JP2010055663A - Optical disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve reliability of data in an optical disk device. <P>SOLUTION: An optical disk 10 is divided into an inner peripheral area and an outer peripheral area. When data 100 is recorded in the inner area, backup data 200 of the data 100 is recorded in the outer peripheral area. When the data 100 in the inner peripheral area cannot be read, the backup data 200 of the outer peripheral area is read. The data 100 is repaired by overwriting the data 100 in the inner peripheral area with the backup data 200. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an optical disk device, and more particularly to recording of backup data.

  Conventionally, it has been proposed to record backup data at different positions on a disk when recording data in order to prevent the data from being unreadable due to a defect occurring on the disk.

  Patent Document 1 below discloses recording backup data at a position separated by a predetermined rotation angle of the same disk, for example, an angle of 180 degrees. FIG. 6 shows the recording position of backup data according to this prior art. The backup data 200 is recorded at a position separated from the original data 100 by 180 degrees. By separating the back data 200 from the original data 100 as much as possible, it is possible to prevent the backup data 200 from being lost at the same time when the original data is lost.

  Patent Document 2 below discloses that one track is divided in half, and sectors A to L are recorded on one side and redundant sectors Ar to Lr are recorded on the other side. It is assumed that the redundant sector has a phase difference of 180 degrees.

JP-A-4-178975 Japanese Patent No. 2858528

  However, when the backup data or redundant tracks are formed at positions separated by an angle of 180 degrees, the data should be recorded in order from the inner periphery side, because the data is recorded in a different order or position. The need to change the existing file system arises.

  An object of the present invention is to provide an optical disc apparatus capable of improving data reliability by recording backup data at different positions on the same disc without affecting an existing file system.

  The present invention is an optical disc apparatus for recording backup data having the same contents as the data at different positions on the optical disc when data is recorded on the optical disc, and the optical disc is divided into at least an inner peripheral area and an outer peripheral area, Recording means is provided for recording the data in an inner peripheral area and recording the backup data in an outer peripheral area.

  In one embodiment of the present invention, the recording means sets the data to a sector number n (n = 1, 2,..., E / 2-1), where E is the number of sectors of the optical disk. The backup data is recorded in sector number n + E / 2.

  Further, in another embodiment of the present invention, when the data in the inner peripheral area cannot be reproduced, there is provided reproducing means for reproducing the backup data in the outer peripheral area, and the data in the inner peripheral area is overwritten with the backup data. It has a repair means to repair by doing.

  According to the present invention, it is possible to improve data reliability without affecting the file system of sequentially recording data from the inner circumference side.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The optical disc apparatus according to the present embodiment is applied to a medical image recording management system and the like in which data reliability is important.

  FIG. 1 shows the overall configuration of the optical disc apparatus according to this embodiment. An optical disk 10 such as a DVD-RW or a DVD-RAM is driven by a spindle motor (SPM) 12. The spindle motor SPM 12 is driven by a driver 14, and the driver 14 is servo-controlled by a servo processor 30 so as to have a desired rotation speed.

  The optical pickup 16 includes a laser diode (LD) for irradiating the optical disk 10 with laser light and a photodetector (PD) that receives reflected light from the optical disk 10 and converts it into an electrical signal, and is disposed opposite to the optical disk 10. . The optical pickup 16 is driven in the radial direction of the optical disk 10 by a sled motor 18 constituted by a stepping motor, and the sled motor 18 is driven by a driver 20. The driver 20 is servo-controlled by the servo processor 30 similarly to the driver 14. The LD of the optical pickup 16 is driven by a driver 22, and the driver 22 is controlled by an auto power control circuit (APC) 24 so that the drive current becomes a desired value. The APC 24 and the driver 22 control the light emission amount of the LD according to a command from the system controller 32. In FIG. 1, the driver 22 is provided separately from the optical pickup 16, but the driver 22 may be mounted on the optical pickup 16.

  When data recorded on the optical disk 10 is reproduced, a laser beam of reproduction power is irradiated from the LD of the optical pickup 16, and the reflected light is converted into an electric signal by the PD and output. A reproduction signal from the optical pickup 16 is supplied to the RF circuit 26. The RF circuit 26 generates a focus error signal and a tracking error signal from the reproduction signal and supplies them to the servo processor 30. The servo processor 30 servo-controls the optical pickup 16 based on these error signals, and maintains the optical pickup 16 in an on-focus state and an on-track state. Further, the RF circuit 26 supplies an address signal included in the reproduction signal to the address decoding circuit 28. The address decoding circuit 28 demodulates the address data of the optical disk 10 from the address signal and supplies it to the servo processor 30 and the system controller 32. Further, the RF circuit 26 supplies the reproduction RF signal to the binarization circuit 34. The binarization circuit 34 binarizes the reproduction signal and supplies the obtained signal to the encoding / decoding circuit 36. The encode / decode circuit 36 demodulates the binary signal and corrects errors to obtain reproduction data, and outputs the reproduction data to a host device such as a personal computer via the interface I / F 40. When the reproduction data is output to the host device, the encoding / decoding circuit 36 temporarily stores the reproduction data in the buffer memory 38 and outputs it.

