JP4265069B2 - Optical rotary recording medium, ID information reproducing apparatus, and ID information reproducing method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical rotary recording medium such as a magneto-optical disk and an optical disk, an optical ID information reproducing apparatus for reading and restoring ID information (address information) from such an optical rotary recording medium, and a method therefor.
[0002]
[Prior art]
FIG. 7 is a diagram illustrating an outline of the magneto-optical disk.
FIG. 8 is a partially enlarged view of the magneto-optical disk illustrated in FIG.
The land Land and the groove Groove are formed adjacent to each other, and are continuously formed in a spiral from the center of the magneto-optical disk toward the outer edge. In the case of the illustrated CAV type magneto-optical disk, each of the land Land and the groove Groove has a header header at an equal angle, and address information Address for indicating the position is recorded in each header header. Yes.
[0003]
Compared to recording media such as magnetic disks, optical rotary recording media such as optical disks and magneto-optical disks have more defects. If there is a defect in the address information Address, subsequent access to the data recording unit becomes impossible. For this reason, various measures are taken in order to improve the reliability of the address information Address.
[0004]
FIG. 9A is an enlarged view illustrating only adjacent land portions of the magneto-optical disk illustrated in FIG.
In FIG. 9A, in each land portion, an address area (header header) LA11 and a recording area (disk area) LD11 are continuous.
[0005]
FIG. 9B is a diagram illustrating an example recorded in the address area (header header) LA11 in the land portion illustrated in FIG. 9A.
FIG. 9C is a diagram illustrating another example recorded in the address area in the land portion illustrated in FIG. 9A.
The symbols in FIGS. 9B and 9C mean the following.
[0006]
[Table 1]
Table 1
SM: Sector mark
VFO (Variable Frequency Oscillation): Variable frequency oscillation code
AM (Address Mark): Address mark
Land ID: ID information corresponding to the land part
CRC (Cyclic Redundancy Code): Cyclic redundancy code (error detection code)
PA (Post Amble): Post-amble (for example, a code for terminating (1,7) modulation rule without shortage)
[0007]
In FIG. 9B, the sector mark SM, [first VFO, first address mark AM1, first land ID information ID11, first CRC], [second VFO, second Address mark AM2, second land ID information ID11, second CRC] and PA are recorded.
The first VFO and the second VFO can be the same code. The first address mark AM1 serves as a synchronization signal when demodulating the first land ID information ID11. Similarly, the second address mark AM2 serves as a synchronization signal when demodulating the second land ID information ID11. The first ID information and the second ID information are the same value. Both the first address mark AM1 and the second address mark AM1 are used as synchronization signals, and they can have the same data pattern.
[0008]
In FIG. 9C, [VFO, address mark AM, land ID information ID11, CRC], PA are recorded in the address area.
[0009]
FIG. 9C shows an example in which only one land ID information is recorded, such as when the length of the address area cannot be secured sufficiently. FIG. 9B shows an example in which two pieces of the same ID information are recorded at a predetermined interval.
In the illustrated example of FIG. 9B, two pieces of land ID information are recorded at a predetermined interval. For example, even if ID information is destroyed due to scratches on the magneto-optical disk, Since the ID information remains intact without being damaged, the reliability of reproducing the ID information is increased.
In the example illustrated in FIG. 9B, the first address mark AM1 used as the first synchronization signal is recorded immediately before the first ID information ID11, and immediately before the second ID information ID11. A second address mark AM2 used as a second synchronization signal is recorded.
[0010]
[Problems to be solved by the invention]
In the example illustrated in FIG. 9C, when not only the land ID information ID11 is destroyed but also the address mark AM used as a synchronization signal is destroyed, the land ID information cannot be demodulated and reproduced. . Thus, the importance of the address mark AM used as a synchronization signal is high.
[0011]
In the example illustrated in FIG. 9B, for example, if the first address mark AM1 cannot be detected normally, and if the second address mark AM2 can be detected normally, the second land ID information ID11 recorded after that can be detected. ID information can be reproduced.
Alternatively, in the example illustrated in FIG. 9B, when the first address mark AM1 is normally detected but the first ID information ID11 is not demodulated normally, the second address mark AM2 is the same as described above. Can be detected normally, the second land ID information ID11 recorded thereafter can be demodulated and the ID information can be reproduced.
