transmission / reception ratio between the primary station and each of the secondary stations.