JPS5961251A - Data transmission system - Google Patents

Abstract

PURPOSE:To obtain a transmission system having no limitation to the number of terminals and the distance by coupling many networks each of which is obtained by connecting many terminals by using a coupler and transmitting data at the same protocol. CONSTITUTION:Data processors 11-65 such as personal computers and pocket computers are connected to transmission lines 1-8 in the same network. The transmission lines 1-8 are connected to other transmission lines through network couplers 120-560 to couple the terminals connected to each transmission line each other. Although the connection terminals pulled out from the devices 170, 580 are not shown in the block diagram, it is indicated that the network is expanded moreover. Thus, the number of terminals and the total extension distance of the networks can be increased infinitely.

Description

[Detailed Description of the Invention] [Technical Field] The present invention relates to a data transmission system, and in particular to a data transmission system in which a large number of data processing devices 1, such as minicomputers, personal computers, pocket computers, etc., are connected through a transmission line to mutually transmit data. The present invention relates to a data transmission system that performs.

<Prior Art> In recent years, data processing devices for personal use such as personal computers and pocket computers have been developed and are rapidly becoming widespread, leading to an era in which each person has one device. Large business establishments are often equipped with as many data processing devices as there are employees, and in order to make effective use of these data processing devices, data transmission between devices or printers is required.

There is a growing need for a data transmission system that allows people to share a desk or the like.

However, in conventional data transmission systems of this type, the number of connected terminals is limited (less than 1,000), and the total network distance is short (2 km).
(below)), which has the disadvantage that the scope of use (2) is limited.

OBJECTS OF THE INVENTION The present invention provides a system that eliminates the drawbacks of conventional data transmission systems and does not impose restrictions on terminal equipment or networks. That is, a network to which a large number of terminals can be connected is further coupled using a network coupling device,
To provide a data transmission system that is easily expandable and enables data transmission to an infinite number of terminals over an infinite distance in principle, by transmitting data using the same protocol over all networks.

<One Embodiment> FIG. 1 is a diagram showing a part of a network configuration example of the present invention. In the figure, 1 to 8 are transmission lines within the same network, and the transmission lines 1 to 8 include data processing devices (hereinafter simply referred to as terminals) such as personal computers and pocket computers that are determined depending on the installation location and convenience of use. )1
1 to 65 are connected. The transmission lines 1 to 8 are network coupling devices 120 to 560 (the number ijo is the transmission line i
It means that it is placed in a position that joins the words ``and'', ``ro'', and ``j''. ), and connects the terminals connected to each transmission path to each other.

The ends of the connection ends pulled out from the network coupling devices 170 and 580 are not shown in blocks, but it shows that this network is expanding further, and the number of terminals and the total network extension pressure [both increase virtually infinitely]. It can be inferred that this is possible.

Next, the operation of data transmission will be specifically explained using the above network configuration diagram. For ease of understanding, it is assumed that the addresses of all terminals and network coupling devices consist of 8 bits (1 byte).

When transmitting data, a transmission packet is sent from the transmitting side, and the address section provided in the transmission packet (P) contains address information for controlling the data passage route. The value of the number of bytes in the address field minus 1 is always written in the first byte A+, and the value of the number of bytes minus 1 in the second byte A2 is the terminal connected to the transmission line from which the transmission packet is sent and which should receive the next Q data. Alternatively, the address of the network coupling device is written, and from the 3rd byte onwards, the address of the route through which the data should pass is written, and the information is rearranged between each byte so that the 11th to 3rd bytes have the above relationship. executed.

First, terminal 11 installed on the same transmission path, for example, transmission path l.
Let us consider the case where data is transmitted from to the terminal 17. Figure 2 shows the address part of the transmission packet (P) for the above data transmission operation, and shows the first 3 bytes A1 to A of the transmission packet.
3 is occupied by the address section, and a value of (the number of bytes of the address section - 1), that is, 3-1=2, is written in the first byte Al. The second byte A2 is the address to which data should be sent next.

