JPS631666B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides an optical recording and reproducing apparatus capable of recording and reproducing digital signals on a rotating disk disk using optical means such as a laser beam. The present invention relates to a data recording method suitable for recording digital information on a surface composed of a large number of spiral tracks and further dividing each track into a large number of sectors.

Conventionally, many techniques have been proposed for recording and reproducing binary data using a light beam such as a laser beam on a rotating disk disk on which a thin film of As, Te, etc. is deposited. A typical method of this type of technology is to form a dissolved spot on the disk using a light beam, where the spot has a weak reflectance and the non-spot has a low reflectance. Indicates a strong state of By effectively allocating binary data to such states, data can be recorded and reproduced. The size of the spot portion recorded here is, for example, 0.8 μm in diameter, the distance between adjacent tracks is 1.6 μm, and the data pitch is 1.6 μm.

Furthermore, special consideration is given to the optical disc disk in devices having random access capabilities for rapid additional recording and selection of arbitrary tracks. One of them is that a tracking groove is provided in advance to control the optical head system to follow a desired track. Furthermore, the track circumference of the disk surface is divided into sections, and sector numbers and track numbers are provided in advance to display each divided area (sector). This type of technology is disclosed, for example, in Japanese Patent Application Laid-Open No. 130102/1983, “Information Writing Method,
"Record carriers, recorded record carriers and information writing and reading devices".

Next, an outline of a general optical recording/reproducing system will be explained using FIG. According to the figure, the system is large and consists of an optical disk device 70, a control device 86, and a processing device 87. In this system, data recording and reproduction in the optical disk device 70 is controlled via the control device 86 in accordance with commands from the processing device 87 . The optical disk device 70 is functionally divided into a rotating disk disk 71, an optical section 72, and a control section 74. The optical disk device 70 includes a control device 8
When an operation such as data recording/reproduction or seeking (meaning an operation to detect a desired track and sector) is instructed by a control signal 77 from 6, the control section 74 signals a seek instruction to the optical system. 75. First, when a seek instruction is given, the optical section 72 moves in the direction of the arrow y, that is, in the radial direction of the disk to perform tracking control, and further controls the objective lens 75 in the direction of the arrow x to perform automatic focus control. Next, when data writing control is given by signal 77, data signal 69 passing through signal 76 to control section 74 is recorded in a desired sector by optical recording beam 68 in optical section 72. In the case of data reproduction control, the control section 74 outputs a reproduction instruction using a signal 75 based on the control signal 77, and the optical reproduction beam 68 is transmitted through the optical section 72.
The data signal 69 is output as reproduced data to the control device 86 via the control section 74 as a signal 76.

Next, the control device 86 is located between the processing device 87 and the optical disk device 70 and performs command processing and data processing. The main commands issued by the processing device 87 are recording commands and playback commands. It is assumed that the command in this case also includes a seek instruction to the optical disk device 70. First, when a recording command is given to the control device 86 in the form of a signal 85, the control mechanism 79 gives a seek instruction to the optical disk device 70 in the form of a signal 77. When the seek instruction is completed, the optical disk device 70
indicates the end of the seek at the signal 77. Control mechanism 7
When 9 detects the end of the seek, it requests transfer of recording data by signal 85. Upon receiving the request, the processing device 87 outputs the recording data to the signal 84. The data control mechanism 80 takes recording data from a signal 84 into a data buffer (not shown) in response to a signal 83 and outputs recording data to a signal 76. Normally, a method is adopted in which the recorded data is taken directly from the storage memory of the processing device 87. Recording data is serially applied to the optical disk device 70 by a signal 76, and the data is recorded in a desired sector of the disk 71. Next, the reproduction command will be described. When a reproduction command is given by the signal 85 from the processing device 87, the control mechanism 79 outputs the signal 77 and gives a seek instruction to the optical disk device. When the seek operation is completed, control mechanism 79 notifies reproduction data transfer by signal 85. The reproduced signal is reproduced from the disk 71 of the optical disk device 70, output as a signal 76, and written into the memory of the processing device 87 via the data control mechanism 80 as a signal 84.