[0012]
However, in the above-described example, when the second address mark AM2 cannot be detected normally, the ID information cannot be demodulated and reproduced.
[0013]
As a countermeasure in such a case, for example, one or more data sets of [VFO, address mark AM, land ID information ID, CRC] illustrated in FIG. 9B are recorded in the address area of the magneto-optical disk. do it. However, the amount of data that can be stored in the address area is naturally limited. When the data storage area of the address area is expanded, the data area is naturally narrowed, and the amount of data that can be recorded on the magneto-optical disk is reduced.
[0014]
For example, as an example of a magneto-optical disk, recently, for example, the applicant of the present application on June 22, 1999 under the technical background such as practical application of blue laser and improvement of recording density of the magneto-optical disk. As presented in Japanese Patent Application No. 11-176029, “Optical Recording Medium and Disc Cartridge” filed, ultra-compact, high-density, large capacity with a diameter of about 35 mm to 65 mm and a storage capacity of 2 GB to 4 GB. For example, the number of times the ID information is written a plurality of times is limited only to improve the reliability of the ID information.
[0015]
However, for example, since defects also occur in such an ultra-small magneto-optical disk, an effective method for improving the reliability of reproduction of ID information (address information) is devised under the above-described circumstances (restrictions). Is desired.
Of course, such a problem is not limited to the above-described ultra-small magneto-optical disk, but should also be improved for existing magneto-optical disks and optical disks.
[0016]
Moreover, although the example mentioned above described ID information of a land part, it is the same also about ID information of a groove part.
[0017]
A first object of the present invention is to provide an optical rotary recording medium that can improve the reliability of demodulation and reproduction of ID information, in particular, detection of a synchronization signal, without greatly expanding the address information area (header area). There is to do.
A second object of the present invention is to provide an ID information reproducing apparatus and method capable of effectively demodulating and reproducing ID information from such an optical rotary recording medium.
[0018]
[Means for Solving the Problems]
  According to the present invention,Land and / or grooveOf an optical rotary recording medium havingIn one address information recording area,Along the rotation direction of the optical rotary recording medium,For one piece of ID information,A first synchronization signal, ID information,At a position separated from the estimated distance at which the defect occurs in the optical rotary recording medium with respect to the position where the first synchronization signal is recorded.Second synchronization signalAnd thisIn orderAnd the first synchronization signal, the ID information, and the second synchronization signal are recorded as at least one set,
  The first synchronization signal recorded at a position before the ID information along the rotation direction of the optical rotary recording medium is a synchronization signal used for demodulating the ID information;
  The second synchronization signal recorded at a position after the ID information along the rotation direction of the optical rotary recording medium is the ID when the first synchronization signal cannot be detected normally. A synchronization signal used for demodulating information.
  An optical rotary recording medium is provided.
  By recording a plurality of synchronization signals, the reliability of detection of the synchronization signals is improved. Since the data amount of the synchronization signal is shorter than the data amount of the ID information, the reliability of reproducing the ID information can be improved with a small amount of data. As a result, the adverse effect of reducing the data storage area is small.
[0019]
  the aboveAs the optical rotary recording medium, various optical rotary recording media such as a magneto-optical disk using light and magnetism, a phase change disk using only light, a read-only optical disk, and a CD are targeted. In this specification, these are collectively referred to as an optical rotary recording medium.
[0020]
  The second synchronization signal is located at a position away from an estimated distance at which a defect occurs in the optical rotary recording medium with respect to a position where the first synchronization signal is recorded.By recording, scratches and other continuous lengths of flaws, dust and other deposits are eliminated as much as possible.It becomes possible.
  The estimated distance at which a defect occurs is statistically within a normal scratch length and is an allowable distance within the address area of the optical rotary recording medium.
[0021]
  Preferably, the first synchronization signal and the second synchronization signal have different signal patterns. This is for facilitating identification of the pattern of the synchronization signal.
  Preferably, when there are a plurality of sets of the first synchronization signal, the ID information, and the second synchronization signal, an area in which information of each set of the plurality of sets is recorded. A signal for performing phase synchronization is recorded at the previous position.
