JPH0423535A - Multiple address communication system - Google Patents

Abstract

PURPOSE:To shorten time required for multiple address communication by transmitting multiple address data to which the destination codes of respective destination terminal equipments are added to a rapid data exchange network in parallel and transferring the data to the destination terminal equipment through the rapid data network by a multiple address function part. CONSTITUTION:A terminal equipment 2z requiring multiple address communica tion adds a multiple address destination display part B specifying destination terminal equipments 2A to 2C to a pair of multiple address data (d) and transmits the processed contents to a multiple address function part 3. Since the function part copies the data (d) correspondingly to the equipments 2A to 2C specified by the display part B, adds respective destination codes to the data (d) and sends the code-added data to a rapid data exchange network 1 in parallel, the multiple address data (d) can be simultaneously transferred to respective equipments 2A to 2C. Consequently, the time required for multiple address commu nication can be shortened.

Description

[Detailed Description of the Invention] [Summary] Regarding a broadcast communication method that simultaneously transfers the same data to a plurality of terminal devices via a high-speed data exchange network, the broadcast communication via the high-speed data exchange network is The aim is to make it possible to create and transfer data without spending a lot of time.In a high-speed data exchange network that transfers high-speed data between multiple terminal devices that accommodate multiple terminal devices, the same broadcast data can be transmitted multiple times. A broadcast means is provided corresponding to a terminal device that desires broadcast communication to be forwarded to a destination terminal device, and the terminal device that desires broadcast communication has a broadcast destination display section for specifying the destination terminal device of the broadcast communication. The broadcasting means transmits the broadcast data to the broadcasting means, and the broadcasting means transmits one terminal to be connected to the terminal device desiring the broadcast communication and the number of destination terminal devices for the broadcast communication connected to the high-speed data exchange network. The high-speed data exchange network communicates to each destination terminal device from the broadcast destination display section added to the broadcast data transmitted from the terminal device desiring broadcast communication. It generates each destination code assigned to set up a route, duplicates broadcast data equal to the number of destination terminal devices from the broadcast data transmitted from the terminal device desiring broadcast communication, and processes each duplicated broadcast data. Each destination code is added to the data, and the data is configured to be transmitted to the high-speed data exchange network from a plurality of terminals connected to the high-speed data exchange network.

[Industrial Field of Application] The present invention relates to a broadcast communication system that simultaneously transfers the same data to a plurality of terminal devices via a high-speed data exchange network.

In recent years, Batcher Banyan has been developed as one of the high-speed data exchange networks that enable high-speed broadband communication.
asynchronous transfer mode (Asynchronous transfer mode)
usTransfer Mode: ATM
) transmission networks are rapidly being put into practical use.

Even in this type of high-speed data exchange network, it is desirable to enable broadcast communication in which the same data is transferred all at once from one of the multiple terminal devices accommodated to multiple other terminal devices. It will be done.

[Conventional technology]

FIG. 5 is a diagram showing an example of a conventional broadcast communication system.

In FIG. 5, a plurality of terminal devices 2A to 2Z are accommodated in a high-speed data exchange network 1, and mutually transfer data via the high-speed data exchange network 1.

The high-speed data exchange wA1 assigns destination codes a to a2 to each of the terminal devices 28 to 2Z it accommodates, and for example, another terminal device 2B that wishes to transfer data d to the terminal device 2A assigns a destination code to the data d. When aA is added and the data is sent to the high-speed data exchange network 1, the high-speed data exchange network 1 analyzes the destination code aA using a known method and transfers the data d to the destination terminal device 2A.

In this state, if any terminal device 2Z wishes to transfer the same data d (hereinafter referred to as broadcast data d) to a plurality of other terminal devices 2A to 2c, the terminal device 2
Z creates three sets of broadcast data d, and each broadcast data d has 2 to 2 destination terminal devices. The destination codes a to a assigned to the data are added to the data, and the data is sequentially sent to the data exchange network l.

When the high-speed data exchange network receives the broadcast data d with the destination code aA first sent from the terminal device 22, it transmits it to the destination terminal device 2 in a known manner. and then to the terminal device 2Z.
When the broadcast data d with the destination code all sent from the terminal device 2B is received, it is transferred to the destination terminal device 2B by a known method, and finally, when the broadcast data d with the destination code ac sent from the terminal device 22 is received, The data is transferred to the destination terminal device 2c using the method described below.

