KR910008505B1 - Optical disk - Google Patents

Abstract

No content.

Description

Optical disc

1 is a block diagram of an embodiment of an optical information recording and reproducing apparatus for recording and reproducing data on an optical disc of the present invention.

2 is a diagram of one embodiment of an optical disc format configuration of the present invention.

3 is a detailed block diagram of the block 15 of FIG.

4 is a first embodiment of the second error correcting code of the sector ECC area 20 of the RO optical disk of the present invention.

5 is a diagram showing an embodiment of another optical disk format configuration applied to the present invention.

Fig. 6 is a diagram of the first embodiment of the sector configuration of the RO optical disc of the present invention.

Fig. 7 is a diagram of a second embodiment of the sector structure of the RO optical disc of the present invention.

8 is a diagram of one embodiment of an inspection sector configuration of an optical disc.

9 is a diagram of one embodiment of an optical disc track configuration applied to the present invention.

10 is a diagram of one embodiment of an information sector (2) configuration of an optical disc to which the present invention is applied.

11 is a diagram of one embodiment of an inspection section 1 of an optical disc to which the present invention is applied.

12 to 16 show the operation pulley art of the control CPU 10 shown in FIG.

12 is an overview.

13 is a detection operation of a defective sector.

14 shows a recording operation for a WT disc.

Fig. 15 is a reproduction operation of data.

Fig. 16 is a flowchart illustrating each decoding operation of the second error correction detection code when the first error correction detection code cannot be corrected when decoding the first error correction detection code on the RO disk.

* Explanation of symbols for main parts of the drawings

1: optical disc 2: optical disc drive

3: controller 4: host CPU

5: System Interface 6: Random Access Memory

7: Error correction detection circuit 8: Data modulation demodulation circuit

9: Sector read / write control circuit 10: Control CPU

11: parity buffer 14: OR circuit

15: block 16: replacement area

17: blank area 18: data area

19: replacement / mapping area 20: sector ECC area

21: Data Sector 22: Inspection Sector

23 sector replacement / mapping area 24 sector ECC area

25: data area 26: parity area

27: data area 28: first control data area

29: second control data area 30: parity area

31: Inspection Sector 32: Information Sector

33: data area 34: parity area

35: control data area 100: recording data

101: read data 102: recording gate

103: erase gate 104: read gate

105: playback address signal R: replacement sector

S: Data Sector M: Map Sector

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disc for recording or reproducing information by irradiating laser light, and more particularly, to an optical disc for uniformly managing defective sectors of a recordable optical disc and a reproduction-only optical disc.

A reproduction-only fluorescent disk (hereinafter referred to as RO disk) for recording data in a bit-shaped bit shape of irregularities arranged finely on a disk-shaped plastic base material and reproducing the data with a laser beam, and also storing the data with a magnetic disk. Attention has been paid to a recording fluorescent disk (hereinafter, referred to as a WT disk) that can be recorded together.

These are external data storage devices, such as personal computers, for recording or reproducing code data sector by sector. In particular, there is a demand for an RO disk capable of cheaply replicating data in large quantities and a WT disk capable of freely recording data by a user to be reproduced or recorded on the same device.

In the optical disc, recording and reproduction are performed by irradiating a laser beam focused at about 1 m, and various errors are caused by dust on the surface of the disc, foreign matter in the disc substrate, or defects in the recording surface. For this reason, in an optical disc having a sector structure, encoding for error detection and correction is performed on a sector basis so that data of each sector can be accurately reproduced. However, since the error detection correcting code is based on sectors of 512 bytes-2K bytes, it is difficult to take a sufficient interleaving length like a compact disc (CD) that does not employ a sector structure, and a long error affecting the entire area of the sector If this occurs, it becomes impossible to correct, which may make it difficult to reproduce data normally.

Therefore, in the WT disc, immediately after the data is recorded, the so-called read confirmation is performed to confirm that the recorded data is reproduced correctly, so as to detect a defective sector, and replace the defective sector in the replacement sector formed in a specific area of the optical disc. Processing has been performed. However, in WT discs, there is a problem in that replacement sectors become complicated and difficult because of an increase in defects in the optical disc due to media life and the number of repetitive recording times, resulting in long replacement processing time.

