JPH02309732A - Start type network communication system - Google Patents

Abstract

PURPOSE:To improve the processing efficiency and to prevent the throughput of a communication from decreasing by assigning mutually different addresses to all low-order stations, specifying one of low-order stations from a master station, and adding data to said addresses and sending them to the respective low-order stations. CONSTITUTION:The respective slave stations and subordinate slave stations are given serial numbers 1-mX(n+1) in order so that their addresses are mutually different. When one of the slave stations is specified and data is sent from the master station, the master station specifies one slave station directly as a final target with one address. For example, when one subordinate slave station is specified and command data is sent from the master station, the master station generates the command data and determines the address of the specified subordinate slave station. Then the data is sent to the respective slave stations and the master station waits for response data from the subordinate slave station. When the response data is received, processing regarding the response data is performed and finished.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a star network communication system, and particularly to a star network communication system in which one master station is hierarchically connected to a plurality of lower stations through sequential multipoint connections. Concerning communication methods.

[Conventional technology]

FIG. 4 is a block diagram showing an example of a conventional star network. In the figure, a master station 1 includes slave stations 21, 22 . ..., 2m are multi-point connected, and furthermore, the slave stations 21, 22, ..., 2m are
Further lower grandchild stations 311 to 31n, each consisting of n stations
, 321-32n,...

3ml to 3mn are multi-point connected to form a star network.

The same address for each station is assigned independently and redundantly between the master station and multiple slave stations connected by multipoints, and between each slave station and multiple substations connected by multipoints. , in this case, 1 to m for the slave station.
, 1 to n are assigned to each child station for the grandchild station.

In this case, the number of grandchild stations that are multi-point connected to each child station is n, but there is no particular restriction and any number may be connected.

FIGS. 5(a) and 5(b) are explanatory diagrams showing an example of a data format used in the conventional star network communication system in the network configuration shown in FIG. 4.

When transmitting command data from the master station to the grand station, and
This is a data format used when sending response data from a grandchild station to a parent station. This data format conforms to the high-level data link control procedure frame structure standardized by ISO and JIS. Fifth
Figure (a) shows a data format used between a master station and a slave station. The address of a grandchild station as seen from the parent station is determined by the combination of the slave station address to which the grandchild station is connected and the grandchild address, so if one of the grandchild stations is specified from the parent station. When sending command data from the master station to the slave station, the data format sent from the master station to the slave station is as follows:
The child station address is specified following the start flag, and the address of the specified grandchild station is added next to the control field.

FIG. 5(b) shows the data format used between the child station and the grandchild station. Each slave station that receives command data in the data format shown in Figure 5(a) from the master station deletes its own address if it confirms that the slave station address on the data format is its own address. ,
Start flag followed by grandchild address, control field, and data.

The data format is converted so that it becomes a chain effect sequence and a termination flag, and the data is sent to each substation connected at multiple points. When each substation receives command data in the data format shown in Figure 5(b) from the substation and confirms that the address is its own address, it processes the command data and sends a response back to the master station. Data is created and sent back to the slave station in the data format shown in FIG. 5(b). The slave station that received the response data from the grandchild station adds its own address and sends it to the fifth station.
After converting into the data format shown in Figure (a), the data is returned to the master station.

[Problem to be solved by the invention]

In the conventional star network communication method described above, the addresses of the lower stations that are hierarchically connected to the master station through multi-point connections are duplicated and uniquely assigned to each layer. When a station specifies one of its lower-level stations for communication, it cannot uniquely specify the address of that lower-level station. In addition to requiring multiple stages of address determination, the data format transmitted from the master station requires
The address of each lower station that is connected between the master station and the designated lower station and relays communication must also be added.
In addition, it is necessary to convert the data format at each lower station that relays communication, which complicates processing at each station, lowering processing efficiency, increasing the amount of data, and reducing communication throughput. There is.

SUMMARY OF THE INVENTION The object of the present invention is to provide a star network communication system that eliminates the drawbacks of the prior art by assigning different addresses to each station.

[Means to solve the problem]

The star network communication system of the present invention is a star network communication system in which one master station is hierarchically connected to a plurality of lower stations through sequential multi-point connections. When transmitting data by specifying one of the lower stations from the master station, the address assigned to the designated lower station is added to the data. The data is sent to each lower station that is multi-point connected, and each lower station that receives the data checks whether the specified lower station that corresponds to the address is hierarchically connected to its own station. , if the specified lower station is connected, the address is added to the data and transmitted to each lower station that is multi-point connected, and each further lower station sequentially transmits the data in the same way. It is characterized by transmitting to lower-level stations.

〔Example〕

Next, the present invention will be explained with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of a star network according to the present invention. In the same figure, similar to the conventional configuration diagram shown in FIG.
22. ..., 2m and multi-point connection,
Furthermore, the slave stations 21, 22°, .
~32 n, ・.

3ml to 3mn are connected at multiple points to form a star-shaped network connected in a hierarchical manner.

A serial number of 1 to m × (n+1) is sequentially assigned to each slave station and each grandchild station so that the addresses of each station are different from each other. Addresses 2 to (n+1>) are assigned to substations 311 to 31n that are multi-point connected to 21. In the same manner, addresses (m-1) x (n+1)+1 are assigned to slave station 2m. However, for the substations 3ml to 3mn that are multi-point connected to the substation 2m, the address (m-1)X (n + 1)
+2~mX(n+1) is assigned.