[Problems to be Solved by the Invention] As is clear from the above explanation, in a conventional high-speed data exchange network, a terminal device 2z desiring broadcast communication transmits broadcast data d to the number of destination terminal devices (three in the previous example). 2 A to 2 destination terminal devices 2 A to 2 via the high-speed data exchange network 1 addressed to the - group.
As the number of destination terminal devices increases, it takes a lot of time to create and transfer the broadcast data d, which causes problems such as occupying the transmitting terminal device 2Z during that time.

SUMMARY OF THE INVENTION An object of the present invention is to enable broadcast communication via a high-speed data exchange network without spending a large amount of time creating and transmitting broadcast data.

(Means for solving problems) FIG. 1 is a diagram showing the principle of the present invention.

In FIG. 1, 1 is a high-speed data exchange network 0.2 to 2Z, which are objects of the present invention, are terminal devices accommodated in the high-speed data exchange network 1, and a terminal device 2Z is connected to a plurality of other terminal devices 2A.
I would like to perform broadcast communication that transfers the same broadcast data d for 2v to 2v.

100 is a terminal device 2 that desires broadcast communication according to the present invention.
This is a broadcast means provided corresponding to Z.

[Operation] The terminal device 22 desiring broadcast communication transmits to the broadcast means 100 the broadcast data d to which a broadcast destination display section B specifying the destination terminal devices 2A to 2v of the broadcast data d is added. .

The broadcast means 100 includes one terminal for connecting to a terminal device 2Z desiring broadcast communication, and a plurality of terminals equal to the number of destination terminal devices for the broadcast communication connected to the high-speed data exchange network 1.

The broadcasting means 100 also includes terminal devices 2 that wish to perform broadcast communication.
From the broadcast destination display part B added to the broadcast data d transmitted from Z, the high-speed data exchange network 1 is connected to each destination terminal device 2.
Destination codes aA to a7 given to A to 2Y for setting communication channels are generated.

The broadcasting means 100 also includes terminal devices 2 that wish to perform broadcast communication.
From the broadcast data d transmitted from Z, the number of broadcast data d equal to the number of destination terminal devices is duplicated.

Further, the broadcasting means 100 adds each of the destination codes aA to aY to each of the duplicated broadcast data d, and transmits the data to the high-speed data exchange network l from a plurality of terminals connected to the high-speed data exchange network 1.

The broadcast destination display section B is composed of a plurality of bits, and each bit corresponds to each terminal device 2 that is assumed to be the target of broadcast communication.
Corresponding to A to 2 so, set the bit corresponding to the terminal device that wishes to transfer the broadcast data d to logic "l"', and set the bit corresponding to the terminal device that does not wish to transfer the broadcast data d to logic "l"'. Setting it to “'0” is considered.

Further, the broadcast means 100 includes a broadcast destination display section B according to claim 2.
and adds the destination codes aA to a7 assigned to the terminal devices 2A to 2y corresponding to the bits set in the logical "pi" to each replicated broadcast data d, and transmits the data to the high-speed data exchange network 1. will be considered.

It is also considered that the high-speed data exchange network 1 is configured as a batch Banyan network.

In addition, when the high-speed data exchange network 1 is constructed using the known batch Banyan system, the broadcasting means 100 includes a plurality of bits that respectively set the destination codes aA to aY to the unit switches of multiple stages constituting the high-speed data exchange network 1. It is considered to consist of

Therefore, a terminal device desiring broadcast communication only needs to transmit a set of broadcast data to which a broadcast destination display section in a predetermined format is added that specifies multiple destination terminal devices to the broadcast means. transmits the broadcast data with the destination code of each destination terminal device added in parallel to the high-speed data exchange network, and then transfers it to the destination terminal device via the high-speed data exchange network, which significantly reduces the time required for broadcast communication. It will be shortened.

〔Example〕

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 2 is a diagram showing a same-layer communication system according to an embodiment of the present invention, FIG. 3 is a diagram showing an example of a broadcast function section in FIG. 2, and FIG. FIG. 3 is a diagram illustrating an example of a broadcast data format according to an example.

■ Note that the same reference numerals indicate the same objects throughout the figures.

