JPH07112158B2 - Data transmission method - Google Patents

Description

The present invention relates to a data transmission method suitable for use in the case of transmitting data via a storage device such as a magneto-optical disk.

[Outline of Invention]

According to the present invention, an error detection code or an error correction code is generated and added to one direction of data that is two-dimensionally arranged with a predetermined number of data as a unit, and the predetermined number of data is n units (n = 1, 2). (3, ...) In addition to the generation and addition of the error detection code or the error correction code for the above-mentioned one direction in each unit when transmitting, an error is caused in the other direction different from the above-mentioned one unit for the above n unit. By generating and adding a detection code or an error correction code and transmitting the data together with the above n units of data together with a synchronization signal, the data can be accessed in the minimum unit even when transmitting the data in the extended unit, and the hardware can be used. Both software and software can facilitate compatibility between minimum unit data transmission and extended unit data transmission, and in any case, error detection and error It is obtained to be able to perform a good transmission by performing correction.

[Conventional technology]

There is a magneto-optical disk as a storage device for data storage of a computer.

As shown in FIG. 2, this magneto-optical disk (1) has data recorded as one track (2) per rotation, with concentric or spiral tracks formed and recorded, and reproduced from this. To be done.

One track (2) of the magneto-optical disk (1) is composed of a plurality of sectors equally divided in the circumferential direction, and an error correction code, an error detection code, etc. are added to a predetermined number of data in each sector. Is added and recorded.

In the case of FIG. 2, one track consists of (n + 1) sectors, and the format of the data recorded in one sector is as shown in FIG. That is, one sector includes a header part, a data part, a header part, and a gap part GAP provided after and after the data part.

A preamble signal is recorded at the beginning of the header part, and an address synchronization signal ASYNC is added to an address signal ADD consisting of a track address TA and a sector address SA to which an error correction code ECC is added. Has been recorded twice.

Further, in the data part, a preamble signal is recorded at the head thereof, and thereafter, data and data to which an error correction code ECC or the like is added are recorded.

By the way, the unit data amount to be recorded in the data section of one sector, when used as a storage device of a computer,
It is usually 512 bytes, but it can be extended to double that 1K.
There are also cases where the number of bytes is doubled to 2K bytes, 4K bytes, etc.

Assuming that the number of revolutions and the bit clock frequency of the disk (1) do not change, if one track consists of 32 sectors with 512 bytes, 1 sector of 1 Kbyte per track is 1/2 of that, and 1 sector of 2 Kbyte is 1 of that. It will consist of 2 sectors, 8 sectors.

In this case, the structure of the data part is as shown in FIG.

That is, in the case of FIG. 3, the number of data is 51 from D _{0 to} D _511.
In the case of 2 bytes, 12 bytes of information including a track number, a sector number, a block number, etc. are added in front of the 512-byte data as the actual data. Then, the CRC code for error detection generated for this total of 524 bytes of data is added for 4 bytes, and 33 × 1 as shown in the figure.
It can be arranged in a matrix with 6 bytes.

Then, the first error correction signal C ₁ (for example, (37,33) Reed-Solomon code) is added to 528 bytes including 4 bytes of this CRC code as 4 bytes for one row in the row direction. Similarly, 4 for each column in the column direction.
The second error correction code C ₂ of the byte (this is, for example, (20,1
6) Reed-Solomon code) is added.

In the figure, a synchronization signal (called a resync) indicating the beginning of each row is added to the beginning of each row in this example.

When the unit data amount is 1 Kbyte, information such as a sector number and a CRC code are generated and an error correction code is generated and added for the entire 1 Kbyte.

Similarly, even if the unit data amount is 2 Kbytes of data, a data structure similar to that of FIG. 3 is constructed for this 2 Kbytes of data.

[Problems to be solved by the invention]

As described above, conventionally, the data structure as shown in FIG. 3 is constructed for each unit data regardless of the amount of data, that is, the data size. Therefore, the error correction system and the data processing are designed to deal only with a specific data size, and compatibility between different data sizes is not considered, which is inconvenient.

[Means for solving problems]

According to the present invention, an error detection code or an error correction code is generated and added to one direction of data that is two-dimensionally arranged with a predetermined number of data as a unit, and the predetermined number of data is n units (n = 1, (2, 3, ...) In addition to the generation and addition of the error detection code or the error correction code for the one direction in each unit when transmitting, for the other units different from the one direction for the n units. An error detection code or an error correction code is generated and added, and is transmitted together with the data of n units together with a synchronization signal.

[Action]

According to the present invention, an error detection code or an error correction code is generated and added to one direction of data that is two-dimensionally arranged with a predetermined number of data as a unit, and the predetermined number of data is n units (n = 1, (2, 3, ...) In addition to the generation and addition of the error detection code or the error correction code for the one direction in each unit when transmitting, for the other units different from the one direction for the n units. By generating and adding an error detection code or an error correction code and transmitting the data together with the above n units of data together with a synchronization signal, the data can be accessed in the minimum unit even during the data transmission of the extended unit, and the hardware can be used. Both software and software can be easily compatible between the minimum unit data transmission and the extended unit data transmission, and error detection is possible in any case. It is possible to perform a good transmission by performing error correction.

〔Example〕

FIG. 1 shows an example in which a signal to be recorded in one sector of a magneto-optical disk is formed by using the method of the present invention.