In addition, since the RO disk has a large amount of staff copying in a dedicated factory, the above read confirmation cannot be adopted, and the data quality is managed by rereading and inspecting all the produced disks and discarding the defective disks. . In this way, the entire inspection had a problem of rising manufacturing cost.

In view of the above, an object of the present invention is to provide an optical disc having high reliability of data reproduction for both a recording type optical disc and a reproduction type optical disc by uniformly handling defective sectors of an optical disc in the same track. do.

In order to achieve the above object, the optical disk according to the present invention records the first coded data for error detection and correction in each sector, and performs second coding by using the first coded plurality of sector data as an information symbol part. The check symbol portion of the second encoding is recorded in a sector different from the plurality of sectors.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing an embodiment of an optical information recording and reproducing apparatus for recording and reproducing data on an optical disc of the present invention. In Fig. 1, reference numeral 1 denotes an optical disc, 2 denotes an optical disc drive (hereinafter referred to simply as a drive) for recording and reproducing data on an optical disc, and (3) connects the drive 2 to the host CPU 4; Controller (4) is a host CPU having the drive (2) / controller (3) as an external storage device, (5) is a system interface with the host CPU, (6) is for temporarily storing data and error correction detection codes. Random access memory (RAM) and (7) encode the data with the first error correction detection code to correct the data generated in the reproduced data, and simultaneously convert the first encoded data with the second error correction detection code. Error correction detection circuits (EDAC) and (8) which decode and correct an error occurring in reproducible data that cannot be corrected by the first error correcting code (8) are used for the first error correction detection code to the data from the nocturn CPU (4). Digitally convert the encoded data to which the The data modulation circuits MODEH and 9 for outputting or demodulating the data from the read data 101 of the drive 2 detect the target sector address and generate sector start signals for recording, reproducing and erasing. The recording control circuit 10 denotes a control CPU for controlling the operation of the controller 3, 11 an interface with the drive 2, and 12 a mapping memory in which mapping data of the mapping sector of the optical disc 1 is stored. (13) is a parity buffer as a work area used when decoding the second error correction detection code of the inspection sector, (14) is a write gate 102, an erase gate 103 and a read gate 104. OR circuit for adding 100, 100 denotes modulation data from the data modulation / demodulation circuit 8, recording data recorded on the optical disc 1, 101 denotes read data reproduced on the optical disc 1, 102 Is a recording gate indicating that the recording data 100 is valid, 103 is for erasing the optical disc 1 An erase gate, 104 is the read gate, 105 is reproduced address signal 106 indicative of the data demodulation disclosed in a data service. Demodulator 8 is CPU data bus of the control CPU (10).

2 is a disc format configuration diagram of the first embodiment of the optical disc to which the present invention is applied. FIG. 2A is a disk format configuration diagram of a WT disc and FIG. 2B is a RO disc.

In Fig. 2, reference numeral 1 denotes an optical disc, 15 denotes a block made up of a plurality of tracks (#N to #N), and 16 denotes a defective sector which overflows the replacement / mapping region 19. A spare area corresponding to the replacement area 16 and not used by the RO disc, 18 denotes a data area for recording protected data obtained by encoding data with a first error correction check code; Reference numeral 19 denotes a replacement / mapping area for recording the defective sector in block 15 and managing replacement map information, and reference numeral 20 denotes a sector ECC area including a check sector encoded with a second error correction detection code.

FIG. 3 is a detailed block diagram of the block 15 of FIG. 2, and FIG. 3A is a detailed block diagram of the WT disc, and FIG. 3B is a detailed block diagram of the RO disc. In FIG. 3A, the block 15 has n tracks, and the tracks (1 to n-1) of (n-1) constituted of data sectors S (S1 to S16) for recording and reproducing data; ₁ track consisting of a defective sector replaced by a replacement sector R (R1 to R14) replacing the defective sectors of these data sectors S and a mapping sector M (M ₁ , M ₂ ) managing address correspondence information of the replacement sector. It is composed. In the embodiment of FIG. 3, since the mapping sector is the most important management data of the optical disc, a plurality of sectors are allocated in consideration of system reliability such as data reliability and power failure during recording of mapping data. In Fig. 3B, the block 15 is a track (n-1) consisting of data sectors S (S1 to S16) in which data is recorded in advance, and the first track of these data sectors S It consists of a track of the inspection sector P (P1 to P16) in which the second encoded data obtained by encoding the encoded data as the information code with the second error correction detection code is recorded. In FIG. 3B, the diagonal sectors S ₁ , S ₃ ,... OY beoul, there is shown the shape of recording the parity check on the sector P _11.

