JPH07110003B2 - Data communication method - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a data communication system, and particularly to data communication capable of continuously transmitting data at high speed up to the upper limit of the communication speed of a communication line. Regarding the scheme.

[Conventional technology]

As a conventional technique related to the data communication system, for example, a technique described in Japanese Industrial Standard JIS-C6362 (basic procedure) is known. This data communication method is performed in the asynchronous or SYN synchronization procedure.When either the central station or the terminal station transmits data, the receiving station returns the response of the reception result and the transmitting station. Receives the response of this reception result, and if the response is negative, retransmits the same data again.

Further, as another conventional technique, for example, Japanese Industrial Standard JIS
-The technique described in C6365 (HDLC procedure) is known. This conventional communication method can perform batch confirmation transmission using concatenated frames, but it is necessary to retransmit the data even if a one-bit loss failure occurs during transmission of the data on the line. It was what was decided.

FIG. 4 is a diagram for explaining a conventional data communication system as described above. In FIG. 4, 2 is a negative acknowledgment signal, and 3 and 6 are positive acknowledgment signals.

The example of the prior art shown in FIG. 4 is an example of sending data from a central station to a terminal station. In this example, the central office
For example, if you send 256 bytes of record data 1,
Has a response from the terminal station, and this response signal is a negative corresponding signal
When it is NAK2, when the same record data 1 is transmitted again and the acknowledgment signal ACK3 or ACK6 is received,
The following data 2 and data 3 can be transmitted.

In such a conventional technique, once the negative acknowledgment signal NA
The time required for T ₁ is required for the terminal station to correctly receive the transmission data 1 that received K2, and the time required for T ₂ is required even when an acknowledgment is returned by one transmission. That is, in the above-mentioned conventional technique, the time required to receive a response from the receiving station is required every time one record data is sent, and the communication circuit having a constant line speed is used to increase the time by several thousand times. No consideration was given to high-speed data transmission up to the upper limit of the line speed while ensuring the transmission quality.

[Problems to be Solved by the Invention]

In the former conventional technology in the above-mentioned conventional technology, when transmitting data from a transmitting station to a receiving station, the transmitting station receives an affirmative or negative response from the receiving station, and the next data is received in response to the positive response. Since the same data is transmitted again when the negative response is received, there is a problem that the transmission rate is significantly reduced due to the retransmission and the transmission rate is significantly reduced due to the response waiting.

Further, the latter conventional technology can perform high-speed data transmission because it can transmit data by concatenated frames, but in low-quality communication lines, retransmission of the same data due to negative acknowledgment increases, The transmission data rate is relatively low, and in order to transmit a large amount of data at high speed, a high quality and expensive line must be used.

An object of the present invention is to solve the above-mentioned problems of the prior art and to recover faulty data in the receiving side device, thereby enabling high quality data transmission even with a low quality line,
It is to provide a data communication system capable of continuously transmitting data up to the upper limit of the line speed.

[Means for Solving the Problems]

According to the present invention, the object is to add horizontal SUM data to n records of transmission data and vertical SUM data to record data of every n records of transmission data, and to receive by the receiving side device. If a failure is detected in the received data, the horizontal SUM data and the record data for which no failure is detected in the received data of n records are logically or arithmetically operated to recover the received data and restore it. The normality check of the received data is performed by performing logical operation or arithmetic operation on the received record data every n records and its vertical SUM data.

This eliminates the need for the receiving side device to send back a negative response even if there is an error in the received data, so the transmitting side control device continuously operates at the upper limit speed of the communication speed of the communication line. Data can be transmitted, and inexpensive and high-speed data transmission can be performed.

[Action]

The transmitting side device divides the data to be transmitted into record data of a predetermined size, successively transmits this record data as record data 1, record data 2, ..., And the number of this record data is predetermined. When the predetermined number n is reached, these record data 1 to n are regarded as one data block, and the operation of transmitting the horizontal SUM data by performing the calculation for each bit of the record data in this block is the data to be transmitted. Until each bit of n pieces of record data of these record data is calculated and n pieces of vertical SUM data are transmitted, and then each bit of n pieces of vertical SUM data is calculated. The vertical and horizontal SUM data, which has been calculated or calculated for each bit of the horizontal SUM data, is transmitted, and the series of data transmission is completed. The receiving device receives these series of data, performs an error check for each record data, and if there is a failure in the data, all other records except the relevant data in the data block containing the relevant record data. Next to the data and its data block
The SUM data is calculated for each bit, and the received record data with the failure is recovered. The recovered data is the record data in the same position of the plurality of data blocks and the vertical data created based on these data.
It is possible to confirm this with the SUM data.