  When data is recorded on the optical disk 10, data to be recorded from the host device is supplied to the encode / decode circuit 36 via the interface I / F 40. The encode / decode circuit 36 stores data to be recorded in the buffer memory 38, encodes the data to be recorded, and supplies the data to the write strategy circuit 42 as modulated data. The write strategy circuit 42 converts the modulation data into a multi-pulse (pulse train) according to a predetermined recording strategy, and supplies it to the driver 22 as recording data. Since the recording strategy affects recording quality, optimization is performed prior to data recording. The laser light whose power is modulated by the recording data is irradiated from the LD of the optical pickup 16 and the data is recorded on the optical disk 10. The recording power during data recording is optimized by trial writing test data using a PCA (Power Calibration Area) formed on the inner circumference side of the optical disc 10 by OPC (Optical Power Control). . After recording the data, the optical pickup 16 reproduces the recorded data by irradiating a laser beam with a reproduction power, and supplies it to the RF circuit 26. The RF circuit 26 supplies the reproduction signal to the binarization circuit 34, and the binarized data is supplied to the encode / decode circuit 36. The encoding / decoding circuit 36 decodes the modulated data and collates it with the recording data stored in the buffer memory 38. The result of the verification is supplied to the system controller 32. The system controller 32 determines whether to continue recording data or execute a replacement process according to the result of verification. The system controller 32 controls the operation of the entire system, drives the sled motor 18 via the servo processor 30, and controls the position of the optical pickup 16. Further, the system controller 32 optimizes the recording power by controlling the OPC.

  In such a configuration, when recording data, the system controller 32 divides the optical disc 10 into two parts, an inner peripheral area and an outer peripheral area, records data in the inner peripheral area, and has the same contents as the data in the outer peripheral area. Record the backup data. Specifically, when data is recorded in units of sectors of the optical disc 10, assuming that the first sector number is 1, the last sector number is E, and the central sector number is E / 2, sector 1 to sector E / 2 Original data is recorded as a data recording area normally used up to -1. On the other hand, the backup data is recorded using the sector E / 2 to the sector E as the backup data recording area. For example, when data is recorded in the sector 100, after data is recorded in the sector 100, backup data is recorded in the sector E / 2 + 100.

  FIG. 2 shows a data recording method of the optical disc 10 in the present embodiment. When the data 100 is recorded in a specific sector in the inner peripheral area, the backup data 200 of the data 100 is recorded in the corresponding sector in the outer peripheral area. The sector of the data 100 and the sector of the backup data 200 are offset by E / 2. By recording the data 100 in the inner peripheral area and the backup data 200 in the outer peripheral area, it is possible to prevent the data 100 and the data 200 from being lost simultaneously due to a defect of the optical disc 10.

  As described above, when the data 100 is recorded, the backup data 200 is also recorded in the sector having the offset of E / 2, thereby duplicating the data and improving the reliability. In this embodiment, the backup data 200 is recorded only in the outer peripheral area from the sector E / 2 to the sector E, and the original data 100 is sequentially only in the inner peripheral area from the sector 1 to the sector E / 2-1. Will not affect the existing file system. That is, when the data 100 is read, it may be read sequentially from the inner circumference side as before.

  3 and 4 show processing flowcharts during data recording. FIG. 3 shows a preparatory process before data recording. The system controller 32 acquires the number of sectors of the mounted optical disk 10 (S101). Then, half the sectors are calculated (S102). If the number of sectors is E, half of the sectors are E / 2, the sector that records data 100 is sector 1 to sector E / 2-1 in the inner area, and the sector that records backup data 200 is in the outer area. Sector E / 2 to sector E.

  FIG. 4 shows processing at the time of data recording. When receiving a write command from a host device such as a personal computer, the system controller 32 acquires a recorded sector (write sector) of the optical disc 10 (S201). Then, it is determined whether or not the number of recorded sectors is less than half of the total number of sectors (S202). If the recorded sector is not less than half of the total number of sectors, it is determined that there is no area in which the data 100 is to be recorded. This is because, in the present embodiment, the data 100 is recorded using half of the sectors in the inner peripheral area out of all sectors of the optical disc 10. If the recorded sector is less than half, the data 100 is recorded in an unrecorded sector in the inner peripheral area (S203). After the data 100 is recorded, the recorded data 100 is read and verified, and it is confirmed whether or not the data to be recorded matches the read data (S204). As a result of the verification, if both data match, it means that the recording of the data 100 has been completed normally, so that the corresponding sector in the outer peripheral area, that is, the sector where the data 100 was recorded is offset by E / 2. The backup data 200 is recorded in the sector (S205). The backup data 200 is verified in the same manner as the original data 100 (S206). If the data does not match as a result of verifying the original data 100 or the backup data 200, replacement recording is performed in predetermined replacement recording sectors (S207 and S208).

