JPH0695430B2 - Disc reproducing method and disc reproducing apparatus - Google Patents

Description

The present invention relates to a disc and a disc device for recording / reproducing a digital signal for each sector divided into a plurality of sectors.

[Outline of Invention]

In the present invention, a code for error detection or correction is added to each sector and also to each group.

[Conventional technology]

When recording digital data on an optical disc, a track is divided into a plurality of sectors, and each sector is a unit. An error correction code is added to the digital data so that correction can be performed for each sector. The maximum number of errors that can be corrected is determined by this correction code. When the data to be recorded is an audio signal, data that cannot be corrected can be corrected, but data that has no correlation before and after cannot be corrected. Therefore, in order to record / reproduce information accurately, it is desirable that the error correction capability be as high as possible.

[Problems to be solved by the invention]

For example, various data are sequentially recorded on one optical disk over a predetermined number of days, and when a certain amount of data is accumulated, a large number of replica disks are copied using the optical disk as a master disk and the disk is read-only. There are possible uses. However, when a replica disk is duplicated by pressing, injection or the like, since reproduction for confirmation cannot be performed immediately after recording, a replica disk having an error exceeding the maximum correction capability may be produced.

Therefore, an object of the present invention is to perform error correction even when an error that exceeds the correction capability of a sector unit occurs when a read-only disc is duplicated. An object is to provide a rewritable information recording / reproducing method and a disc recording / reproducing apparatus.

[Means for solving problems]

In order to solve the above-mentioned problems, the invention according to claim 1 of the present application is a disk in which an error correction code for a sector is added to digital data and recorded, or an error correction code for a sector and a plurality of sectors are added to the digital data. When an error correction code for a group is added to each group of sectors and recorded, and an identification signal indicating that the error correction code for a group is recorded is reproduced, one of the disks is reproduced. When the identification signal is detected from the predetermined position of, and when the identification signal is not detected, error correction in sector units is performed on the reproduced digital signal reproduced from the disc, and when the identification signal is detected When error correction is not possible only with error correction code,
Reproducing an error correction code for a group from a predetermined position on the disc, performing error correction in sector units on the reproduced digital signal, and performing error correction in group units,
Is characterized by.

According to a second aspect of the present invention, a disk in which a sector error correction code for each sector unit is added to digital data and recorded, or a digital data for each group unit including a sector error correction code and a plurality of sectors is recorded. A demodulation circuit for demodulating a reproduced digital signal from one of the discs on which an error correction code for a group is added and recorded, and an identification signal indicating that the error correction code for a group is recorded is also provided, and a predetermined disc of the disc. An identification circuit that detects the identification signal from the position, a correction circuit that performs error correction in sector units or group units on the reproduced digital signal under the control of the control circuit, and a reproduction digital signal when the identification signal is not detected. The error correction code for the sector is used for the signal to perform error correction in units of sectors, and the identification signal is When the error correction code cannot be corrected only by the sector unit error correction code when it is issued, the sector unit error correction is executed on the reproduced digital signal and the group unit error correction code using the group error correction code is executed. And a control circuit for controlling the correction circuit so as to execute.

[Action]

According to the invention of claim 1, the error correction is performed for each sector or for each disk or sector, and
When reproducing a disc that performs error correction for each group composed of a plurality of sectors, an identification signal is detected from a predetermined position of the disc. When the identification signal is not detected, it is determined that this disk is a disk that performs error correction in sector units, and error correction in sector units is performed on the reproduced digital signal reproduced from the disk. Further, when the identification signal is detected, it is determined that the disc has an error correction code recorded in group units. Then, when the error correction cannot be performed only with the sector unit error correction code, the group unit error correction is executed.

According to the second aspect of the present invention, the demodulation circuit demodulates the reproduced digital signal from either the disk in which the error correction in the sector unit is recorded or the disk in which the error correction code in the group unit is also recorded. The identification circuit detects an identification signal from a predetermined position on the disc. The correction circuit performs error correction on a sector unit basis or a group unit basis on the reproduced digital signal under the control of the control circuit. The control circuit controls the correction circuit based on this identification signal.

In other words, when the identification signal is not detected, the reproduced digital signal is subjected to sector unit error correction using the sector error correction code, and when the identification signal is detected, only the sector unit error correction code is detected. In case error correction is impossible, error correction is performed in sector units on the reproduced digital signal and error correction is performed in group units using the group error correction code.

〔Example〕

(I) Normal Recording Operation FIG. 1 is a block diagram of the optical disk device of the present invention.
In the figure, 1 is a generation circuit, which adds an error correction code to the input digital data and outputs it. The digital data is further modulated by the modulation circuit 2 by a predetermined method (for example, M ² ) and recorded on the optical disc 3.

For example, a plurality of optical discs 3 (eight) as shown in FIG.
It is divided into sectors. Each sector has an address area A
Address information such as a track number and a sector number is recorded in advance in the address area A, and the data is recorded in the data area of the designated address.

The data recorded in one sector is, for example, data and control data (C
D), error detection code (CRC), and error correction code (ECC)
And is sequentially read and recorded in the direction indicated by the arrow in the figure. Therefore, in each sector, for example, the sixth
Recording data is arranged as shown in FIG. That is, in this embodiment, one sector is composed of blocks B _{0 to} B ₆₃ , data, control data and error detection code are arranged in 62 blocks B ₀ to B ₆₁ , and the last two blocks B ₆₂ , B _An error correction code (parity) is arranged at ₆₃ .

The data thus recorded is reproduced from the optical disc 3 and demodulated by the demodulation circuit 4. The demodulated signal is input to the correction circuit 5, and the error is corrected for each sector by using the error correction code arranged for each sector.