In FIGS. 2 and 3, a broadcasting function section 3 is provided as the broadcasting means 100 in FIG. 1.

The broadcast function unit 3 is provided in correspondence with the terminal device 2Z that may target all other terminal devices 2A to 2v for broadcast communication, and is configured to perform broadcast communication via the communication adapter (ADP) 301. A communication adapter (ADP) connected to the corresponding terminal device 22 and corresponding to each destination terminal device 2^ to 2Y.
It is connected to the high-speed data exchange network 1 via 310a to 310Y.

Also, in the broadcast function unit 3, destination registers (ARG) 308A to 308 corresponding to each destination terminal device 2A to 2S are provided.
v is provided, and by executing a predetermined registration operation from the console 311, the high-speed data exchange network 1 can register each destination terminal device 2. Destination code aA assigned to to 2.
thru aY are accumulated respectively.

Note that the destination codes a to aY are route information having bits equal to the number of stages, for example, when the high-speed data switching network 1 is configured as a batch Banyan network consisting of multiple stages of unit switches (2X2). is expressed by

In this state, if the terminal device 2Z wishes to transfer the same broadcast data d to the terminal devices 2A, 2, and 2c, it changes the broadcast destination display section B to the broadcast data d as shown in FIG. and transmits it to the broadcast function section 3.

As shown in FIG. 4, the broadcast destination display section B includes broadcast display bits bA to b corresponding to each destination terminal device 2A to 2Y.
Set the broadcast display pins }bA to bc corresponding to the terminal devices 2A to 2 that wish to transfer the device broadcast data d consisting of v to logical ``bi'', and do not wish to transfer the broadcast data d. terminal device 2D
Broadcast indication bit b corresponding to 2v to 2v. to b7 are set to logic "0".

In the broadcast function unit 3, a microprocessor (MPU
) 302 is transmitted from the terminal device 2Z to the broadcast destination display section B
When the attached broadcast data d is received via the communication adapter (ADP) 301, the received broadcast data d with the multicast destination display part B is temporarily stored in a predetermined storage area in the memory (MEM) 303, and then the same The broadcast destination display section B is divided into a broadcast destination display section B and broadcast data d, and the broadcast destination display section B is stored in a broadcast destination reading section (BRD) 304, and the broadcast data d is stored in a data register (DRG) 305.
Accumulate in.

The broadcast destination reading section (BRD) 304 reads corresponding AND gates 306^ to 306V according to the logical values of the broadcast display bits bA to bY of the accumulated broadcast destination display section B.
The logical product data 1 corresponds to the broadcast display bits bA to bc which are set to logic "1".
-306A to 306 are set to conductive state, and logic "'
Logical product game corresponding to broadcast display bits bD to by set to 0''}306. to 306V is set to the cutoff state.

As a result, the microprocessor (MPU) 302 transfers the broadcast data d accumulated in the data register (DRG) 305 to the data buffer (DBF )3
Transfer/copy from 07A to 307c.

Next, the microprocessor (MPU) 302 controls the adder circuits 309A to 309c, and controls the data buffer y (D
BF) Destination codes aA to a stored in destination registers (ARG) 308A to 308c are added to each broadcast data d copied to 307A to 307o, respectively, and sent via communication adapters (ADP) 310A to 310c. and sends it to the high-speed data exchange network 1.

Thereafter, the high-speed data exchange network 1 uses a known method to extract the destination codes aA to aC added to each broadcast data d sent from the broadcast function unit 3 via the communication adapters (ADP) 31 oa to 310C. The multicast data d is analyzed and transferred to each of the destination terminal devices 2A to 2C.

As is clear from the above description, according to this embodiment, the terminal device 2Z desiring broadcast communication is connected to the destination terminal devices 2A to 2.
By simply adding the broadcast destination display section B specifying Z to a set of broadcast data d and transmitting it to the broadcast function section 3, the broadcast function section 3
Copies the broadcast data d corresponding to the destination terminal devices 2A to 2c designated by the broadcast destination display section B, adds destination codes aA to ac to each, and sends them in parallel to the high-speed data exchange network 1. , the broadcast data d is simultaneously transferred to each of the destination terminal devices 2A to 2c.