  FIG. 5 shows a processing flowchart during data reproduction. First, when the system controller 32 receives a read command from the host device and acquires a read sector (S301), the system controller 32 reads the data 100 from the sector in the inner peripheral area (S302). If the data 100 can be read (YES in S303), the read data 100 is transmitted to the host device, and the process ends. On the other hand, when some defect occurs in the optical disk 10 and the data 100 cannot be read (NO in S303), the system controller 32 next reads the sector in the outer peripheral area offset by E / 2 (S304). That is, when the sector to be read is A, the sector whose sector is A + E / 2 is read. If the backup data 200 can be read (YES in S305), the backup data 200 is transmitted to the host device. Further, the data 100 is restored by overwriting the data 100 in the inner peripheral area, that is, the data (unreadable data) 100 recorded in the sector A with the backup data 200 (S306). On the other hand, when the backup data 200 cannot be read (NO in S305), the process ends as a read error.

  As described above, in this embodiment, since the data 100 is recorded in the inner peripheral area and the backup data 200 is recorded in the outer peripheral area, the data can be duplicated and the data reliability can be improved. In addition, an existing file system can be used as it is, and when data is reproduced, it may be read sequentially from the inner peripheral area side as before. In this embodiment, when the data 100 in the inner peripheral area cannot be read out and the backup data 200 in the outer peripheral area can be read out, the data 100 in the inner peripheral area is restored with the backup data 200. Therefore, the reliability of the data 100 is further improved. Of course, in order to restore the data 100 in the inner peripheral area, the optical disc 10 is premised on a rewritable optical disc such as a DVD-RW or a DVD-RAM.

  In this embodiment, the optical disk 10 is divided into an inner peripheral area and an outer peripheral area, and the outer peripheral area is used as a recording area for the backup data 200. However, in the case where the data is particularly important and reliability is important, the optical disk 10 can be divided into an inner peripheral area, an intermediate peripheral area, and an outer peripheral area, and the data can be tripled by using the intermediate peripheral area and the outer peripheral area as the recording area of the backup data 200.

  In this embodiment, when the data 100 in the inner peripheral area cannot be read out and the backup data 200 in the outer peripheral area can be read out, the data 100 in the inner peripheral area is restored with the backup data 200. The user may select whether or not to repair.

  In this embodiment, verification is performed in both inner area data recording and outer area backup data recording. However, only inner area data recording is verified, and outer area backup data is recorded. It is possible not to execute verification in recording.

  In this embodiment, as a result of verifying the data in the inner peripheral area, when the data to be recorded and the read data do not match, the replacement recording is performed in a predetermined replacement recording sector. The backup data 200 may be recorded in the outer peripheral area.

  Further, in this embodiment, it is determined whether or not the inner sector data 100 has been read in S303 of FIG. 5, but this determination may be repeated a predetermined number of retries. However, in this embodiment, since the backup data 200 is recorded in the outer peripheral area, the number of retries can be reduced as compared with the conventional case. For example, the number of retries is normally set to 3 at the time of data reproduction, but in this embodiment, it can be reduced to 1 or 2 times. Of course, it is possible not to execute the retry, and it is possible to reproduce data quickly without executing the retry.

  In this embodiment, when the inner area is divided into the outer area and the outer area, the inner area is defined as sector 1 to sector E / 2-1 and the outer area is defined as sector E / 2 to sector E. The data recording area may be set larger than the backup data area, with the peripheral area as sector 1 to sector 3E / 5-1 and the outer area as 3E / 5 to sector E. In this case, data that is particularly important among the data 100 and that should be recorded simultaneously with the backup data 200 is selected. Then, the backup data 200 is recorded in the outer peripheral area only for the selected data, and the backup data 200 is not recorded for the unselected data. Thereby, a small backup data area can be used effectively.

It is a configuration block diagram of an embodiment. It is explanatory drawing which shows the relationship between the data of embodiment, and backup data. It is a processing flowchart (the 1) of an embodiment. It is a processing flowchart (the 2) of an embodiment. It is a processing flowchart (the 3) of an embodiment. It is explanatory drawing which shows the relationship between the data of a prior art, and backup data.

Explanation of symbols

  10 optical disk, 32 system controller, 100 data, 200 backup data.

Claims (4)

When recording data on an optical disk, an optical disk device that records backup data having the same content as the data at different positions on the optical disk,
An optical disc apparatus comprising: a recording unit that divides the optical disc into at least an inner peripheral area and an outer peripheral area, records the data in the inner peripheral area, and records the backup data in the outer peripheral area. The apparatus of claim 1.
The recording means records the data in a sector number n (n = 1, 2,..., E / 2-1) when the number of sectors of the optical disk is E, and stores the backup data in a sector number. An optical disc apparatus for recording at n + E / 2. The apparatus of claim 1.
An optical disc apparatus, comprising: reproducing means for reproducing backup data of the outer peripheral area when the data of the inner peripheral area cannot be reproduced. The apparatus of claim 3.
An optical disc apparatus comprising: a restoration unit that restores the backup data by overwriting the data in the inner peripheral area with the backup data.

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