(Ii) Mastering Operation When a predetermined amount of data is recorded on one optical disk 3, a read-only disk (disk ROM) is mastered using the disk as a master, for example, as shown in the flowchart of FIG.

First, the address A is set to 0. 64 sectors are selected from the master and made into one group. At the time of this selection, if the same data is recorded in the alternate sectors, the alternate sectors are grouped. Then, the data of the corresponding blocks are sequentially read one by one from the 64 sectors. When 64 blocks of data are read, an error correction code having a data length of, for example, 4 blocks is generated for the data. In this way, the process of generating the correction code for 4 blocks for the data for 64 blocks in total is sequentially performed for the other blocks of 64 sectors, and the error correction code for 4 sectors in total is prepared (predetermined). Stored in memory). A total of 68 sectors of group data consisting of the original data of 64 sectors and the error correction code of 4 sectors are sequentially recorded in each sector of the mastering disk ROM. As a result of this recording, as shown in FIG. 6 (b), a sector in which data is arranged similarly to the master sector and a sector in which only error correction code is recorded are formed. The location of the latter sector is arbitrary, but can be, for example, a replacement sector.

Interleaving is limited to one sector in order to perform correction in units of one sector. On the other hand, the disc RO
In M, the interleave length is 64 sectors. Therefore, it becomes stronger against burst errors. Further, the correction capability of the error correction code to be added can be the same as that of the master, but it can be made higher as in the above-mentioned embodiment.

When recording of data for 68 sectors is completed, address A
Is changed from 0 to 68 (the address is sequentially incremented by 1 when recording 68 sectors). The above operation is repeated until the final address is reached. When the recording of the data of the last address is completed, the identification signal is recorded at a predetermined position. This identification signal indicates that the disc is read-only.

(Iii) Playback operation of disc ROM The format of the read-only disc thus formed is the same as that of a normal optical disc. Therefore, this read-only disc can be reproduced by an ordinary optical disc device.

Therefore, the optical disk device controls the operation according to the flowchart shown in FIG. 3, for example. At the time of startup, the identification circuit 6 first determines whether or not there is an identification signal, that is, whether or not the disc is a read-only disc. If the disk is a read-only disk, the flag is turned on, and if the disk is a normal disk (writable disk), the flag is turned off, and then a command input waiting state is entered.

When a command other than the read command is input, the routine for that command is entered, and when a read command is input, the read operation is executed. When the error generated in the read signal can be corrected by the error correction code in the sector, the correction is performed using the code. If the error is uncorrectable by the error correction code in the sector, error handling is performed when the flag is off. When the flag is turned on, the control circuit 7 switches the correction circuit 5 to execute the correction using the error correction code recorded in the alternate sector. Even if the correction is impossible by this, it is regarded as an error.

The case where the present invention is applied to the optical disc and the optical disc device has been described as an example, but the present invention can be applied to other discs and the device.

〔effect〕

As described above, according to the present invention, when the disc on which the sector unit error correction code is recorded is reproduced, since the identification signal is not detected, the sector unit error correction is performed. When playing a disc with error correction codes recorded in groups,
Since the identification signal is detected, correction is performed according to the error correction situation. That is, when sufficient error correction cannot be performed only by sector unit error correction, group unit error correction is performed using the group unit error correction code.

Therefore, if the disc is a sector that cannot be corrected and an error correction code is recorded in a group, more errors can be corrected.

Further, it is possible to discriminate between a disc to which a read-only group-unit error correction code is added and a normal disc for reproduction.

[Brief description of drawings]

FIG. 1 is a block diagram of the disk device of the present invention, FIGS. 2 and 3 are flowcharts thereof, FIG. 4 is an explanatory diagram of its tracks, FIG. 5 is an explanatory diagram of its data, and FIG. 6 is its sector. It is explanatory drawing of arrangement | positioning of the above data. 1 ... Generation circuit 2 ... Modulation circuit 3 ... Optical disk 4 ... Demodulation circuit 5 ... Correction circuit 6 ... Identification circuit 7 ... Control circuit

Claims (2)

[Claims] 1. A disk in which a sector error correction code for each sector unit is added to digital data and recorded, or a group for each group unit composed of the sector error correction code and a plurality of the sectors in the digital data. When an error correction code is added and recorded, and one of the discs on which an identification signal indicating that the group error correction code is recorded is reproduced, the identification signal is recorded from a predetermined position on the disc. When the identification signal is detected and the identification signal is not detected, error correction in sector units is performed on the reproduced digital signal reproduced from the disc, and when the identification signal is detected, the error correction code in sector units is detected. When the error correction cannot be performed only by itself, the error correction code for the group is reproduced from a predetermined position on the disc and the reproduced digital signal is reproduced by the sec Disc playback method, characterized by, that performs error correction in units of groups and executes error correction of the data units. 2. A disk in which a sector error correction code for each sector unit is added to digital data and recorded, or a group for each group unit composed of the sector error correction code and a plurality of the sectors in the digital data. A demodulation circuit for demodulating a reproduced digital signal from one of the discs on which an error correction code is added and recorded, and further an identification signal indicating that the group error correction code is recorded, and a predetermined disc of the disc. An identification circuit for detecting the identification signal from the position, a correction circuit for performing error correction for each sector or group for the reproduced digital signal under the control of the control circuit, and when the identification signal is not detected , Performing sector-by-sector error correction using the sector error correction code on the reproduced digital signal, When another signal is detected and the error correction cannot be performed only with the sector unit error correction code, the sector unit error correction is performed on the reproduced digital signal and the group error correction code is added. A disc reproducing apparatus comprising: a control circuit that controls the correction circuit to execute error correction in units of groups used.