JPH0787098A - Equipment address designation method for network system - Google Patents

Abstract

PURPOSE:To allow the method to cope flexibly with revision of an equipment address of a communication opposite party even when the equipment has a difficulty in the processing of a character string such as a sequencer. CONSTITUTION:The system is provided with plural equipment A, B, C and one or plural networks K, L to which the plural equipments are connected and the equipments have equipment addresses Kn0, Kn1, Kn2, Ln0 comprising the network numbers K, L of the networks and comprising numbers N0, N1, N2 allocated to the equipments connecting to the same network. Each equipment is connected to the network system and the network is provided with an equipment address registration table in which equipment addresses of all equipment making inter-equipment communication is implemented via the network system and the communication opposite party is specified by designating relative numbers 0, 1, 2,...n of the equipment address registration table in the inter-equipment communication.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device addressing method in a network system.

[0002]

2. Description of the Related Art A conventional method of designating a device address of a communication partner device is to directly describe the device address of the communication partner device in an application program for communication (hereinafter abbreviated as an application program). Alternatively, as shown in FIG.
Provide the management table shown in (A) or (B) of FIG.
A method of registering the device name and the device address corresponding to this in the management table and describing the device name in the application program has been used.

3A and 3B are block diagrams of network systems used in the prior art and the present invention. In FIG. 3A, all devices are on the same network (network number K). 3B shows an example of the configuration connected to
A configuration example in which communication is performed by further connecting to another network (network number L) via the route control device TC from the configuration of FIG. 3A is shown.

In FIG. 3A, for simplification, three devices A, B, and C are connected to a network K indicated by a network number K (hereinafter, the network is identified by the network number). An example of the created configuration is shown. The device address is composed of a network number of the network and a number assigned to each device connected to the same network. All devices A, B, C are connected to the network K, and the device numbers assigned to the devices A, B, C connected to the same network are sequentially
The numbers n ₀ , n ₁ , n ₂ , are taken. At this time, all device addresses seen as a network system are
At n ₀ , device B is designated as Kn ₁ and device C is designated as Kn ₂ .

In FIG. 3B, the device A and the device B are connected to the network K, the device C is connected to the network L, and the route control device TC is used to connect the network K and the network L from the network K. Information is transmitted to the network L, and conversely, information from the network L is transmitted to the network K. Since the network K and the network L may normally have different transmission speeds, transmission capacities, transmission formats, etc., the route control device TC uses a communication data memory buffer, a communication data memory buffer, or the like so as to adapt to the coupling interface between these networks. Has intelligence such as format conversion. The device numbers of the devices A and B connected to the network K are n ₀ and n ₁ . The device number of the device C connected to the network L and shown in a double frame for facilitating identification is the number n ₀ on the network L. At this time, all device addresses of the network system as a whole are Kn ₀ for device A, Kn ₁ for device B, and Ln _{0 for} device C.
It is represented by.

FIG. 4 is a management table of the above device addresses used as a network system, and is represented by a set of a device name and a device address. 4A shows a management table in the case where all devices are connected to the same network shown in FIG. 3A. Device names “HOST-A”, corresponding to devices A, B, and C, are shown in FIG. The names of "HOST-B" and "HOST-C" correspond to the device addresses Kn ₀ , Kn ₁ and Kn ₂ . 4 (B) is
FIG. 3B shows a management table when devices are connected to the two networks K and L in FIG. 3B, and device names “HOST-A” and “HOST-B” are associated with devices A, B and C. , The name of “HOST-C” corresponds to the device addresses Kn ₀ , Kn ₁ , and Ln ₀ .

When the device C is changed from the network K to the network L, the device address of the device C is changed by changing the device address corresponding to the device name "HOST-C" on the management table from Kn ₂ to Ln ₀ . It is done by That is, since the device name on the management table is configured with the same name regardless of the network configuration, modification of the device on the network can be done by simply changing the management table. Need not be changed.

FIG. 5 shows a processing flow chart of inter-device communication.
For example, when a communication request is made from the device A to the device C in step S1, at this time, by describing "HOST-C" in the application program of the device A, "HOST-C" is specified in step S2. The device address Kn ₂ (in the case of FIG. 3 (A)) or Ln ₀ (in the case of FIG. 3 (B)) corresponding to is obtained, and the communication process with “HOST-C” is executed in step S3. .

[0009]

As described above, since the device address includes the network number, it may be changed due to a change in the scale of the network system. Therefore, the device address of the communication partner device is changed. It must be able to respond flexibly to changes. In addition, it is often difficult to handle a character string such as a device name in a computer with limited functions such as a sequencer, as in a computer.

The present invention has been made in view of the above points, and an object of the present invention is to solve the above-mentioned problems and to provide a communication partner device even in a device such as a sequencer in which a character string is difficult to handle. An object of the present invention is to provide a device addressing method for a network system capable of flexibly coping with changes in device addresses.

[0011]

In order to achieve the above-mentioned object, the invention according to claim 1 is provided with a plurality of devices and one or a plurality of networks to which the plurality of devices are connected. Is connected to a network system in a device addressing method of a network system having a device address consisting of a network number of a network and a number assigned to each device connected to the same network, and is connected via this network system. Each device that performs device-to-device communication includes a device address registration table in which device addresses are registered, and in device-to-device communication, a communication partner device is specified by specifying a relative number in the device address registration table.

In the invention according to claim 2, it is assumed that the device address registration table is registered with the device addresses of all the devices that perform inter-device communication. Further, in the invention according to claim 3, in the device address registration table, the device addresses of all the devices, excluding the device address of the device itself, are registered among all the devices that perform inter-device communication.