This eliminates the need for the receiving side device to make a retransmission request to the transmitting side device, and the transmitting side device can continuously send record data to be transmitted at high speed.

〔Example〕

An embodiment of a data communication system according to the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a diagram for explaining the order of record data strings of data to be transmitted according to an embodiment of the present invention, and FIG. 2 is a diagram for explaining the relationship between transmitted record data and horizontal SUM data, vertical SUM data, and vertical and horizontal SUM data. FIG. 3 and FIG. 3 are flow charts for explaining the transmission operation.

The example shown in FIG. 1 shows an example in which data is transmitted from the central device to the terminal device.

In this example, the central device on the transmission side sequentially divides the data to be transmitted into record data with a length of 256 bytes,
When this record data is successively transmitted and the number of record data is transmitted by a predetermined number n, 26 in this example, this is regarded as one data block, and horizontal SUM data for these 26 record data is performed, This lateral SUM data is transmitted. After that, the central unit similarly transmits the record data and the SUM data until there is no transmission data, and finally performs the vertical SUM data for the data block and transmits the obtained 26 vertical SUM data. Then, the horizontal and vertical SUs are performed for these vertical SUM data.
M Send data and finish sending all data. The central device transmits a POLL signal requesting a response from the terminal device since it has finished transmitting all the data. The terminal device is
This request from the central unit sends a completion code indicating the completion of data reception, and the central unit thereby sends an EOT signal to end the transmission of a series of data.

Next, generation of horizontal SUM data, vertical SUM data and vertical / horizontal SUM data and failure recovery of record data on the receiving device side using these SUM data will be described with reference to FIG.

Generation of transmission data a) 256-byte record data 1 that can be checked by CRC
~ Exclusive OR is performed for each bit of the record data 26 to generate a horizontal SUM1 having a length of 256 bytes, and a data block 1 is generated by these 26 record data and the horizontal SUM1 data.

b) Similarly, for all 26 data items to be transmitted, horizontal SUM2 to horizontal SUMm + 1 are generated and data block 2 to data block m + 1 are generated.

c) Record data 1,2 with a distance of 26 record data
Exclusive-OR each bit of 7,53, ... 26m + 1 to generate a vertical SUM1 of 256 bytes.

d) Similarly, vertical SUM2 to vertical SUM26 are generated.

e) An exclusive OR operation is performed on each bit of horizontal SUM1, horizontal SUM2, ..., Horizontal SUMm + 1 to generate vertical and horizontal SUM.

The transmission data thus generated is transmitted to the receiving side in the order described in FIG.

Check of received data and recovery method a) The received data can be CRC checked for each record data, but in this embodiment, one record data in one data block is lost. In that case, the record data can be recovered. For example, when the record data 2 in the data block 1 shown in FIG. 2 is lost, the receiving side apparatus excludes the record data 2, exclusive of the record data 1, the record data 3 to the record data 26, and the horizontal SUM1. The record data 2 can be recovered by performing the logical sum. This check of the recovered record data 2 is performed by exclusive ORing the record data 28,54, ... 26m + 2 having the distance of the recovered record data 2,26 record data and the vertical SUM2. , All “0”, it can be done by assuming that the recovery is correct.

Therefore, in this case, the loss of one record data per one data block can be recovered by using the horizontal SUM and the recovery can be performed by using the vertical SUM. Therefore, there is one record data loss in each data block. In this case, record data can be recovered.

b) In the embodiment of the present invention, even when a plurality of record data in one data block are lost, the record data can be recovered. For example, when all the record data 1 to record data 26 in the data block 1 are lost, the record data 1 is
Record data 27 …… Record data 26m + 1 and vertical SUM
It is possible to recover by performing an exclusive OR of 1. Similarly, the record data 2 to the record data 26 have vertical SUM2 to
It is possible to recover by performing the exclusive OR of the vertical SUM 26 and the record data other than the lost record data used for obtaining these vertical SUMs.

In the record data 1 to record data 26 thus recovered, the exclusive OR of the horizontal SUM1 is performed with these record data, and the result becomes all “0”, so that all the record data are correct. You can check that you have been recovered.

Therefore, in this case, the loss of consecutive record data is
Up to 26 can be recovered.