[0026]
  Also according to the invention,Land and / or grooveOf an optical rotary recording medium havingIn one address information recording area,Along the rotation direction of the optical rotary recording medium,
    A first synchronization signal;
    First ID information,
    A second synchronization signal,
    Second ID information,
    Common auxiliary sync signal
  In the above order,Recorded,
  The common auxiliary synchronization signal is separated from an estimated distance at which a defect occurs in the optical rotary recording medium with respect to a position where the first synchronization signal is recorded and a position where the second synchronization signal is recorded. Is recorded at the position
  In order to demodulate the first ID information, the first synchronization signal recorded at a position before the position where the first ID information is recorded along the rotation direction of the optical rotary recording medium. A synchronization signal to be used,
  The common auxiliary synchronization signal recorded at a position after the position where the first synchronization signal is recorded along the rotation direction of the optical rotary recording medium is normally detected by the first synchronization signal. A synchronization signal used to demodulate the first ID information when it is not possible,
  The second synchronization signal recorded at a position before the position where the second ID information is recorded along the rotation direction of the optical rotary recording medium is the first synchronization signal or the common synchronization signal. A synchronization signal used to demodulate the second ID information when the demodulation of the first ID information performed when the auxiliary synchronization signal is normal is not successful;
  The common auxiliary synchronization signal recorded at a position after the position where the first synchronization signal is recorded along the rotation direction of the optical rotary recording medium is normally detected by the second synchronization signal. A synchronization signal used to demodulate the second ID information if it is not possible,
  An optical rotary recording medium is provided.
[0027]
  Preferably,SaidCommonThe signal pattern of the auxiliary synchronization signal is the first pattern.Sync signalandAboveSecond synchronization signaleachIt is different from the signal pattern.Sync signalThis is to facilitate identification.
[0028]
  According to the present invention,Land and / or grooveOf an optical rotary recording medium havingIn one address information recording area, a plurality of synchronization signals for one ID informationKeep the recording position apartThe ID information is read from the recorded optical rotating recording medium.Read ID informationMeans,AboveStorage means for storing the ID information read by the ID information reading means and data including the plurality of synchronization signals in the order of reading, synchronization signal detection means for detecting the plurality of synchronization signals, and the detected synchronization If one of the signals is normal, the ID information stored in the storage meansDemodulating means for demodulatingAnd comprising,An ID information reproducing apparatus is provided.
  A storage means is provided for reading and temporarily storing data including ID information and a plurality of synchronization signals. By using such a storage means as a data buffer, the recording position of the synchronization signal can be made arbitrary. In other words, the reading position of the synchronization signal is not restricted by the order of signal processing.
  When the synchronization signal recorded before the recording position of the ID information is normally detected, the demodulating means demodulates the ID information with the synchronization signal and performs normal detection of such a preceding synchronization signal. Otherwise, if the synchronization signal located after the ID information is normally detected, the ID information located before the synchronization signal is demodulated. That is, in this way, in order to demodulate the ID information read earlier in time than the synchronization signal located later, the data is temporarily read and stored in the storage means.
[0029]
  Preferably, the optical rotary recording medium includes a first synchronization signal, ID information, and one ID information in one address information recording area along the rotational direction of the optical rotary recording medium. The second synchronization signal is arranged in this order at a position separated from the estimated distance at which a defect occurs in the optical rotary recording medium with respect to the position where the first synchronization signal is recorded. At least one set of a signal, the ID information, and the second synchronization signal is recorded, and is recorded at a position before the ID information along the rotation direction of the optical rotary recording medium. The first synchronization signal is a synchronization signal used for demodulating the ID information, and is recorded at a position after the ID information along the rotation direction of the optical rotary recording medium. The synchronization signal is the first synchronization signal. If can not be detected correctly, a synchronization signal used for demodulating the ID information. The storage means stores the first synchronization signal read by the ID information reading means, the ID information, and data including the second synchronization signal in the order of reading, and the demodulation means When the synchronization signal of 1 is normal, the ID information is demodulated, and the first synchronization signal cannot be detected normallyIn caseWhen the second synchronization signal is detected normally, the ID information is demodulated.
[0030]
  According to the invention, the land and / or the grooveOf an optical rotary recording medium havingIn one address information recording area,Along the rotation direction of the optical rotary recording medium, the first synchronization signal, the ID information, and the second synchronization signal are in this order.From the recorded optical rotating recording medium,Read data including the first synchronization signal, the ID information, and the second synchronization signalID informationreadingMeans and the ID information reading means,AboveA first synchronization signal;AboveID information andAboveThe data including the second synchronization signal,Storage means for storing in the order of reading;From the data stored in the storage means,The first synchronization signal andAboveSynchronization signal detecting means for detecting a second synchronization signal;AboveWhen the detected first synchronization signal is normalStorage meansInMemoryWhen the ID information is demodulated and the first synchronization signal is not detected normally,AndThe aboveWhen the second synchronization signal is detected normallyStorage meansInMemoryThe ID informationDemodulation to demodulateMeans,An ID information reproducing apparatus is provided.