The optical disk device described above is publicly known,
The controller is similar to a magnetic disk controller and will be easily implemented by a specialist in this type of technology.

FIG. 2 is an explanatory diagram of recording/reproducing tracks and sectors on a disk disc. disk disc 1
is provided with a continuous spiral track 2. Furthermore, the track 2 is divided into a number of sectors, for example sectors 3 to 7, over its entire circumference. Usually the track is divided into equal parts.

FIG. 3 is a diagram showing an example of one configuration format of the divided sector. 1 sector is ID
It is roughly divided into two parts: an (index) part 21 and a data part 22. The ID section 21 is further divided into a sector gap 23, a synchronization section 24, a track 25, a sector number 26, and a check section 27. Here, the sector gap 23 includes information indicating the start of each sector. The synchronizer 24 provides a signal to start a synchronous oscillator for reproducing subsequent signals. Track number 25 is a consecutive track number. Furthermore, consecutive serial numbers are repeatedly assigned to the sector number 26 corresponding to each track. The check section 27 includes check bits for determining whether the track number 25 and the sector number 26 are correct or incorrect, and for example, a check bit based on a cyclic code is added.

The data section 22 includes an ID flag 50, a synchronization section 51,
It is composed of data 52, an error correction section 53, and a data flag 54. The ID flag 50 is the ID section 21
This is an area to record information if there is an error in the content. For example, information about the ID that became defective during inspection of the disk disk may be written in advance, or the ID information before the operation to record data in the sector concerned may be written.
It may be written systematically after detection. Synchronization part 5
1 is a pattern for generating synchronization of subsequent data by a synchronization circuit. Data 52 is data that is recorded following the synchronization section 51 during recording, and is data to be reproduced during playback. The error correction section 53 is provided with an error correction code for correcting errors in the recorded and reproduced data 52 within its correction capability. The data flag 54 is used to reproduce the data (data 53 and error correction section 53) immediately after recording and check whether it was recorded correctly.If an uncorrectable error occurs, the data flag 54 is information indicating that the sector is unusable. is recorded. At this point, the ID flag 50 may be stopped and used also as the data flag 53.

SUMMARY OF THE INVENTION An object of the present invention is to provide a data recording method that can shorten the playback check time immediately after data recording. According to the present invention, in a data recording method on a disk-shaped recording medium in which tracks for recording data are arranged in a spiral, a point that intersects a straight line extending from the center of the spiral to the outer circumference through a recording start position. The present invention is characterized in that the recording operation is ended by recording up to the front, and in the rotational operation immediately following the recording operation, the data access mechanism is moved to reproduce data from the recording start position.

An embodiment of the present invention will be described in detail below with reference to the drawings.

FIG. 4 is a schematic diagram for explaining one embodiment of the present invention. As shown in the figure, a large number of continuous spiral tracks are arranged on the disk 1. As shown in FIG. In this example, one circumference of the disk is 8
It is explained as being divided into equal parts. Each equally divided area 29-48 is a sector. Furthermore, all sectors are provided as recordable and reproducible sectors.

In this embodiment, as will be described later, the track recording format is improved so that the optical system of the optical disk device jumps one round outward for a playback check immediately after data recording, so that time for movement can be secured. In addition, in optical disk devices, the data pit diameter and data pit spacing are, for example, 0.8 μm and
The size of the defect is as small as 1.6 μm, and even with improvements in disk manufacturing technology, the occurrence of small defects is unavoidable.For the reasons explained below, data in the defective sector cannot be subsequently re-recorded and reproduced. We have secured a sector area for checking.

FIG. 5 is an explanatory diagram for explaining the processing process during data recording on the disk surface. truck
The case of recording data to _T1 will be explained. Therefore, data recording starts from the circle shown in the figure.
Data is first recorded in sector 30. The recording method is to reproduce the track number and sector number of the ID section in sector 30, and determine that the ID can be correctly reproduced and that the sector is the target sector. Next, data is recorded in the data section of sector 30. The recording process then moves to sector 31. When an ID error 61 is detected in sector 31, the entire sector is regarded as a bad sector and no data is recorded, information indicating that it is a bad sector is recorded in the ID flag section, and data is recorded in the next sector 32. Processing moves on. Data is recorded in sectors 32, 33, 34, and 35 through similar recording processing.

