JPH07297817A - Data transmission system - Google Patents

Abstract

PURPOSE:To provide a data transmission system which is tolerant to error generated by data transmission and improves the secrecy of data. CONSTITUTION:A transmission side 10 is provided with a storage part 13 where data is stored, an address generation part 12 which generates an address with a PN code, an encoding part 14 which encodes input data into a PN code and stores it in the storage part 13 in order and reads out data by the address of the address generation part 12 after the end of storage of all data, and a radio transmission part 15 which transmits read data to a data transmission line, and a reception side 20 is provided with an address generation part 22 and a storage part 23 having the same functions as the address generation part 12 and the storage part 13, a radio reception part 21 which receives the signal of the data transmission line and outputs reception data, and a decoding part 24 which stores reception data in the storage part 23 in accordance with the address of the address generation part 22 and reacts out data in order after the end of storage of all data and decodes an error correction code to output the data.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmission system which is highly resistant to errors in data transmission and has confidentiality.

[0002]

2. Description of the Related Art A data transmission system for transmitting data with error resistance and confidentiality is used, for example, for wireless data transmission.

In data transmission by radio, burst errors are likely to occur in the data to be transmitted, so that it is required to be robust against errors. Further, since the data is transmitted wirelessly, there is a possibility that the third party receives the radio wave and the transmitted data is used. For this reason, confidentiality is required for data transmission.

A data transmission device which is highly error-resistant and confidential during data transmission is disclosed in Japanese Patent Application Laid-Open No. 3-295365. Since this data transmission device performs error correction coding of data to be transmitted during data transmission,
Strong against mistakes. Further, since this data transmission device transmits the data of each data block that has been subjected to error correction coding for each fixed bit, it is possible to perform confidential data transmission.

[0005]

By the way, in the above-mentioned data transmission apparatus, the confidential communication is carried out by a simple method of transmitting the data of each data block for every fixed bit. However, in the method of transmitting the data of each data block in constant bits, when the third party receives this data, the data may be analyzed and the reliability of confidentiality is low.

An object of the present invention is to eliminate the above drawbacks and to provide a data transmission system which is resistant to errors caused by data transmission and which can improve the confidentiality of data.

[0007]

In order to achieve the object of the present invention, in a data transmission system in which a transmission side is connected to a reception side by a data transmission line for transmitting data, the transmission side stores data. When the storage unit on the transmission side, the address generation unit on the transmission side that generates an address by a pseudo-noise code, and the error correction coding of the input data are stored in the storage unit on the transmission side in order, and storage of all data is completed An encoding unit that reads the data in the transmitting-side storage unit according to the address from the transmitting-side address generating unit and a transmitting unit that transmits the data read by the encoding unit to the data transmission path.

The receiving side receives and receives a signal from the receiving side storing section for storing data, the receiving side address generating section for generating the same address as the address generated by the transmitting side address generating section, and the signal from the data transmission path. The receiving section that outputs data and the received data from the receiving section are stored in the receiving side storage section according to the address from the receiving side address generating section, and when all the data are stored, they are stored in the receiving side storage section. A decoding unit that sequentially reads data, performs error correction decoding, and outputs the data.

[0009]

With this configuration, the coding unit on the transmission side performs error correction coding on the input data and sequentially stores the data in the storage unit on the transmission side. After this, the encoding unit, according to the address by the pseudo-noise code generated by the transmission side address generation unit,
Reads the data from the sender storage. As a result, data interleaving is performed on the transmitting side.

The receiving side decoding section stores the received data in the receiving side storage section according to the address generated by the receiving side address generating section. After that, the decoding unit sequentially reads the data stored in the reception side storage unit and outputs the error-correction-decoded data. At this time, since the receiving side address generating section generates the same address as the transmitting side address generating section, the decoding section outputs the same data as the data input to the transmitting side. As a result, deinterleaving is performed on the receiving side.

[0011]

Embodiments of the present invention will now be described with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of the present invention. In this data transmission method, the transmission side 10 is connected to the reception side 20 by a wireless data transmission line for transmitting data.

In this data transmission system, the transmitting side 10 is
An input unit 11, an address generation unit 12 as a transmission side address generation unit, a storage unit 13 as a transmission side storage unit, an encoding unit 14, and a wireless transmission unit 15 as a transmission unit are provided. The reception side 20 includes a wireless reception section 21 as a reception section, an address generation section 22 as a reception side address generation section, a storage section 23 as a reception side storage section, a decoding section 24, and an output section 25.

The input unit 11 of the transmission side 10 is connected to a data terminal (not shown) or the like, and sends the data received from the data terminal or the like to the encoding unit 14.

The storage unit 13 stores the data from the encoding unit 14. The storage unit 13 has a storage area 100 as shown in FIG. 3, and the storage area 100 is divided into a row direction and a column direction. The storage area 100 has a plurality of storage area elements due to this division.