[0031]
  According to the present invention,Land and / or grooveOf an optical rotary recording medium havingIn one address information recording area,Along the rotation direction of the optical rotary recording medium, the first synchronization signal, the ID information, and the second synchronization signal are in this order.From the recorded optical rotating recording medium,Read data including the first synchronization signal, the ID information, and the second synchronization signalID informationreadingRead in the process and the ID information reading process,AboveA first synchronization signal;AboveID information andAboveThe data including the second synchronization signal,A storing step for storing the reading means in the reading order;From the data stored in the storage means,The first synchronization signal andAboveA synchronization signal detection step of detecting a second synchronization signal;AboveWhen the detected first synchronization signal is normalStorage meansInMemoryThe ID informationdemodulationAnd the first synchronization signal is not normally detected.,AndThe aboveWhen the second synchronization signal is detected normallyStorage meansInMemoryThe ID informationDemodulation to demodulateProcess,An ID information reproducing method is provided.
[0032]
  According to the present invention, the first synchronization signal and the first address are recorded in one address information recording area of the optical rotary recording medium having a land and / or a groove along the rotation direction of the optical rotary recording medium. ID information, second synchronization signal and second ID information, and a common auxiliary synchronization signal are recorded in the above order, and the first ID information along the rotation direction of the optical rotary recording medium. The first synchronization signal recorded at a position before the position where the image is recorded is a synchronization signal used for demodulating the first ID information, and is along the rotation direction of the optical rotary recording medium. The second ID informationWhere is recordedPosition beforeIs recorded inThe second synchronization signal is a synchronization signal used for demodulating the second ID information, and the common auxiliary synchronization signal includes a position where the first synchronization signal is recorded and the second synchronization signal. It is recorded at a position away from an estimated distance at which a defect occurs in the optical rotary recording medium with respect to the position where the signal is recorded, and the common auxiliary synchronization signal is the first synchronization signal or the second synchronization signal. Optical synchronization recording, which is a synchronization signal used for demodulating the first ID information or the second ID information in place of the synchronization signal that cannot be normally detected when the synchronization signal cannot be normally detected. ID information reading means for reading data including the first synchronization signal, the first ID information, the second synchronization signal, the second ID information, and the common auxiliary synchronization signal from a medium ,
  Data including the first synchronization signal, the first ID information, the second synchronization signal, the first ID information, and the common auxiliary synchronization signal read by the ID information reading unit. Storage means for storing in the read order;
  Synchronization data detection means for detecting the first synchronization signal, the second synchronization signal, and the common auxiliary synchronization signal from the data stored in the storage means;
  Demodulation means
  Have
  The demodulating means includes
    Demodulating the first ID information stored in the storage means when the detected first synchronization signal is normal;
    When the first synchronization signal cannot be normally detected and the detected common auxiliary synchronization signal is normally detected, the first ID information is demodulated.,
    The detected second synchronization signal is normal when the demodulation of the first ID information performed when the first synchronization signal or the common auxiliary synchronization signal is normally detected is not successful. In such a case, the second ID information stored in the storage means is demodulated,
    When the second synchronization signal is not normally detected and the detected auxiliary synchronization signal is normally detected, the second ID information stored in the storage means is demodulated.,
  ID information playback deviceProvided.
  According to the present invention, there is also provided an ID information reproducing method in the ID information reproducing apparatus.
[0033]
DETAILED DESCRIPTION OF THE INVENTION
As the optical rotary recording medium of the present invention, various optical rotary recording media such as a magneto-optical disk using light and magnetism, a phase change disk using only light, a read-only optical disk, and a CD are targeted. In this specification, these are collectively called an optical rotary recording medium.
In the following description, as an embodiment of the optical rotary recording medium of the present invention, the above-described ultra-small magneto-optical disk capable of recording / reproducing, that is, a diameter of about 35 mm to 64 mm and a storage capacity of 2 GB or more, for example, An ultra-compact, high-density, large-capacity magneto-optical disk that realizes 2 GB to 4 GB will be exemplified.