Furthermore, since a defective sector occurs in sector 31 during the recording process, data is recorded in sector 36 and the entire recording process is completed. Next, in the optical disk device, the optical section jumps outward by one rotation, and checks the first sector 30 for reproduction with a margin time. If there is no reproduction error in sector 30, then reproduction of sector 31 is started. Sector 31 has a defect in the ID section 60 during data recording, and the result is recorded in the ID flag area, so sector 31 is regarded as a defective sector and a reproduction check for the next sector 32 is started. Assume that sectors 32, 33, and 34 are correctly reproduced. Next, sector 35 is reproduced, and since an error 61 has occurred in the data reproduction section, it is determined to be a bad sector. Therefore, data indicating a bad sector is additionally recorded in the data flag of sector 35. This bad sector is registered in a register (not shown) within the control device. In this way, the playback check process passes through sector 35. Next, a reproduction check of the final sector 36 is started. A data error 62 also occurred in the sector 36.
Therefore, data indicating a bad sector is additionally recorded in the data flag of sector 36, sector 36 is also determined as a bad sector, and this bad sector is registered in a register in the control device.
The playback check process for sector 36 is completed.

As a result of the above, data recording processing is performed again for sectors 35 and 36 that have been registered as defective sectors. First, the same data content as the data to be recorded in sector 35 is recorded in the subsequent sector 37. After this data is recorded, sector 3
The same data content as that to be recorded in sector 6 is recorded in the subsequent sector 38. The data recording process again ends at sector 38, and then jumps one round to the outside and moves on to playback checks in sectors 37 and 38. If the data in sectors 37 and 38 are correctly reproduced as a result of the reproduction check, all data recording processing is completed.

It is clear that by repeating the processing steps as described above, data can be recorded even when the number of error sectors increases.

According to this embodiment, if a defective sector is detected during data recording processing on a spiral track, data recording can be shifted to the next sector after the defective sector. This eliminates the need for wasteful sector management. Similarly, if a defective sector occurs in the data section during a playback check after data recording, the same data as the defective sector is sequentially recorded from the beginning to the succeeding sector following the sector after the last recording. Track data can always be handled as one group, and the above-mentioned replacement sector is also unnecessary.

Although the embodiments of the present invention have been described above, the present invention has the effect of shortening the playback check time immediately after data recording.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing an example of the configuration of a general optical recording/reproducing device. FIG. 2 is a diagram showing an example of the arrangement of spiral tracks and sectors on a disk. FIG. 3 is a diagram showing an example of the format of one sector. FIG. 4 is a diagram showing an example of the layout of tracks and sectors according to the present invention, and FIG. 5 is a diagram showing an embodiment of the present invention, illustrating a data recording processing method and a playback check processing method. 70... Optical disk device, 71 and 1... Optical disk disc, 29 to 48... Sector, T ₁ ,
T ₂ , T ₃ ... Track, △ mark ... Track separation point,
20... Sector, 21... ID section, 22... Data section, 23... Center gap, 24... Synchronization section, 25... Track group, 26... Sector number, 27... Check section, 50 ...ID flag,
51...Synchronization unit, 52...Data, 53...Error correction unit, 54...Data flag.

Claims (1)

[Scope of Claims] 1. In a data recording method on a disk-shaped recording medium in which tracks for recording data are arranged in a spiral, a point that intersects a straight line extending from the center of the spiral to the outer circumference through the recording start position. A data recording method characterized in that the recording operation is ended by recording up to the point before the recording operation, and in a rotational operation immediately following the recording operation, a data access mechanism is moved to reproduce data from the recording start position. 2. In the data recording method according to claim 1, when a defect is detected in an area where data has already been written by the reproducing operation, the data to be recorded in the defective area is transferred to an area after the recording end position. A data recording method characterized by recording.