In this case, "7" is written as the receiving terminal address because the seventh terminal 17 is targeted in this data transmission operation.Furthermore, the third bye 1-A3 is the transmitting terminal address, and "7" is written as the target terminal 17 in this data transmission operation. address 1 of terminal 11 is written.

When the transmission packet P having the above address information is output from the terminal 11 to the transmission path 1, all the terminals 12 to 17 . All network coupling devices 120, 17
0 detects the second byte A2 of the address field of the transmission packet 7) P in which address information to be sent next is written and checks whether it is addressed to itself. The device you have confirmed is addressed to you (in this case, device 17) (
and receives the transmission packet on transmission path 1.

Next, a different transmission path 9, for example, a terminal 1 installed on transmission path 1
A case will be described in which data is transmitted from terminal 1 to terminal 64 installed on transmission path 6. In this case, the terminals and network coupling devices that pass along the route from terminal 11 to terminal 64 are 11-120-240-450-. 560
-・64. Address of all terminals 1]
, II, the address of the fourth terminal 64 on the transmission line 6 is 4'', the address of the network coupling device 120 between the transmission lines is ``11'', and the address of the coupling device 240 is ``113''. #, the address of the coupling device 450'
11”.

And the address of the coupling device 560 is ``13''.

When allocating addresses, if the connected transmission paths are different, even if the same address information is set, the terminal and network coupling device belonging to the other transmission path will not receive the same address information.

When the addresses are determined as above, each address as seen from the data transmission direction is 1-11-13-11-13.
-4. FIG. 3(a) shows the address part of the transmission packet P sent by the terminal 11 to the transmission path 1. 1st byte A
1 is the value of address part byte number - 1 (8 - 1) 117 L
' is set. The second byte indicates the address of the terminal or network coupling device that should take in the transmission data on the transmission path on which the transmission packet currently exists; in this case, address 11 of the network coupling device 120 is set. In the third byte A3 to the eighth byte A8, the addresses of the terminals and network coupling devices through which the data has already passed and the terminals and network coupling devices to which the data should pass are arranged in the order of passage. The sending terminal 11 that sent the data is written. In the fourth byte A4, 0" is written as a mark to facilitate the rearrangement of the next address information. In other words, from the original writing order of address information, ft is the network that should receive the transmission packet on the transmission path. Write 0'' or -4h only to the byte that contains the address of the coupling device.

FIG. 3(a) shows the signal 1- sent from the terminal 11 to the transmission path 1.
Indicates the address part of the transmission packet at the moment when the address 11 is written in the second byte A2, the address 1 of the sending terminal is written in the third byte A3''!, 'FL1, the fourth byte A4 is written in the following order: A network coupling device 240 connected to the other transmission line 2 of the network coupling device 11 located at
Where the address of ``0'' should be inserted, this part contains
``Address is written, and address information according to the connection direction is written sequentially from the fifth byte A5 onward.

In the transmission packet addressing method described above, each terminal and coupling device does not check only whether or not its own address is in the second byte A2 of the address field of the incoming transmission packet; The information entered in the remaining address field tells where to send the message.

Now, as shown in Figure 3(a), the address is 7.11, 1°0.
When a transmission packet with 13.4 set is sent from the terminal 11 to the transmission path 1, all the terminals 12 to 17. All network coupling devices 120 and 170 detect the second byte A2 of the address field and check whether it is addressed to them. The terminal that has confirmed that it is addressed to itself, in this case, /) work coupling device 120 captures the transmission packet being sent.

The network coupling device 120 is shown in FIG. 3(a).
The transmission packet is sent to the transmission path 2 with only the address part changed as shown in FIG. 3(b). That is, the own address ``11'' in the second byte A2 is changed to the fourth byte A4, where the address ``0'' was input at the stage of FIG. 3(a).
At the same time, input the value 1113n inputted in the 5th byte A5, which is the next byte where the ``0'' address is input, to the 2nd byte A2. , instead, the fifth pilot A5 is newly set to the address "0".