Further, a row address and a column address are given in the row direction and the column direction of the storage area 100.
In FIG. 3, 1, 2, 3, 4, 5, 6, 7 are given as row addresses. Moreover, 1, 2, 3, 4, 5, ..., N are given as column addresses. By the address indicated by these row address and column address, for example, the storage area element 101 is
The storage area element 102 is represented as (1, 1), and (1, 1)
2). When the byte unit data is input from the encoding unit 14, the storage unit 13 is represented by (1,1), (1,2), (1,3), ..., (7, n). Data is sequentially stored in the storage area element.

The address generator 12 generates an address for reading data from the memory 13.

An example of the address generator 12 is shown in FIG.
The address generator 12 includes a PN code generator 31 including an EX / OR circuit 31A and a shift register 31B.
Generates a PN code (Pseudo Noise Code). The shift register 31B is a three-stage shift register, and the output value is fed back by the EX / OR circuit 31A. The initial value of the shift register 31B is "1.
11 ", the shift register 31B sequentially generates the following values.

"111", "011", "101",
“010”, “001”, “100”, “110” These values are sent to the weighting circuit 32.

When the weighting circuit 32 receives a value of "011" from the shift register 31B, for example, it weights each value "0", "1", "1". That is, “0” → “0 × 2 ² ”, “1” → “1 × 2 ¹ ”, “1” →
For example, “1 × 2 ⁰ ”.

The adder circuit 33 adds "0x2 ² ", "1x2 ¹ ", and "1x2 ⁰ " output from the weighting circuit 32, and adds "0x2 ² + 1x2 ¹ +1". X2 ⁰ "is output. The value "3" indicated by this becomes the row address. Therefore, "111", "011", "101", "010" generated by the PN code generation circuit 31
The row addresses corresponding to “001”, “100” and “110” are “7”, “3”, “5”, “2”, “1”, “4”,
It becomes "6". That is, the row address changes in this order. This row address is output to the encoding unit 14.

In the decision circuit 34, the value of the row address is "6".
It is determined whether or not. This “6” is the last address among the seven addresses output by the adder circuit 33. The determination circuit 34 determines that the row address value is “6”.
Then, the signal "1 (active)" is output to the EN terminal of the counter 35.

The counter 35 has a row address value of "6".
EN terminal is enabled each time. This allows
The counter 35 counts up and sequentially outputs the values of "1", "2", "3", "4", ..., "N". This value is output to the encoding unit 14 as a column address.

The address generator 12 of FIG. 2 thus generates the row address and the column address.

The encoding unit 14 converts the data from the input unit 11 into an RS (Reed-Solomon) code for error correction in byte units, and performs error correction encoding. After that, the encoding unit 14 outputs the error-correction-encoded data to the storage unit 13 in units of bytes.

The encoding unit 14 reads the data from the storage unit 13 using the address generated by the address generation unit 12. The encoding unit 14 receives “7”, “3”, “5”, “2”, “1”, “4”, as a row address from the address generation unit 12.
Receives a value of "6". Further, the values of "1", "2", "3", "4", ..., "N" are received as column addresses. This column address is incremented by "1" when the row address becomes "6". As a result,
The addresses received by the encoding unit 14 are (7,1), (3,1), (5,1), (2,1),
(1,1), (4,1), (6,1) (7,2), (3,2), (5,2), (2,2),
(1,2), (4,2) (6,2) ... (7, n), (3, n), (5, n), (2, n),
(1, n), (4, n), (6, n). The encoding unit 14 reads out data in bit units from the storage area element of the storage unit 13 indicated by these addresses and sends the data to the wireless transmission unit 15.

The wireless transmitter 15 modulates the data from the encoder 14 and wirelessly transmits it to the receiver 20.

The radio receiving section 21 of the receiving side 20 is
A signal transmitted by radio waves from 0 is demodulated to generate reception data, and the reception data is output to the decoding unit 24.

The address generating unit 22 is similar to the address generating unit 12 of the transmitting side 10, and the storage unit 23 is the transmitting side 1
It is the same as the storage unit 13 of 0.

Upon receiving the data from the wireless reception section 21, the decoding section 24 stores the data in the storage section 23 according to the address generated by the address generation section 22. The decoding unit 24 stores all the data from the wireless reception unit 21 in the storage unit 2.
When the data is stored in No. 3, the data is sequentially read from the storage unit 23. Then, error correction decoding of the read data is performed,
The decrypted data is output to the output unit 25.

The output unit 25 is a data terminal (not shown).
The data from the decoding unit 24 is sent to a data terminal or the like.

Next, the operation of this embodiment will be described.

When transmitting data, the input unit 11 of the transmission side 10 sends the data received from a data terminal (not shown) or the like to the encoding unit 14. The encoding unit 14 converts the data from the input unit 11 into an RS code and performs error correction encoding. After that, the encoding unit 14 outputs the encoded data to the storage unit 13 in units of bytes.

The storage unit 13 stores the byte-unit data from the encoding unit 14 as (1,1), (1,2), (1,3), ..., (7, n). The area elements are stored in order. That is, the storage unit 13 stores the byte-unit data in the storage area element in the order shown by the broken line in FIG.