Although FIG. 1 shows a hierarchical connection up to the grandchild stations, lower stations may be connected in a hierarchical manner. In addition, although the number of grandchild stations that are multi-point connected to each slave station is set to n, there is no particular restriction on the number of stations that are multi-point connected to each slave station, and any number of stations may be connected. Furthermore, the addresses of each station may be randomly assigned different addresses instead of serial numbers.

FIG. 2 is an explanatory diagram showing an example of a data format used in the star network communication system of the present invention.

This is a data format used when transmitting command data from a master station to a lower station, and when returning Helles Bonus data from a lower station.This data format is a high-speed data format established by ISO and JIS. This is based on the level data link control procedure frame. Each lower station is assigned a different address, so when a master station specifies one of the lower stations and sends data, the master station uniquely identifies the final target lower station using one address. can be specified directly. Therefore, the data format can be configured as a start flag followed by a specified lower station address, control field, data, chain execution sequence, and end flag, and all lower stations hierarchically connected to the master station. All data formats used between them can be unified into the same format.

FIGS. 3(a) to 3(c) are flowcharts showing an example of the processing procedure at each station of the star network communication system of the present invention in the network configuration shown in FIG. 1. FIG. 3(a) is a flowchart showing an example of the processing procedure at the master station. When the master station specifies one of the grandchild stations and sends command data (step 110), the master station transmits the command data. step 111), determine the address of the specified substation (step 112), send the data format shown in Figure 2 to each slave station that is multi-point connected (step 113), and the response from the substation. Waiting for data reception (step 114)
, upon receiving the response data, performs processing related to the response data (step 115), and ends the processing (step 1B).

FIG. 3(b) is a flowchart showing an example of a processing procedure at each slave station connected intermediately between a master station and a slave station designated as the master station and relaying command data from the master station.
Step 12: Receive command data from the master station
0), (Step +21), the slave station checks whether the grandchild station with the corresponding address is connected. As a means for checking, for example, the check is performed by referring to a table in which addresses of lower-level stations connected in a hierarchical manner are written in advance. If it is confirmed that the corresponding grand station is connected (step 122), the received command data is sent to each multi-point connected grand station in the same data format 1 (step 123). .

After transmitting the command data, it waits to receive response data from the substation (step +24), and when the response data is received, it returns it to the master station in the same data format (step +25), and ends the process (step 126). . If the corresponding grandchild station is not connected, the process ends (step 122).
6).

FIG. 3(C) is a flowchart showing an example of the processing procedure of a designated substation that receives command data transmitted from a master station, and includes step 130) when receiving command data via a slave station. (Step 131) Checks whether the address shown on the data format is the address of the own station. If it is confirmed to be the own address, then Step +32) performs processing regarding the received command data (Step 131). 133), create response data to the master station (step 134), return the response data to the slave station in the same data format (step +35), and end the process (step 136). If it is not the own station address (step +32), the process ends (step 136).

Note that even when many lower stations are connected in a hierarchical manner, the processing procedure of the master station is the same as that shown in Figure 3 (a), and the processing procedure of the master station is the same as that shown in Figure 3 (a). The processing procedure of the designated lower station is the same as the procedure shown in Figure 3 (C), and furthermore, the processing procedure of the designated lower station is the same as that shown in Figure 3 (C). The processing procedure of each lower station that relays data is also the same as the procedure shown in FIG. 3(b).

〔Effect of the invention〕

As explained above, according to the star network communication system of the present invention, by allocating different addresses to all lower-level stations connected in a hierarchical manner, the master station can control each lower-level station using one address. It is possible to specify the address uniquely and directly, therefore, the process for determining the address of the lower station is simplified, and the data format can be unified. There is no need to convert the data format at each lower-level station that is connected to the network and relays communications, improving processing efficiency.Additionally, only one address is required to add address information to the data format, making it easier to use than conventional This method has the effect of reducing the amount of data and improving communication throughput compared to the conventional method. Furthermore, since the data format is unified for each station, in the unlikely event that a failure occurs in the lower station that relays communication, communication can be resumed normally by directly connecting the master station and the specified lower station. It has the advantage that it can be done.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of the star network of the present invention, and FIG. 2 is an example of a data format used in the star network, 71 to 71-work communication system of the present invention. FIGS. 3(a) to 3(C) are flowcharts showing an example of the processing procedure at each station of the star network communication system of the present invention in the network configuration shown in FIG.
Figure 4 is a configuration diagram showing an example of a conventional star network, and Figures 5 (a) and (b) are data used in the conventional star network communication system in the network configuration shown in Figure 4. It is an explanatory diagram showing an example of a format.

1... Master station, 21~2m... Slave station, 311~3mn
...Sun Station.

Claims (1)

[Claims] In a star network communication system in which one master station is hierarchically connected to a plurality of lower stations through sequential multi-point connections, different addresses are assigned to all of the hierarchically connected lower stations, and the When transmitting data by specifying one of the lower stations from the master station, the address assigned to the designated lower station is added to the data and each lower station connected at a multi-point Each lower station that has received the data checks whether the specified lower station corresponding to the address is hierarchically connected to itself, and confirms that the specified lower station is connected. If the address is added to the data, it is transmitted to each lower-level station that is multi-point connected, and each further lower-level station sequentially transmits the data to the lower-level station in the same manner. A star network communication method.