The transmission packet u shown in FIG. 3(b) sent from the network coupling device 120 to the transmission path 2, all the terminals and the coupling device connected to the transmission path 2 read the address field in the same manner as in the operation on the transmission path 1. Detects the second byte of and checks whether it is addressed to you. In this case network coupling device 2
After confirming that 40 is addressed to him, he takes in the transmission buff 1-. Similarly to what the network coupling device 120 did, the network coupling device 240 transfers the transmission packet (b) in which the ``0'' address is set to the fifth byte to the second byte and the transmission packet (c). 5th゜6th
The byte number is changed and sent to the transmission path 4.

Similarly, the network coupling device 450 takes in the transmission packet (c), changes it and sends it to the next stage transmission path 5, and then the network coupling device 560 takes in the transmission packet (c) and sends it to the next stage transmission path 5. d), converts it into transmission packet (e), and sends it to the network 6. The transmission packet (e) is received by the terminal 64,
This completes data transmission from the terminal 11 to the terminal 64.

Figure 4 shows each transmission path 1, 2゜4.5, on the data transmission path.
6 and 1 timing of the above transmission packet occurring at 6 pm is not shown.

The characteristics of the transmission packets shown in FIGS. 3(a) to 3(e) are that in all packets, the order of the address part is only changed, and there is no change in the packet size; ), the sender is included in the address part, and it is possible to reply by simply reversing the order. In addition, the address allocation for each terminal may be such that it can be identified only within the same transmission path, and the address allocation for each network coupling device may be such that it can be identified only within the two transmission paths to which it is connected. Therefore, there is a large degree of freedom in address assignment, and the number of address bits may be small.

Also, - methods of simultaneous broadcast transmission and group broadcast transmission are shown.

Here, - Simultaneous broadcast transmission means transmission from one terminal to all terminals connected to all transmission paths, and group broadcast transmission means transmission from one terminal to a certain group, for example, that transmission path. Terminals with internal disks, terminals with disks,
This means sending to a group of terminals with printers, etc.
In either case, the transmitting terminal sends a transmission packet only once, and the designated terminal receives all of it. FIG. 5 shows the transmission packet.

By setting the address field to a fixed number of bytes and using a pattern that does not appear in a packet in a one-to-one transmission operation in the first byte, broadcast communication is executed. In other words, in the case of one-to-one transmission, the first byte of the address field indicates the number of bytes in the address field, so in the case of a broadcast communication packet, by using 0 or a very large value (for example, 128 or more), both transmission packets can be can be distinguished. However, the terminal.

The network coupling device is previously provided with a function of recognizing whether a transmission packet is a broadcast communication packet based on the first byte of the address section of the transmission packet and determining whether or not it should capture it.

Effects> The feature of the present invention is that, first, addresses need only be different within the same transmission path, so there is a large degree of freedom in allocating addresses. Furthermore, even if the number and distance of terminals connected to one transmission path are limited, there is no limit to these in Zen-no-dowork. As a network access method, any method that does not require a master station is acceptable.C3MA
(carrier sense multiple access) method, token method, etc., and the same method can be used on all networks.

Therefore, the present invention provides a data transmission system that can be configured with two types of modules, that is, terminals and network coupling devices, has a high degree of freedom and expandability in network configuration, and has no restrictions on the maximum number of terminals or distance. I can do it.

[Brief explanation of drawings]

Fig. 1 is a block diagram of a network for explaining an embodiment of the present invention, Fig. 2 is a diagram showing the main parts of the transmission process, and Figs. Figure 4 is a timing chart of transmission operation.
The figure is a diagram showing transmission packets for explaining other operating states. 1 to 8: Transmission line 11 to 65: Terminal 120°170.
230, 240, 450. 560, 580: Network coupling device P: Transmission node A/near address section

Claims (1)

[Claims] 1) A transmission line in which a plurality of data transmission devices are connected,
It is connected through a coupling means and sent to the transmission packet.
In a data transmission system in which address information is set for reception, all address information 4 of the data passing position is preset 1-2 in the address field of the transmission packet.
In the process of data passing sequentially along the transmission path according to the address information, the information in the address section is rearranged so that the address information of the next position to be sent is always at a predetermined position on the transmission packet. A data transmission system characterized in that the data transmission device and the coupling means check the address of the predetermined position and perform a check operation for data import.