[0034]
FIG. 1A is an enlarged view of a land portion in the magneto-optical disk illustrated in FIGS. 7 and 8 corresponding to the diagram illustrated in FIG. 9A. The contents illustrated in FIG. 9A have been described above with reference to FIGS. Since the contents of the illustration in FIG. 1A are the same as the contents of the illustration in FIG. 9A, description of the contents of the illustration in FIG. 1A is omitted.
Also in this embodiment, a magneto-optical disk using a land portion is illustrated, but a magneto-optical disk using a groove portion instead of a land portion may be used, or light using both a land portion and a groove portion. A magnetic disk may be used.
[0035]
FIGS. 1B to 1C illustrate address information recording formats as the first and second embodiments of the optical rotary recording medium of the present invention corresponding to the diagram illustrated in FIG. 9B. FIG. FIG. 1 (D) is a diagram illustrating a recording format of address information as a third embodiment of the optical rotary recording medium of the present invention corresponding to the diagram illustrated in FIG. 9 (C). The contents of these illustrations will be described in detail.
[0036]
FIG. 2 is a block diagram showing an embodiment of an ID information reproducing apparatus in a magneto-optical storage / reproducing apparatus according to the present invention. The magneto-optical recording / reproducing apparatus writes data to and reads data from the magneto-optical disk. It is a block diagram of an apparatus. The ID information reproducing apparatus in the present invention means an ID information reproducing part in the magneto-optical storage / reproducing apparatus described below.
[0037]
The magneto-optical recording / reproducing apparatus illustrated in FIG. 2 records data on the above-described ultra-small magneto-optical disk 1 capable of recording / reproducing, and reproduces the data recorded on the magneto-optical disk 1.
The magneto-optical recording / reproducing apparatus has a configuration in which a magneto-optical recording apparatus and a magneto-optical reproducing apparatus are combined, and as a common part thereof, a spindle motor 17, a spindle servo circuit 2 for controlling the spindle motor 17, There are a pickup 3, a servo circuit 4, an ID information decoding circuit 7, a tracking control circuit 16, and a controller 8. In the pickup 3, a laser diode, a beam splitter, an objective lens, a photo detector, etc., not shown, are accommodated.
[0038]
The parts corresponding to the magneto-optical recording apparatus are an error correction code adding circuit 9, a modulation circuit 10, a magnet drive circuit 11, an external magnetic field generating coil 5, and a laser power control circuit 6.
[0039]
The parts corresponding to the magneto-optical reproducing apparatus are a laser power control circuit 6, an equalizer 12, an RF signal binarization circuit 13, a data demodulation circuit 14, and a data error correction decoding circuit 15.
[0040]
Although the tracking control circuit 16 is provided in the magneto-optical recording / reproducing apparatus illustrated in FIG. 2, the focus control circuit is not illustrated. That is, in the present embodiment, the pickup 3 is, for example, a flying head type pickup, and the slider portion on which the objective lens is mounted floats by a predetermined distance from the magneto-optical disk 1 by the wind pressure accompanying the rotation of the magneto-optical disk 1. In this example, focus control is unnecessary. Of course, the present invention can also be applied to a pickup that performs focus control, and the presence or absence of focus control is not the subject of the present invention.
[0041]
The spindle servo circuit 2 controls the rotational speed of the spindle motor 17 to rotate the magneto-optical disk 1 at a predetermined rotational speed.
The tracking control circuit 16 positions the pickup 3 at a position to be recorded or reproduced via the servo circuit 4. The position of the pickup 3 is calculated by the ID information decoding circuit 7 with reference to the detection signal of the photodetector. Details of the configuration and operation of the ID information decoding circuit 7 will be described later.
The controller 8 manages various controls described later in the magneto-optical recording / reproducing apparatus.
[0042]
The external magnetic field generating coil 5 is positioned on the extended line of the laser beam emitted from the laser diode of the pickup 3. The output of the laser diode in the pickup 3 differs between data recording and data reproduction, but the laser power control circuit 6 controls the power.
The pickup 3 reads, for example, address information recorded as concave and convex pits on the magneto-optical disk 1 as the light intensity signal PITRF, and decodes the read signal by the ID information decoding circuit 7. That is, the ID information decoding circuit 7 decodes the track address information of the magneto-optical disk 1 and sends the position and address information to the controller 8 and the tracking control circuit 16. The controller 8 refers to such information to control data recording or data reproduction, and the tracking control circuit 16 performs positioning control of the pickup 3.
