KR910008506B1 - Optical disk - Google Patents

Abstract

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Description

Optical disc

1 is a block diagram of an optical information recording and reproducing apparatus according to one embodiment of the present invention.

2 is a disc configuration diagram of the first embodiment of the optical disc of the present invention.

3 is a disc configuration diagram of a second embodiment of the optical disc of the present invention.

4 is a layout view of replacement tracks of the conventional optical disc.

5 is a block diagram of an optical information recording and reproducing apparatus using the track replacement of FIG.

* Explanation of symbols for main parts of the drawings

1: optical disc 2: block

3: Block Management Track 4: Data Track

5: alternate track area 6: block management sector

7: Host CPU 8: Controller

9 optical disc drive 12 error correction detection circuit

13 data modulation / demodulation circuit 14 sector read / write control circuit

17: mapping memory 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 R: Alternate Sector

M: Mapping Sector

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

As a defect management method of a conventional optical disc, it is described in Unexamined-Japanese-Patent No. 61-20271, for example. 4 is a diagram showing the arrangement of alternative tracks of the conventional optical disc, in which (A) is a substitute track, (B) is a normal track for recording data, (C) is a secondary alternative track, (D) is a sector identifier part which recorded a sector address. 5 is a block diagram of an optical information recording and reproducing apparatus using the track replacement of FIG. Reference numeral 19 denotes a sector address reproducing circuit, 20 a data reproducing circuit, 21 a target sector address register, 22 a sector address matching detection circuit, 23 a data recording gate signal circuit, and 24 Is a data regeneration gate signal circuit, 25 is a bad sector detection circuit for detecting a defective sector, 26 is a replacement track setting circuit, and 27 is a sector erase gate signal circuit for writing an identification mark in a defective sector.

In the conventional optical disc and the optical information recording and reproducing apparatus constituted as described above, when the outputs of the target sector address register 21 and the sector address reproducing circuit 19 coincide, they are based on the coincidence signal output from the coincidence detection circuit 22. Thus, the defective sector detection circuit 25 detects the defective sector in the signals from the data reproducing circuit 20, the data recording gate signal circuit 23, and the data reproducing gate signal circuit 24. The defective sector is detected by an error syndrome which decodes the error correction detection signal by the sector address detection circuit or the data reproducing circuit 20 of the sector identifier. When a defective sector is detected, the replacement track setting circuit 26 calculates a replacement track and substitutes and records data of the defective sector in an unrecorded sector of the replacement track.

Next, the sector erase gate signal circuit 27 superimposes the erase signal on the data portion of the defective sector. It is understood that the defective sector in which the erase signal is overwritten is replaced by detecting the erase signal at the time of reproduction.

Therefore, in the conventional example, the replacement tracks are distributed and formed for each block of the optical disc to shorten the access time to the replacement tracks.

However, in the above configuration, when the same sector is repeatedly recorded, such as an erasable optical disc, in the bad sector detection circuit 25, the sector address detection error of the sector identifier can be detected as a defective sector. In addition, since the erase signal recorded in the data portion cannot be detected before the sector address detection of the sector identifier portion, data is recorded in spite of a defective sector, and as a result, sector replacement is required again, resulting in further sector replacement processing time. There was a problem that the access speed is slowed down.

In view of the above, the present invention provides an optical disc for improving the processing speed of the replacement process by forming a mapping sector in which the combined sector records the address of the replacement sector in which the defective sector has been replaced by the address corresponding map information (hereinafter referred to as mapping data). The purpose is to provide.

The optical disc of the present invention divides an optical disc for recording and reproducing data into tracks divided into a plurality of sectors into blocks consisting of a plurality of tracks, and replaces data sectors for recording data in each block and defective data sectors among the data sectors. And an at least one mapping sector for recording the mapping data of the defective data sector and the replacement sector.

According to the above-described configuration, the present invention records the mapping data corresponding to the address information of the defective data sector and the address information of the replacement sector in which the defective data sector is recorded in the mapping sector of the corresponding block, thereby reproducing the sector during data reproduction or data rewriting. The address information of the replacement sector is obtained from the mapping sector of the block to which the block belongs, and the reproduction or recording process of the defective sector is performed at high speed.

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

FIG. 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 disk, 7 denotes a host CPU having the drive 9 and the controller 8 as an external storage device, and 8 denotes a drive 9 connected to the host CPU 7. The controller 9 is an optical disc drive (hereinafter referred to simply as a drive) for recording and reproducing data on the optical disc. (10) shows a system interface with the host CPU (7), (11) a random access memory (RAM) for temporarily storing data and error correction detection codes, (12) shows an error correction code and an error occurring in the reproduction data. Error correction detection circuit (EDAC) and 13 for digitally modulating the coded data to which the error correction detection code is added to the data of the host CPU 7 to output the write data 100, or Data demodulation / demodulation circuits MODEM, 14 for demodulating data from the read data 101, sector read / write control circuits for detecting target sector addresses and generating start signals for recording, reproducing and erasing; 15 is a control CPU for controlling the operation of the controller 8, 16 is an interface with the drive 1, 17 is a mapping memory storing mapping data from the mapping sector of the optical disc 1, 18 The outputs of the write gate 102, erase gate 103 and read gate 104 OR circuit 100 denotes recording data recorded on an optical disc as modulation data from the data modulation and demodulation circuit 13, 101 read data reproduced from an optical disc, and 102 denotes recording data 100. A recording gate indicating that it is valid, 103 is an erasing gate for erasing the optical disc 1, 104 is a reading gate which instructs the data modulation and demodulation circuit 13 to start data demodulation, and 105 is a reproduction gate. The address signal 106 is a CPU data bus of the control CPU 15.