The optical disc and the optical information recording and reproducing apparatus of the present embodiment configured as described above will be described below in accordance with the pulley art of FIGS. 12 to 16.

First, in FIG. 12, the [a] controller 3 inquires the type of the optical disc 1 currently inserted in the drive 2 at the time of power supply and at the time of replacing the optical disc 1, and the drive 2 Detects the type of the optical disc 1 by the control information recorded in the identification hole of the optical disc cartridge or the control track of the optical disc 1, and notifies the controller 3 of its contents. [b] The controller 3 executes read, write, and erase commands in accordance with each disk type of the RO disk and the WT disk.

In the case where the optical disc 1 is a recording type optical disc, #N is first formatted from # 1 of block 15, and the test data is recorded and reproduced in all sectors of each block 15, thereby causing sector address errors, data errors or data. It is assumed that the presence of negative defects is confirmed, and mapping data replacing the defective defect sectors is recorded in the mapping sectors M (M1 and M2).

Defect sectors are detected as follows along the flowchart art shown in FIG.

The sector address error sets the sector read / write control circuit 9 with an instruction of one of the target sector addresses and the write / erase / read. The sector read / write control circuit 9 detects the sector address from the reproduction address signal 105, and in the case of detecting the coincidence with the target sector address, the write gate 102 and the erase gate 103 according to the set instruction. ), Which of the read gates 104 is outputted. Each of these outputs is input to the OR circuit 14, and the output of the OR circuit 14 is confirmed by the control CPU 10 and detected. If the output of the OR circuit 14 is detected, the sector address is normal, otherwise it is an error.

[b] The data error of the data portion reads the recorded data, decodes the first error correction detection code, and detects a data error from the contents of the error syndrome. It is detected from the width and number of signals binarized by the threshold value.

The mapping data is composed of a defective sector address of the block 15, an address of the replacement sector recorded therein, a use status map of the replacement sector, a sector use state of the replacement track area, and the like.

The number of traps (n copies) of the block 15 is selected from the characteristics of the search mechanism of the optical disk drive as a possible value for high-speed search, that is, the movable range (precision search or track jump range) of the operator of the optical head. In this way, it is not necessary to operate the low speed linear motor, and high speed sector replacement processing is performed.

Now, the operation at the time of recording data when the optical disc 1 is a WT disc will be described with reference to FIG.

[1] The host CPU 4 outputs a write command to the system interface 5. The write command is made up of a device command block (DCB) such as a target sector address, the number of sector blocks to be written, and a write operation code.

[2] The control CPU 10 of the controller 3 receives the DCB from the system interface 5 and searches for a track of the replacement / mapping area 19 of the block 15 to which the target sector belongs to the drive 2. Instruct them to. [However, in FIG. 1, the block of the search system of the drive 2, the control CPU, and the drive control interface is not shown.]

[3] Upon completion of the track search, the controller 3 control CPU 10 reads the mapping sector M1 and stores it in the mapping memory 12. If the mapping sector M1 is an error, read M2.

[4] Upon completion of storing the mapping data in the mapping memory 12, the data is transferred from the host CPU 4 to the RAM 6 via the system interface 5.

[5] The error correction detection circuit 7 attaches the first error correction detection code to the data transferred to the RAM 6.

[6] The control CPU 10 instructs the drive 2 to search for a track having a target sector, and sets the sector read / write control circuit 9 with an address and a write command of the target sector.

[7] When the sector read / write control circuit 9 detects the target sector, the write gate 102 is output to the data modulation / demodulation circuit 8 to read encoded data from the RAM 6 and digitally modulate it. The record data 100 is output to the drive 2. In the drive 2, the recording gate 102 modulates the semiconductor laser drive circuit as the recording mode to the recording data 100 and writes it in the sector.

[8] The target sector address of [6] refers to the mapping data of the mapping memory 12 before writing to check whether the corresponding sector is defective, and if the target sector is a defective sector, the replacement sector address is determined from the mapping data. The data of the replacement sector R of the replacement / mapping area 19 of the block 15 is recorded. When the use of the replacement sector in the block 15 is finished, the unused sector in the replacement area 16 is allocated to the replacement sector, the mapping memory 12 is started, and the mapping sectors M1 and M2 are updated.