[0013]

With the above configuration, each device connected to the network system and performing device-to-device communication via this network system has a device address registration table in which device addresses are registered. The communication partner device can be specified by designating the relative number in the device address registration table of the partner device.

Therefore, in the application program, it is not necessary to directly describe the device address in this program,
It can be described by specifying the relative number of the device address registration table. When changing the device address,
Since this can be done only by changing the device address registration table, it is possible to flexibly deal with changing the device address. In the device address registration table, device addresses of all devices that perform inter-device communication are registered. In this case, a device address registration table common to the network system may be created and installed in each device.

Further, in the device address registration table, the device addresses of all the devices, excluding the device address of the device itself, among all the devices that perform inter-device communication are registered. In this case, the location corresponding to the relative number with which the device number of itself is registered is blank.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is an explanatory view for explaining a device address registration table according to the present invention, FIG. 2 is a processing flow diagram for communication between devices, and FIG. 3 is a configuration diagram of a network system already explained in the prior art, and FIG. 5, the same members corresponding to FIG. 5 and steps in the flow chart are denoted by the same reference numerals.

FIG. 3A shows a configuration example in which all devices are connected on the same network K. The device addresses in this configuration example are that device A is Kn ₀ and device B is Kn ₁ , Device C
It is represented by Kn ₂ . FIG. 1 shows the configuration of the device address registration table, in which device addresses, for example, Kn ₀ , Kn ₁ , and Kn ₂ are registered and described corresponding to the relative numbers of the device address registration table. 1A is an example of the configuration of the device address registration table connected to the same network K shown in FIG. 3A. In this example, the relative address 1 is the device address Kn ₀ of the device A. , The relative address 2 is the device address Kn ₁ of the device B, and the relative number n is the device address Kn ₂ of the device C. The relative number describing the device address is created, for example, as a serial number when the device address registration table is first created. However, as the number of devices connected to the network is improved, the relative number describing the device address is described as an empty relative number. In FIG. 1A, the device C is an example described in the relative number n, and when the device C is called by the application program,
The relative number n may be designated on the application program.

FIG. 1B shows a configuration example of the device address registration table when the devices A and B are connected to the network K shown in FIG. 3B and the device C is connected to the network L. Yes, here, for example, the device C is (A) in FIG.
A configuration example of the device address registration table when the connection is changed from the network K shown by to the network L shown in FIG. In this configuration modification example, the device address Kn ₀ of relative number 1 and the device address of relative number 2 are
There is no change in Kn ₁ , and the description of the device address of device C described in relative number n is changed from Kn ₂ to Ln ₀ surrounded by a double frame. That is, the device C described by the relative number n means that the device number n ₀ is connected to the network L.

As described above, the device address change of the device C is as follows.
This can be done by changing the description of the device address corresponding to the relative number n. By specifying the relative numbers in the device address registration table, all device addresses seen as the entire network system can be specified without being aware of which network the device is connected to and what number it is. , The refurbishment of devices on the network,
There is no need to change the application program, only changing the device address registration table.

FIG. 2 shows a processing flow chart of inter-device communication.
For example, when the device A makes a communication request to the device C in step S1, at this time, the relative number is described as n in the application program of the device A, so that step S2A
Device address Kn ₂ (Fig. 3 (A))
, Or Ln ₀ (in Fig. 3 (B)),
In step S3, the communication process with the device C is executed.

In the above description, all the devices that are connected to the network system and communicate with each other are described in the device address registration table. However, in the application program, the devices are generally self-registered. Since it is not necessary to communicate with itself, there is no practical problem even if the description of the device address corresponding to the relative number of itself is omitted from the device address registration table installed in each device.

In the above description, for simplification of description, the devices connected to the network system have been described as the three devices A to C, but the number of devices connected to the network system or the number of networks is different. It need not be limited.

[0023]

As described above, according to the configuration of the present invention, when the device address registration table is provided and the communication partner device is designated, the relative number of the device address registration table is described in the application program. , The communication partner device can be specified. Therefore, even a device such as a sequencer whose character string is difficult to handle can be connected to the network system for communication. At this time, even if the device address of the communication partner device is changed, it can be dealt with by changing the device address registration table of the corresponding relative number. Therefore, it is possible to flexibly respond to the change of the device configuration on the network system. It is possible to respond.

[Brief description of drawings]

FIG. 1 is an explanatory diagram illustrating a device address registration table according to the present invention.

FIG. 2 is a processing flowchart of communication between devices.

FIG. 3 is a configuration diagram of a network system used in the description of the related art and the present invention.

FIG. 4 is an explanatory diagram illustrating a management table in the related art.

FIG. 5 is a processing flow chart of inter-device communication in the related art.

[Explanation of symbols]

A, B, C device n ₀ , n ₁ , n ₂ device number K, L network number Kn ₀ , Kn ₁ , Kn ₂ , Ln ₀ device address TC communication path controller 0,1,2, ... n relative number HOST -A, HOST-B, HOST-C device name

Claims (3)

[Claims] 1. A plurality of devices and one or a plurality of networks to which the plurality of devices are connected, wherein the device includes a network number of the network,
A device addressing method for a network system having a device address consisting of a number assigned to each device connected to the same network, and performing device-to-device communication via the network system. Each device includes a device address registration table in which the device address is registered, and in inter-device communication, a communication partner device is specified by designating a relative number in the device address registration table. Device addressing method 2. The device address designating method for a network system according to claim 1, wherein the device address registration table is registered with device addresses of all devices that perform inter-device communication. Device addressing method 3. The device address designating method for a network system according to claim 1, wherein the device address registration table is a device address of all devices among the devices performing inter-device communication, excluding the device address of the device itself. Is registered, the device addressing method of the network system characterized by the above