2 is a disc configuration diagram of the first embodiment of the optical disc of the present invention.

In Fig. 2, reference numeral 1 denotes an optical disk, 2 denotes a block (# 1 to #N) consisting of a plurality of tracks, and 3 denotes a replacement sector R (R1 to R14) and a mapping sector M. A block management track consisting of (M1, M2), (4) is a data track consisting of tracks with data sectors S (S1 to S16), and (5) is a replacement sector R of block (R) (R1). Is a replacement track area for substituting recording of defective sectors exceeding R14). In FIG. 2, the block 2 includes data sectors S (S1 to S16) for recording and reproducing data, and replacement sectors R (R1 to R14) replacing defective sectors of these data sectors S. In FIG. And a mapping sector M (M1, M2) that manages the address correspondence between the replaced defective sector and the replacement sector.

The operation of the optical disc and the optical information recording and reproducing apparatus of the present embodiment configured as described above will be described below.

In the optical disc 1, block #N is first formatted from block # 1, and the test data is recorded and reproduced in all sectors of each block to check for a sector addresser error, a data error, or a defect in the data part. It is assumed that mapping data replacing defective sectors is recorded in mapping sectors M (M1 and M2). The sector addresser error can be checked by checking the output of the OR circuit 18 by setting the desired sector address and the write / erase / read command to the sector read / write control circuit 14. If the output of the OR circuit 18 is detected, the sector addresser is normal and if not detected it is an error. The data error of the data portion reads the recorded data and codes the error correction detection code to detect it from the contents of the error syndrome. The defect of the data portion is the width of the signal obtained by binarizing the reproduction signal of the unrecorded sector at a certain threshold value. Detected from fruit water.

The mapping data consists of a defective sector address of the data sector, an address of the replacement sector recorded in the replacement sector, a usage map of the replacement sector, and a usage status of the sector in the replacement track area.

The number of tracks of the block is selected from the characteristics of the search mechanism of the optical disc drive by a value that can be searched quickly, that is, the movable range (precision search or track jumping 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 can be performed.

First, the operation of data recording will be described.

[1] The host CPU 7 outputs a write command to the system interface 10. 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 record operand.

[2] The control CPU 15 of the controller 8 receives the DCB from the system interface 10 and instructs the drive 9 to search the head track of the block 2 to which the target sector belongs. (However, in Fig. 1, the block of the search system of the drive 9 and the control CPU drive control interface is not shown.)

[3] Upon completion of the track search, the control CPU 15 of the controller 8 reads the mapping sector M1 and stores it in the mapping memory 17. If the mapping sector M1 is an error, M2 is read.

[4] When the mapping data is stored in the mapping memory 17, the data is transferred from the host CPU 7 to the RAM 11 via the system interface 10.

[5] The error correction detection circuit 12 attaches an error correction detection code to the data transferred to the RAM 11.

[6] The control CPU 15 instructs the drive 9 to search for a certain track of the target sector, and sets the sector read / write control circuit 14 with the address and the write command of the target sector.

[7] When the sector read / write control circuit 14 detects the target sector, the write gate 102 is output to the data modulation / demodulation circuit 13 to read the encoded data from the RAM 11 and digitally modulate it. The record data 100 is output to the drive 9. In the drive 9, the recording gate 102 modulates the recording laser data into the recording data 100 using the semiconductor laser drive circuit as the recording mode, and records the data in the sectors.

[8] The destination sector address checks whether the corresponding sector is defective by referring to the mapping data of the mapping memory 17 prior to writing, and if the defective sector is found, the replacement sector address is determined from the mapping data, and the replacement sector of the corresponding block is checked. Record data in (R). When the replacement sector of the block is finished, the unused sector of the replacement track area 5 is allocated as the replacement sector, the mapping memory 17 is rewritten, and the corresponding mapping sectors M1 and M2 are updated. do.

This completes the description of the data recording operation, and then describes the operation of data reproduction.

[1] The host CPU 7 outputs a read command to the system interface 10. The read command is made up of device command blocks (DCBs) such as the target sector address, the number of read sector blocks, and the read operation code.

[2] The control CPU 15 of the controller 8 receives the DCB from the system interface 10 and instructs the drive 9 to search the head track of the block 2 to which the target sector belongs.

[3] Upon completion of the track search, the control CPU 15 of the controller 8 reads the mapping sector M1 and stores it in the mapping memory 17. If the mapping sector M1 is an error, M2 is read.

[4] When storing the mapping data in the mapping memory 17 is completed, the controller 8 calculates a track to which the target sector address belongs, and instructs the drive 9 to search.