When all the data from the input unit 11 is stored in the storage unit 13, the encoding unit 14 reads the data from the storage unit 13. At this time, the encoding unit 14 causes the addresses (7,1), (3,1), (5,1), (2,1),
(1,1), (4,1), (6,1) ... (7, n), (3, n), (5, n), (2, n),
Data is read according to (1, n), (4, n), (6, n). That is, the encoding unit 14
Data is read from the storage area elements of the storage area 100 in the order of the parenthesized numbers in FIG.

The wireless transmitter 15 modulates the data read by the encoder 14 and sends the modulated data to the receiver 20.

The radio receiving section 21 of the receiving side 20 is
A signal transmitted by a radio wave from 0 is demodulated to generate received data.

Upon receiving the reception data from the radio reception unit 21, the decoding unit 24 stores the data in the storage unit 23 according to the address generated by the address generation unit 22.
That is, the decoding unit 24 stores the storage area 1 in the order shown in FIG.
00 to store the data.

When the storage of all data is completed, the decoding section 24 reads the data from the storage section 23 in order. That is, the decryption unit 24 reads data from the storage area 100 in the order shown in FIG. After that, the decoding unit 24 performs error correction decoding of the read data. At the time of this decoding, the decoding unit 24 corrects the error generated in the data transmission. The output unit 25 sends the data from the decoding unit 24 to a terminal (not shown) or the like.

As described above, according to this embodiment, when an error occurs in data transmission, the receiving side 20 can correct this error.

On the transmitting side 10, the address generator 1
Since the data is read from the storage unit 13 and transmitted by the address generated by 2, interleaving can be performed. Further, on the transmitting side 10, since data is stored in the storage unit 23 according to the address generated by the address generation unit 22, deinterleaving can be performed. This enables confidential communication.

Since the address used at this time is created using the PN code, it is difficult to analyze the data even when the third party receives the radio wave. As a result, the reliability of confidential communication can be improved.

Further, in this confidential communication, the transmitting side 1
0 and the receiving side 20, the address generating units 12 and 22 for generating the address by the PN code, and the storage units 13 and 23.
Since only and are required, the configuration of the device can be simplified.

In this embodiment, the PN code is used when the address is generated, but it is not limited to this. For example, other PN such as Gold code
You may use the code | symbol of a series.

Although the number of row addresses is seven in this embodiment, it is not limited to this.

Further, in this embodiment, the storage unit 13 is
Although the data is stored in the storage area element of the storage area 100 in byte units, the present invention is not limited to this. For example, when a BCH code that corrects an error on a bit-by-bit basis is used as the error correction code of the encoding unit 14, the storage unit 2
Data is stored bit by bit in the storage area element 3 of FIG. The same applies to the receiving side 20.

[0047]

As described above, according to the present invention,
The coding unit on the transmission side performs error correction coding on the input data, stores the data in the storage unit on the transmission side, and further reads the data in the storage unit on the transmission side according to the address based on the pseudo noise code. As a result, interleaving is performed on the transmitting side. Further, the decoding unit on the reception side stores the data in the storage unit on the reception side using the same address as the address on the transmission side, and then sequentially reads the stored data. Then, this data is subjected to error correction decoding and output. As a result, deinterleaving is performed on the receiving side.

As a result, when an error occurs in data transmission, this error can be corrected, and since the address based on the pseudo noise code is used, stronger confidential communication is enabled as compared with the conventional one. Moreover, since the address based on the pseudo noise code is used, only the sender side address generator and the receiver side address generator are required on the transmitter side, so that the configuration of the device can be simplified.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention.

FIG. 2 is a block diagram showing an example of an address generator.

FIG. 3 is a diagram showing a storage unit.

FIG. 4 is a diagram showing a state of storage in a storage unit.

FIG. 5 is a diagram showing a state of reading from a storage unit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 transmission side 12 address generation part 13 storage part 14 encoding part 15 wireless transmission part 20 reception side 21 wireless reception part 22 generation part 23 storage part 24 decoding part

Claims (1)

[Claims] 1. In a data transmission method in which a transmission side is connected to a reception side by a data transmission path for transmitting data, the transmission side stores a data on the transmission side and a transmission for generating an address by a pseudo noise code. The side address generator and the input data are error-correction-encoded and stored in the transmitter storage in order, and when all the data is stored, the sender storage unit stores the data according to the address from the transmitter address generator. It has a coding unit that reads data and a transmission unit that sends the data read by the coding unit to a data transmission path. The reception side includes a reception side storage unit that stores data and a transmission side address generation unit. Address generator that generates the same address as the address to be transmitted, a receiver that receives the signal from the data transmission path and outputs the received data, and a receiver device that receives the data from the receiver. Data in the receiving side storage unit according to the address from the receiving side address generation unit, and when all the data is stored, the data stored in the receiving side storage unit is read in order, error-correction-decoded and output. And a decoding unit for performing the data transmission.