As described above, one embodiment of the present invention can continuously transmit all data to be transmitted without waiting for a response from the receiving side. The operation of the transmission side device that performs such transmission is shown in the flow chart of FIG. 3, which will be described below.

(1) The data to be transmitted is divided into record data units each having a length of 256 bytes, and n pieces (n = 26 in the illustrated example) of this record data are generated as one data block (step 20).

(2) The value of the control counter is set to "0", the horizontal SUM data for the first data block is calculated, and n or 26 record data and the horizontal SUM data are transmitted (steps 21 and 22). ).

(3) Check whether all the data to be transmitted have been transmitted. If the data transmission has not been completed, the control counter is incremented by 1 and the above steps 21 and 22 are repeated to transmit the data. The horizontal SUM of the data block is calculated and the data block is transmitted (step 23, step 21, 22).

(4) In step 23, if the transmission signals of all the data to be transmitted have been completed, the control counter is set to "0", the first vertical SUM data is calculated, and the value of the control counter is incremented by 1, n vertical SAM data, that is, 26 vertical SAM data are calculated, and the calculated vertical SUM data is transmitted.
Calculate the vertical and horizontal data for UM data
Data is transmitted (steps 24 to 26).

According to the present invention, it is possible to perform error recovery on the receiving side by performing the above-described transmission operation. When one embodiment of the present invention is applied to, for example, a data communication system using a line of 9600 BPS, the one embodiment of the present invention is applicable to a time value corresponding to a maximum of 6656 bytes and a line failure of about 7 seconds. The data in the meantime can be recovered by the receiving device, and high-reliability and high-quality data transmission can be performed using a low-quality line. In addition, in one embodiment of the present invention, the total time of waiting times for acknowledgments according to the prior art is the vertical SUM according to the present invention.
If the data and the horizontal SUM data are transmitted for a long time, high-speed data can be transmitted by continuously transmitting the data. For example, in the case of transmitting 512 Kbytes of data using the above-mentioned line, in the case of the prior art, it took 17 minutes for the transmission time, whereas in one embodiment of the present invention,
With only a transmission time of 11 minutes, one embodiment of the present invention is
It was possible to transmit data at a speed of about 1.54 times that of the conventional technique.

In the above-described embodiment of the present invention, the exclusive OR operation is used to calculate the horizontal SUM data, the vertical SUM data, and the vertical / horizontal SUM data. However, the present invention uses other logical operations or addition, subtraction, and multiplication. , It is also possible to use arithmetic operations such as division, and in this case as well, similar effects can be obtained.

〔The invention's effect〕

As described above, according to the present invention, it is possible to recover the data that has become a failure in the receiving side device, to perform high-quality data transmission, and to receive data units from the receiving side device. Since it is possible to continuously transmit all the data to be transmitted without having a response of 1, the transmission speed can be increased up to the upper limit of the communication line to be used, and the data can be transmitted at high speed.

[Brief description of drawings]

FIG. 1 is a diagram for explaining data transmission according to an embodiment of the present invention, and FIG. 2 is a transmission record data, horizontal SUM data,
FIG. 3 is a diagram for explaining the relationship between vertical SUM data and vertical and horizontal SUM data, FIG. 3 is a flow chart for explaining the transmission operation, and FIG. 1 ... Negative response signal, 3,6 ... Positive response signal.

Claims (3)

[Claims] 1. In a data communication method performed between a transmission side device and a reception side device via a communication line, the transmission side device performs error detection coding on each of the data to be transmitted, This error detection coded data to be transmitted is calculated, and the result is calculated as SUM.
A data block added as data is generated, and the data block is continuously transmitted to the reception side device without waiting for a response from the reception side, and the reception side device detects an error in each of the received data. When a code check is performed and a failure is detected, all data in that data block and the SUM data in that data block, excluding the data that became the failure, are not retransmitted by the device on the sending side. A data communication method characterized by recovering a failed data and then recovering an erroneous data block by performing a calculation. 2. The transmission side device uses horizontal SUM data as SUM data of data blocks to be continuously transmitted to the reception side device, and data at the same position and horizontal SUM data of each data in a plurality of data blocks. For the vertical S
It is characterized in that a data block based on UM data is generated and transmitted to the reception side device, and the reception side device confirms the normality of the recovered data block using the vertical SUM data. The data communication method described in the first item of the range. 3. The data communication system according to claim 1 or 2, wherein the operation is an exclusive OR of bits corresponding to each data.