Note that FIGS. 2 to 4 are only one embodiment of the present invention, and for example, the destination terminal devices are not limited to 2A to 20, and can be arbitrarily specified within the terminal devices 2A to 2Y. However, the effects of the present invention remain the same in either case. In addition, the terminal device that executes broadcast communication is 2. However, any terminal device 2A to 2Z provided with the broadcast function section 3 can perform broadcast communication, but the effects of the present invention remain the same in either case. Furthermore, the high-speed data exchange network 1 to which the present invention is applied is not limited to the batch Banyan network, and the broadcast destination display section B is not limited to the route information applied to the batch Banyan network.
Although many other modifications may be considered, the effects of the present invention remain the same in any case.

[Effects of the Invention] As described above, according to the present invention, in the high-speed data exchange network, a terminal device desiring broadcast communication uses one terminal device to which a broadcast destination display section in a predetermined format for specifying a plurality of destination terminal devices is added. By simply transmitting the set of broadcast data to the broadcast means, the broadcast means sends the broadcast data to which the destination code of each destination terminal device is added in parallel to the high-speed data exchange network, and the broadcast data is transmitted via the high-speed data exchange network. Since the information is then transferred to the destination terminal device, the time required for broadcast communication is significantly reduced.

[Brief explanation of drawings]

FIG. 1 is a diagram showing the principle of the present invention, FIG. 2 is a diagram showing a broadcast communication system according to an embodiment of the invention, FIG. 3 is a diagram showing an example of the broadcast function section in FIG. FIG. 4 is a diagram showing an example of a broadcast data format according to an embodiment of the present invention, and FIG. 5 is a diagram showing an example of a conventional broadcast communication system.

Claims (5)

[Claims] (1) In a high-speed data exchange network (1) that transfers high-speed data between multiple terminal devices (2_A to 2_Z) accommodated, the same broadcast data (d) is transferred to multiple destination terminal devices (2_A to 2_Z).
The terminal device (from
2_Z) is provided with a broadcast means (100), and the terminal device (2_Z) desiring the broadcast communication has a broadcast destination display section for specifying the destination terminal device (2_A to 2_Y) of the broadcast communication. The broadcast data (d) to which (B) has been added is transmitted to the broadcast means (100), and the broadcast means (100) connects to the terminal device (2_Z) that desires the broadcast communication. one terminal and a plurality of terminals equal to the number of destination terminal devices of the broadcast communication connected to the high-speed data exchange network (1), and the terminal device (2_Z) that is transmitted from the terminal device (2_Z) desiring the broadcast communication In order for the high-speed data exchange network (1) to set up a communication path to each of the destination terminal devices (2_A to 2_Y) from the broadcast destination display section (B) added to the broadcast data (d). from the broadcast data (d) transmitted from the terminal device (2_Z) desiring the broadcast communication, broadcast data (d) equal to the number of destination terminal devices. ), add each of the destination codes (a_A to a_Y) to each of the duplicated broadcast data (d), and transmit the high-speed data exchange from a plurality of terminals connected to the high-speed data exchange network (1). A broadcast communication system characterized by transmitting to each network (1). (2) The broadcast destination display section (B) is composed of a plurality of bits, and each bit corresponds to each terminal device (2_A to 2_Y) that is assumed to be the target of the broadcast communication, and The bit corresponding to the terminal device that wishes to transfer the broadcast data (d) is set to logic “1”, and the bit corresponding to the terminal device that does not wish to transfer the broadcast data (d) is set to logic “0”.
2. The broadcast communication system according to claim 1, wherein the broadcast communication system is set to ``. (3) The broadcast means (100) analyzes the broadcast destination display unit (B) according to claim 2, and selects terminal devices (2_A to 2_Y) corresponding to the bits set to logic "1". 2. The broadcasting system according to claim 1, wherein a destination code (a_A to a_Y) assigned to the broadcast data (a_A to a_Y) is added to each of the replicated broadcast data (d) and transmitted to the high-speed data exchange network (1). Communication method. (4) The broadcast communication system according to claim 1, wherein the high-speed data exchange network (1) is comprised of a batch Banyan network. (5) When the high-speed data exchange network (1) is configured with the batch Banyan network, the broadcast means (100) configures the high-speed data exchange network (1) with the destination code (a_A to a_Y). 2. The broadcast communication system according to claim 1, wherein each of the plurality of unit switches for setting a plurality of bits includes a plurality of bits.