[5] The control CPU 15 sets the address and read command of the target sector in the sector read / write control circuit 14. The target sector address refers to the mapping data of the mapping memory 17 before writing to check whether the corresponding sector is defective, and if the defective sector address is determined from the defective sector two year mapping data, the replacement sector of the corresponding block is read. .

[6] When the sector read / write control circuit 14 detects the target sector, the read gate 104 is output to the data modulation / demodulation circuit 13 to demodulate the read data 101 to store the demodulated data in RAM. It is stored in (11).

[7] The demodulation data stored in the RAM 11 is subjected to error detection and correction by the error correction detection circuit 12 and stored in the RAM 11 again.

[8] The error corrected data of the RAM 11 is transmitted to the host CPU 7 via the system interface 10.

In addition, an optical disc may cause a sector to be defective due to deterioration of the recording film due to repetitive recording or dust or dirt adhering to the use environment.

For this reason, the recorded data is read immediately after the data is recorded, the error correction detection code is decoded, and the state of the error syndrome, that is, the quality of the data, is checked, and if there is an error exceeding a predetermined standard, the sector is newly added as a joining sector. Replace. Since the read confirmation operation takes a margin, it confirms under severe conditions in which the reproducing condition or the error correction capability is intentionally bad.

Then, the data of the corresponding sector is recorded in the unused replacement sector of the corresponding block, the contents of the mapping memory are updated, and new mapping data is recorded in the mapping sector. By doing this, it is possible to always match the contents of the mapping sector to the replacement relationship between the data sector and the replacement sector. In addition, if the usage state of the replacement sector is recorded simultaneously in addition to the mapping data in the mapping sector, the available replacement sector can be known immediately. If the block is selected as the number of 10 tracks that can be accessed at high speed by the optical head operator, one or two mapping sectors can sufficiently record not only the initial defective sectors but also additional sectors of replacement processing in use. Since the mapping data has a small capacity of 1 to 2 sectors, the mapping data can be easily managed by providing a small amount of memory in the controller.

For example, assuming 64 tracks / blocks, 1024 bytes / sectors, and 3 bytes of defective sector addresses and 3 bytes of alternate sector addresses as mapping data, 170 sectors equal to 170 sectors can be accommodated. Defect rate can be handled. This is the value which can afford enough practically.

3 is a disc configuration diagram of an optical disc second embodiment of the present invention.

In Fig. 3, the same numerals (1) to (5) in Fig. 2 indicate the same thing, and (6) is a block consisting of mapping sector M (M1) and replacement sector R (R1 to R15). The management sector. In Fig. 3, each block 2 (# 1 to #N) has a sector S (S1 to S15) for recording and reproducing data, and a replacement sector R (replacement of defective sectors of these data sectors) ( R1 to R15, and mapping sectors M and M1 which manage address correspondence between the replaced sector and the replacement sector R.

In FIG. 3, replacement sectors R (R1 to R15) are each assigned one sector to the track. For this reason, the replacement of defective sectors is considered from the occurrence activity ratio of error correcting sectors from 10 ^-8 to 10 ^-10 , and since most of them are within one sector per track, it is necessary to search the block management track 3 as shown in FIG. Can be processed at high speed.

In the embodiments of Figs. 2 and 3, since the mapping sector is the most important management data of the optical disc, it is preferable to allocate multiple sectors in consideration of system reliability due to power failure or the like during data reliability and mapping data recording.

As described above, since the defective sector is managed 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 jump of the optical head. Since the search can be performed, sector replacement can be performed at high speed.

As is apparent from the above description, by dividing the optical disc into blocks and forming mapping sectors for recording mapping data into defective sectors and replacement sectors for 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.

As described above, according to the present invention, even if a sector of an optical disc is a defective sector, data can be recorded and reproduced satisfactorily by replacing the sector, and its practical effect is large.

Claims (5)

An optical disc for recording and reproducing data on tracks divided into a plurality of sectors is divided into blocks (2) consisting of a plurality of tracks, each block (2) comprising a data sector (S ₁ ) for recording data, and the data sector 10. An optical disc having a replacement sector (R ₁ ) for alternately recording a defective sector in the middle, and at least one mapping sector (M _K ) for recording address correspondence map information of the defective sector and the replacement sector. 2. The optical disc of claim 1, wherein the block (2) allocates at least one sector for each track either as a mapping sector (M _K ) or a replacement sector (R ₁ ). 2. A block according to claim 1, wherein each block (2) is assigned at least one track (3) to either a mapping sector (M _K ) or a replacement sector (R ₁ ), and at least one sector of the track is the mapping sector. An optical disc characterized in that. 4. The optical disc (1) according to claim 1, 2 or 3, wherein the optical disc (1) has a plurality of blocks (2) and a replacement track area (5), and the number of replacement sectors (R ₁ ) of the blocks (2). An optical disc, characterized in that when an excess joining sector occurs, the excess defective sector is replaced by a sector of the replacement track area (5). 4. An optical disc as claimed in claim 1, 2 or 3, wherein each block (2) is a number of tracks within a movable range of the optical head operator.