In the above, the operation of the data recording operation is finished. Next, the operation of the data recording operation will be described with reference to FIG.

[1] The host CPU 4 outputs a read command to the system interface 5. The read command includes a device command block (DCB) such as a target sector address, the number of read sector blocks, and a read operation code.

[2] The control CPU 10 of the controller 3 receives the DCB from the system interface 5 and searches for a track of the replacement / mapping area 19 in the block 15 to which the target sector belongs to the drive 2. Instruct them to.

[3] Upon completion of the track search, the control CPU 10 of the controller 3 reads the mapping sector M1 and stores it in the mapping memory 12. If the mapping sector M1 is an error, read M2.

[4] Upon completion of storing the mapping data in the mapping memory 12, the controller 3 calculates a track to which the auto sector address belongs and instructs the drive 2 to search.

[5] The control CPU 10 sets the address and read command of the target sector in the sector read / write control circuit 9. The target sector address checks whether the sector is defective by referring to the mapping data of the mapping memory 12 prior to reproduction, and if the defective sector is found, the replacement sector address is read from the mapping data, and the replacement sector of the block is read. do.

[6] When the sector read / write control circuit 9 detects the target sector, the read gate 104 is output to the data modulation / demodulation circuit 8 to demodulate the read data 101, and the demodulated data is stored in RAM. We store in (6).

[7] The demodulated data stored in the RAM 6 is again stored in the RAM 6 by performing error detection and correction in the error correction detection circuit 7.

[8] The error corrected data of the RAM 6 is transferred to the host CPU 4 via the system interface 5.

This completes the data reproducing operation.

In addition, a disc may have a bad sector due to deterioration of the recording film due to repetitive recording or dust or dirt adhered during use. For this reason, the recorded data is read immediately after data recording, the quality of the data is decoded by the first error correction detection code, and the state of the error syndrome is checked. Replace with join sector. Since the read / check operation takes a margin, it is confirmed under severe conditions that intentionally deteriorate the reproducing condition or the error correcting ability.

Subsequently, the data of this sector is recorded in the unused replacement sector of the block 15, the contents of the mapping memory 12 are updated, and new mapping data is recorded in the mapping sector M. By doing so, it is possible to always match the contents of the mapping sector M to the substitution relationship between the data sector S and the replacement sector R. In addition, if the usage state of the replacement sector R other than the mapping data is recorded in the mapping sector M at the same time, the replacement sector can be used immediately. Block 15 selects the number of tracks that can be accessed at high speed by the optical head operator, so that not only the initial defective sector but also the additional defect sector of the replacement management in use by 1-2 mapping sectors M The registration data can be sufficiently registered, and the capacity of the mapping data is also small in one to two sectors, so that the mapping data can be easily managed by having the controller 3 have a small amount of memory.

For example, assuming that 64 tracks / blocks, 16 sectors / tracks, 1,024 bytes / sectors, and mapping data are 3 bytes of defective sector addresses and 3 bytes of alternate sector addresses, 170 sectors worth of defective sectors can be accommodated. (64 x 16) = 16.6% defective rate can be handled. This is the value which can afford enough practically. As described above, since the defective sector is managed by the mapping sector in units of blocks, the mapping memory 17 of the controller 8 has a small capacity of about 1 to 2 sectors, and the block is fast by the precise search jumping of the optical head. Since it is possible to search by, fast sector replacement can be performed.

As is clear from the above description, by splitting the optical disc into blocks and forming mapping sectors for recording mapping data of defective sectors and replacement sectors in each block, it is possible to efficiently realize high speed sector replacement processing. In addition, the small size of the mapping memory for storing the mapping data by block management makes it possible to reduce the cost of the device.

4 is a diagram showing the configuration of one embodiment of the second error correcting code of the sector ECC area 20 of the RO optical disk of the present invention. In Fig. 4, reference numeral 21 denotes a data sector and reference numeral 22 denotes an inspection sector.