That is, in this example, the data size 51 in FIG.
As with the case of 2 bytes, the sector of 512 bytes of data
A CRC code is generated and added to the data with the No., block No., etc., and the entire generated and added data is further added with the first error correction code C ₁ to form one data group A.

When recording with a size of 512 bytes per sector, just as in the case of FIG. 3, synchronization with the one in which the second error correction code C ₂ is generated and added for this one data group A as shown in FIG. A signal is added, and a header is further added for recording.

And when recording with 1 sector 1 Kbyte size,
Two data groups A are stacked as shown in the figure, and the stacked ones are used as a second error correction code (36,3
2) Generate and add Reed-Solomon code C ₂ ′. And
A sync signal is added to all of them, and a header portion is added to record them as one sector. In this case, 2 of 1 sector area in case of 512 bytes size
Data of 1 Kbyte size is recorded with one area as one sector.

When recording with 1 sector 2 Kbytes size, four data groups A are stacked, a (68,64) Reed-Solomon code is generated and added as a second error correction code for the stacked data, and a synchronization signal is generated for all of them. By adding and further adding a header part, recording is performed with four areas of one sector in the case of 512 byte size as one sector.

As described above, when the data size is expanded, a plurality of data groups A are stacked, and a sync signal is added to the stacked data groups so as to have a size of 1 sector. Based on the processing of byte data group A, there are many parts that can be shared by both hardware and software when the size is expanded, and it is easy to maintain compatibility even when the data (sector) size is different. Have.

In particular, if the format does not use the second error correction code C ₂ ′, the data processing means can be used in common for each sector size of 512 bytes, 1 Kbytes, 2 Kbytes ...

When the second error correction code C ₂ ′ is added as in the example of the figure, the second error correction code C ₂ ′ is added according to the size.
The correction circuit for C ₂ ′ is 512 bytes for (20,16) Reed-Solomon code, 1 Kbyte for (36,32) Reed-Solomon code, and 2 Kbytes for (68,64) Reed-Solomon code. In 4 Kbytes, it is sufficient to switch to (132,128) Reed-Solomon codes.

For that purpose, it is necessary to identify the data size. As an example of the identifying means, 2 to 3 bits of 1 byte of the sector address of the header part of 1 sector in FIG. 2 are used. The identification information indicating the data size in one sector is recorded, and when this is reproduced,
A method of extracting and determining can be considered. Various other methods can be considered as means for identification.

Although the present invention has been described above by taking the case where the magneto-optical disk is used as a transmission medium as an example, the present invention is not limited to this and can be applied to various other general data transmissions.

〔The invention's effect〕

According to the present invention, an error detection code or an error correction code is generated and added to one direction of two-dimensionally arranged data with a predetermined number of data as a unit, and the predetermined number of data is n units (n = 1). (2, 3, ...) In addition to the generation and addition of the error detection code or the error correction code for the one direction in each unit when transmitting, for the n units, other directions different from the one direction are targeted. By generating and adding an error detection code or an error correction code and transmitting it together with the above-mentioned n-unit data together with a synchronization signal, the data can be accessed in the minimum unit even during the data transmission in the extended unit, Both hardware and software make it easier to achieve compatibility between the minimum unit data transmission and the extended unit data transmission. The data can be accessed in the minimum unit, and both hardware and software can easily achieve compatibility between the minimum unit data transmission and the extension unit data transmission, and the two-dimensional arrangement is performed with a predetermined number of data as a unit. The error detection code or the error correction code can be generated and added by the same process even if the transmission amount may change in one direction of the data, and the error detection can be performed in the other direction of n unit data to be transmitted. Alternatively, an error correction code can be generated and added, whereby remarkable error correction capability can be exerted by detecting an error and correcting an error, and one of the two-dimensionally arranged data of n units of transmission data can be displayed. Even if the transmission amount is different for each direction, error detection or error correction processing is executed when a predetermined number of data arranged in this one direction is received. It is suitable for partially utilizing the received n-unit transmission data, and in this case, even if an error exceeding the error detection or error correction capability exists, the other direction is used. It is possible to improve the error detection or error correction capability by using the error detection or error correction code generated and added to, and perform good transmission.

[Brief description of drawings]

FIG. 1 is a diagram showing a data format for explaining the method of the present invention, FIG. 2 is a diagram showing a format of a magneto-optical disk and its sector, and FIG. 3 is an example of a conventional one-sector data structure. FIG. A is a data group in which an error correction code or the like is added to a predetermined number of data.

 ─────────────────────────────────────────────────── ─── Continuation of front page (56) Reference JP 62-171326 (JP, A) JP 59-101015 (JP, A) JP 52-128023 (JP, A) JP 56- 111957 (JP, A) JP 55-129913 (JP, A) JP 60-20363 (JP, A) JP 62-60174 (JP, A)

Claims (1)

[Claims] 1. An error detection code or an error correction code is generated and added to one direction of two-dimensionally arranged data with a predetermined number of data as a unit, and the predetermined number of data is n units (n = 1, n = 1, 2, 3, ...)
In addition to generating and adding an error detection code or an error correction code for the one direction in each unit when transmitting, an error detection code or an error correction code for another direction different from the one direction for the n unit Is added and transmitted together with the n units of data together with a synchronization signal.