[0043]
A normal data recording operation in the magneto-optical recording / reproducing apparatus will be described.
During the data recording operation, the controller 8 activates the tracking control circuit 16. The tracking control circuit 16 controls the servo circuit 4 to position the pickup 3 at a position where data is to be recorded. When data to be recorded is input to the error correction code adding circuit 9, the error correction code adding circuit 9 adds an error correction code to the data to be recorded. The data to be recorded with the error correction code added is modulated by the modulation circuit 10. The modulation in the modulation circuit 10 is performed appropriately according to the type of the magneto-optical disk 1 or the like. For the magneto-optical disk 1, for example, 16/17 conversion is performed. Of course, other modulations, such as EFM plus modulation for DVDs, can also be performed. The magnet drive circuit 11 generates an external magnetic field so that a magnetic field having positive and negative polarities is generated in the recording film of the magneto-optical disk 1 according to the polarity of data to be recorded modulated by the modulation circuit 10, that is, 1 or 0. The generating coil 5 is driven. At this time, the controller 8 instructs the laser power control circuit 6 to put the laser diode in the pickup 3 into a high output drivable state where data can be recorded, and the laser diode in the pickup 3 is driven in a high output state. A recording mark corresponding to the polarity of the magnetic field generated by the external magnetic field generating coil 5 is formed on the recording film of the magneto-optical disk 1 by the high-power laser diode beam.
[0044]
A normal data reproducing operation in the magneto-optical recording / reproducing apparatus will be described.
During the data reproduction operation, the controller 8 activates the tracking control circuit 16. The tracking control circuit 16 controls the servo circuit 4 to position the pickup 3 at a position where data is to be reproduced. An RF signal of a magneto-optical signal (MO signal) recorded on the magneto-optical disk 1 is generated by a detector in the pickup 3 and is input to the equalizer 12 for waveform shaping (equalization). The output signal of the equalizer 12 is subjected to binary comparison in the RF signal binarization circuit 13 and is identified as a digital signal of 1 or 0. The data demodulating circuit 14 performs processing reverse to that of the modulating circuit 10, that is, demodulation processing. The data error correction decoding circuit 15 performs error correction when there is an error in the demodulated digital signal. The data reproduced in this way is sent to an external device such as a host computer.
[0045]
As a premise for performing the above-described data recording or data reproduction, it is necessary that the pickup 3 is accurately positioned at a desired position on the magneto-optical disk 1. However, optical disks and magneto-optical disks have a high possibility of data loss due to scratches and defects, and the reliability of recorded data is low.
[0046]
Therefore, as illustrated in FIGS. 1B and 1C, two pieces of ID information (or address information) are recorded in one address area (header area).
[0047]
First embodiment
With reference to FIG. 1B, FIG. 2, FIG. 3, and FIG. 4, an optical rotary recording medium, an ID information reproducing apparatus, and a method thereof as a first embodiment of the present invention will be described.
[0048]
In one address area of the land portion of the magneto-optical disk 1 illustrated in FIG. 1B, the sector mark SM, [first VFO1, first address mark AM1, first land ID information ID11, first CRC1 and first auxiliary synchronization signal PAM1], [second VFO1, second address mark AM2, second land ID information ID11, second CRC2 and second auxiliary synchronization signal PAM2] Is recorded.
The symbols in FIG. 1B are the same as those shown in Table 1.
[0049]
Two data sets of [VFO, address mark AM, land ID information, cyclic redundancy code CRC, auxiliary synchronization signal PAM] are continuously recorded in the address area of the magneto-optical disk 1. That is, VFO, address mark AM as a synchronization signal, ID information, CRC, and auxiliary synchronization signal PAM are recorded in the address area of the magneto-optical disk 1 in succession.
As AM and PAM, a pattern that does not appear in the data pattern is used. As a modulation method, for example, a PE (phase encode) modulation method that modulates “0” → “01”, “1” → “10” is used. For example, the following data is obtained.
AM = 111000111000
RAM = 111100001100
[0050]
The VFO is, for example, a portion in which continuous data for reproducing a clock by performing phase synchronization (PLL) in the ID decoding circuit 7 illustrated in FIG. 2 continues.