In Fig. 4, the data area 18 is an example of (n-1) tracks and m sectors, and the data sectors 21 encoded by the first error correcting code for each of the first encoded data are shown. Over-the-counter for every (n-1) sector every two sectors, one sector from the track. Second coded data with parity is recorded in the inspection sector 22 of the sector EEC area 20. That is, S _{12 in} track 1 sector 2 and S _{24 in} track 2 sector 4. The overload of S _n -1 _m -1 encoded data of track (n-1) sector (m-1). Parity P ₁ , S ₁₃ of track 1 sector 3 _, S ₂₅ of track 2 sector 5. And over of S _n -1 _m encoded data of track (n-1) and sector (m). N inspection sectors of P _n from P ₁ are recorded in advance so as to be parity P ₂ . Now, when the RO disk having the block 15 constituted as shown in FIG. 4 has a defect that generates an error such as affecting the entire area of the sector, and an uncorrectable error is detected by the error detection correction circuit 7 during data reproduction. Will be described with reference to FIG.

[1] The control CPU 10 of the controller 3 calculates the sector address of the corresponding block that generated the second encoded data of the uncorrectable sector, and the corresponding inspection sector 22 of the sector ECC area 20.

[2] The controller 3 commands the drive 2 to track search of the first sector.

[3] When the track search ends, the control CUP 10 reproduces the data sector 21 and the inspection sector 22 other than the uncorrectable sector one sector by one, and parity the first encoded data of the RAM 6. Using the buffer 13 as a work area, over parity between sectors is taken.

[4] The contents of the parity buffer 13 in which all the over-parity of the data sector 21 and the inspection sector 22 other than the uncorrectable sector are calculated are the corrected sectors of the uncorrectable sector.

As apparent from Fig. 4, the data sector 21 for calculating the over parity has only one sector of the same sector address in the block 15. If the defect is 10 bytes or less from the number 10 bytes of the sector ID portion and the gap portion, one or more sectors related to the inspection sector cannot be corrected because of error correction.

In addition, if a reading solomon code or the like is recorded in a plurality of sectors instead of over parity, the plurality of sectors can be corrected even if an error occurs.

As described above, it is possible to construct a RO disk resistant to defects in a disk format such as a WT disk by unifying the disk format of the optical disk, simplifying the management of logical sector addresses and physical sector addresses, and controlling the control macro code of the controller. It is effective in reducing the dose of.

5 is a disc format configuration diagram of the second embodiment of the optical disc to which the present invention is applied. 5A is a disk format configuration diagram of a WT disc and FIG. 5B is a RO disc. In Fig. 5, numerals 1 and 15 to 18 denote the same as in Fig. 2, and 23 and 24 are sector medium / mapping areas and sector ECC areas formed for each track, respectively.

The sector replacement / mapping area 23 is sufficient for one sector per track in consideration of the probability of occurrence of an error correctable sector 10 ^-8 -10 ^-10 .

The configuration of FIG. 5 improves the processing time of data recording and reading confirmation immediately after recording of the optical disc 1 having a spiral track, and minimizes disk rotation waiting time by performing one track jump in the sector replacement / mapping area. FIG. 6 shows the first embodiment of the sector structure of the RO disk of the present invention, in which FIG. 6A shows an information sector in which information is recorded, and FIG. 6B shows a plurality of information sectors. Fig. 3 shows an inspection sector in which error detection correction is performed between sectors. In Fig. 6, reference numeral 25 denotes a data area, 26 denotes a parity area, and is divided into these two logical areas of each sector. In each of the information sectors shown in FIG. 6A, an information symbol is recorded in the data area 25, and an inspection data symbol obtained by correcting error detection and correction in the sector with respect to this information symbol is a parity area 26. As shown in FIG. ). Next, in the inspection sector shown in Fig. 6B, the over parity of the information symbols of the N information sectors is recorded in the data area 25, and the over parity of the information sector in the sectors is again recorded. In the parity area, inspection data symbols encoded by error detection correction are recorded in the parity area.

In the conventional optical disc constructed as described above, the inspection sector shown in FIG. 6 (b) and the inspection data symbol recorded in the parity area 26 are over parity of the information symbols recorded in the data area 25. Is an inspection symbol obtained by correcting error detection and correction within a sector, and in each information sector shown in FIG. 6A, the overall parity of each inspection data symbol recorded in each parity area 26 of the N information sectors. It is. Therefore, when decoding an error detection and correction code in a sector becomes uncorrectable when reproducing a certain information sector, the information sector is generated by generating (N-1) information sectors other than the information sector and the over parity of the inspection sector. Can be decoded.

FIG. 7 is a diagram showing the configuration of the information sector of the RO disk in the second embodiment of the present invention. In Fig. 7, reference numeral 27 denotes a data area, reference numeral 28 denotes a first control data area, reference numeral 29 denotes a second control data area, and reference numeral 30 denotes a parity area.

In the information sector divided into four logical regions as described above, the data symbol 27 has a second control data symbol unique to each information sector such as an information symbol in the data area 27 and an address in the first control data area 28. In the control data area 29, a symbol having a total of zero is recorded, and the parity area 30 is recorded in the data area 27, the first control data area 28 and the second control data area 29. For each data that is generated, inspection data symbols encoded by error detection correction in a sector are recorded for error detection correction.

FIG. 8 is a diagram showing the configuration of the inspection sector of the RO disk in the first or second embodiment of the present invention. In FIG. 8, (27)-(30) shows the same thing as FIG.

In the inspection sector divided into four logical regions as described above, over parity of each information symbol of the N information sectors in the data area 27 and the N information sectors in the first control data area 28 are shown. In the over parity of each control data symbol, and the second control data area 29, control data symbols unique to the corresponding inspection sector, such as addresses, are respectively recorded. In the parity area 30, each data recorded in the data area 27, the first control data area 28 and the second control data area 29 is corrected within a sector for error detection and correction. Detection-corrected inspection data symbols are recorded.

Generate over parity of (N-1) information sectors and inspection sectors other than the corresponding uncorrectable sector. Next, the control CPU 10 determines the over parity of the information symbols of the N information sectors recorded in the data area 27 and the first control data area 28 of the inspection sector and the over parity of the control data symbol. All of them are replaced with zero, and the error correction detection circuit 7 encodes them to generate a pseudo inspection sector and store it in the RAM 6. Then, the exclusive parity between the (N-1) sectors, the over parity of the inspection sectors, and the pseudo inspection sector data generated previously is taken. The over parity obtained as a result is data of the corresponding information sector, and the data can be reproduced normally.

Incidentally, although the control data is a sector address in the embodiment of the present invention, it may be obvious that the disc identification character and other arbitrary control data may be used.

9 is a diagram showing the configuration of an optical disc track in the embodiment of the present invention. In FIG. 9, 31 is an inspection sector, 32 is an information sector, and one track is composed of 2 ^m sectors. In the optical disc of the present embodiment configured as described above, information is recorded in the information sector 32 whose address is 1- (2 ^m -1). In addition, the over parity of these (2 ^m -1) information sectors 32 is recorded in the inspection sector in which the address of the sector is zero.

10 is a diagram showing the configuration of the information sector 35 of the optical disc in the embodiment of the present invention. In Fig. 10, reference numeral 33 denotes a data area, 34 denotes a parity area, and 35 denotes a control data area. In the information sector 32 of the optical disc of the embodiment configured as described above, the information symbol is recorded in the data area 33, and the address of each information sector is recorded in the control data area 35. The address of a sector is composed of a track address and a sector address. In the parity area 34, a check data symbol obtained by correcting error detection / correction / decoding in a sector is recorded for each symbol recorded in the data area 33 and the control data area 35. FIG.

11 is a diagram showing the configuration of the inspection sector 31 of the optical disk in the embodiment of the present invention. In FIG. 11, (33)-(34) is the same as (33)-(34) in FIG. In the inspection sector 31 of the optical disc according to the embodiment of the present invention configured as described above, over parity of each information symbol of (2 ^m -1) information sectors 32 is recorded in the data area 33, and the control data area. At 35, the address of the inspection sector is recorded. The address of a sector is composed of a track address and a sector address. In the parity area 34, a check data symbol obtained by correcting error detection / correction / decoding in a sector is recorded for each symbol recorded in the data area 33 and the control data area 35. FIG.

In the optical disc of the embodiment of the present invention configured as described above, the address of the inspection sector 31 recorded in the control data area 35 of the inspection sector 31 is the track address and the sector address of the inspection sector 31. At the same time, the address and over parity of each information sector 32 recorded in each control data area 35 of the (2 ^m -1) information sectors 32 are included. In other words, when the over parity of each track address and sector address of the (2 ^m -1) information sectors 32 is generated, it becomes the track address and the sector address of the corresponding inspection sector 31.

In Table 1, the address recorded in the control data area 35 of each sector in the case of 2 ^m = 16 (that is, one track is composed of one inspection sector 31 of 15 information sectors 32). For example.

In Table 1, the example in the case where track addresses are 10 and 20 is shown. "00001010,0000" and "00010100,0000" are respectively recorded in the control data area 35 of the inspection sector 31, which is the address of the inspection sector 31 and (2 ^m -1) sectors 32 (I.e., over parity of addresses of 15 information sectors 32). In the example shown in Table 1, the track addresses are set to 10 and 20, but the same is true for the other tracks.

As described above, according to the present invention, in the reproduction-only optical disc in which error detection and correction is performed by taking over parity between sectors, it is possible to record the address of the sector in each sector together with the information. Big.

TABLE 1

Claims (14)

An optical disc having tracks divided into a plurality of sectors, comprising: information sectors (21) and (32) for recording encoded data obtained by encoding data with a first error detection correction code for error detection correction; And an inspection sector (22) (31) for recording encoded data as second information detection part of the second error detection correcting code. The optical disc for reproduction as claimed in claim 1, wherein the information symbol portion and the inspection symbol portion of the second error detection correction portion are recorded on the same track. The optical disc for reproduction as claimed in claim 1, wherein the information symbol portion and the inspection signal portion of the second error detection correction portion are recorded in a plurality of tracks. The optical disc for reproduction as claimed in claim 3, wherein the information symbol portion and the inspection symbol portion of the second error detection correction portion are recorded in a plurality of non-adjacent tracks. The optical disc for reproduction as claimed in claim 1, wherein the inspection symbol portion of the second error detection correction portion is recorded in an inspection track composed of only inspection sectors. 6. The optical disc for reproduction as claimed in claim 5, wherein the second error detection correcting code is encoded using the first error detection coded data recorded on one track as an information code part. The optical disc for reproduction as claimed in claim 5, wherein the second error detection correcting code is encoded by using the first error detection coded data recorded on the plurality of tracks as an information code unit. 8. An optical disc for reproduction only according to claim 7, wherein the plurality of tracks are tracks which are not adjacent to each other. 6. The reproduction according to claim 5, wherein the second error detection correcting code encodes the first error detection coded data recorded in a plurality of sectors which are not adjacent in the radial direction of the track as the information symbol part. Dedicated optical disc. 10. The method of claim 9, wherein the second error detection correcting code includes at least one sector of at least one information block when a plurality of sectors spaced at predetermined intervals in the circumferential direction of the track are one sector from each track. An optical disc for reproduction, characterized in that the first error detection coded data recorded in " 11. An optical disc for reproduction only according to claim 10, wherein each information block is not adjacent to each other. 12. The sector of claim 11, wherein each sector is divided into four logical areas: a data area 27, a first control data area 28, a second data area 29, and a parity area 30. An information symbol is provided in the data area 27 of a sector, a control data symbol is provided in the first control data area 28, a symbol having a total zero in the second control data area 29, and a symbol in the parity area 30. For each symbol of the data area, the first control data area and the second control data area, a check data symbol that has been misdetected and corrected in a sector is recorded, and the data area 27 of the check sector is recorded. ) Has an over parity for each information symbol of N information sectors, the first control data area 28 has an over parity for each control data symbol of the N information sectors, and the second control data area. 29, the corresponding test A control data symbol for a sector, in the parity area 30, for each symbol of the data area 27, the first control data area 28, and the second control data area 29 within a sector. An optical disc for exclusive use in reproduction, characterized in that an error detection correction coded inspection data symbol is recorded respectively. 13. The test according to claim 12, wherein when m is any positive integer, (2 ^m -1) information sectors 32 on which information is recorded and one parity of the information sectors 32 are recorded. One track is composed of the sectors 31, and each sector is divided into three logical areas of the data area 33, the control data area 35, and the parity area 34. An information symbol in the data area 33, a sector address in the control data area 35, and a parity area 34 in the sector for each symbol of the data area 33 and the control data area 35. Inspection data symbols detected and coded are recorded, respectively, and in the data area 33 of the inspection sector 31, the over parity for each information symbol of the (2 ^m -1) information sectors 32, In the control data area 35, an address of a corresponding inspection sector, and in the parity area 34, Reproduction-only optical disk, characterized in that the data area 33 and the error correction coding the scanned data symbols in the sector with respect to each symbol of the control data area 35 is recorded, respectively. The optical disc for reproduction as claimed in claim 13, wherein the sector address is composed of a track address and a sector address.