The address mark AM is used as a synchronization signal in the ID information decoding circuit 7 and has a specific data pattern.
The land ID information is, for example, data indicating the ID information of the corresponding land illustrated in FIG. 1A, for example, address information, demodulated by the ID decoding circuit 7.
CRC is a cyclic redundancy code, and is used, for example, for error correction in the ID decoding circuit 7.
[0051]
In the present embodiment, the auxiliary synchronization signal PAM (PostAM) is recorded at a position after the address mark AM and ID information as the main synchronization signal, and when the address mark AM cannot be normally detected, for example, In the ID information decoding circuit 7, the synchronization signal is used in place of the address mark AM. That is, the auxiliary synchronization signal PAM is a redundant synchronization signal used when the address mark AM as the main synchronization signal cannot be detected. In the present embodiment, the reliability of the address mark AM as the main synchronization signal is improved. The data format is enhanced.
[0052]
Comparing the data format illustrated in FIG. 9B with the data format illustrated in FIG. 1B, in the data format illustrated in FIG. 1B, the address mark AM and auxiliary synchronization are provided for each ID information. A signal PAM is provided, and there is no last PA (Post Amble) in FIG. On the other hand, when compared with FIG. 9B, the data format of FIG. 9B has only one address mark AM before one ID information, and no auxiliary synchronization signal PAM.
The auxiliary synchronization signal PAM is a signal having a data pattern similar to that of the address mark AM, and the data length is significantly shorter than the ID information. Therefore, in the present embodiment, the address area is only slightly expanded, or the unused portion of the address area is used for the auxiliary synchronization signal PAM, so that the magneto-optical disk illustrated in FIG. The reliability of the synchronization signal can be increased twice with respect to one piece of ID information, and the illustrated example can increase the reliability four times because there are two pieces of ID information.
[0053]
In the present embodiment, the first ID information ID11 and the second ID information ID11 are the same ID information. Further, the first VFO1 and the second VFO2 followed by continuous data for reproducing the clock by performing phase synchronization (PLL) are the same data. Further, the first address mark AM1 and the second address mark AM2 as the synchronization signal have the same data pattern.
[0054]
There are various methods for recording such address information on the magneto-optical disk 1. For example, the above-described data (information) is recorded as pits on the magneto-optical disk 1 by a dedicated address information recording apparatus different from the magneto-optical recording / reproducing apparatus illustrated in FIG.
[0055]
Reproduction method and apparatus
Next, the apparatus and method of the first embodiment for reading and reproducing data in the address area (header area) described above with reference to FIG.
FIG. 3 is a configuration diagram of a portion related to the present embodiment of the ID information decoding circuit 7 illustrated in FIG.
The ID information decoding circuit 7 includes an ID data buffer 71, an address mark (AM) detection circuit 72, an auxiliary synchronization signal (PAM) detection circuit 73, a control circuit 74, an ID data demodulation circuit 75, and an error detection circuit 76. And have.
[0056]
The ID data buffer 71 sequentially stores the pit RF signals detected by the pickup 3 illustrated in FIG.
The ID data buffer 71 has a storage capacity capable of sequentially storing the data illustrated in FIG. The ID data buffer 71 reads the data stored by the control signal from the control circuit 74, for example, at the timing when the address mark AM or the auxiliary synchronization signal PAM is detected. Therefore, the data in the ID data buffer 71 is read at each start timing of demodulation and reproduction of ID information described below.
[0057]
The AM detection circuit 72 detects the address mark AM among the data stored in the ID data buffer 71. The AM detection circuit 72 constantly monitors the inside of the ID data buffer 71 and searches the ID data buffer 71 for a data pattern of a predetermined address mark AM. If the data pattern of the address mark AM is detected, the control circuit 74 is informed of the position.
[0058]
Similarly, the PAM detection circuit 73 detects the auxiliary synchronization signal PAM from the data stored in the ID data buffer 71. The PAM detection circuit 73 constantly monitors the inside of the ID data buffer 71 and searches for a data pattern of a predetermined auxiliary synchronization signal PAM in the ID data buffer. If the data pattern of the auxiliary synchronization signal PAM is detected, the position is taught to the control circuit 74.
[0059]
The control circuit 74 inputs the address mark AM detected by the AM detection circuit 72 and the auxiliary synchronization signal PAM detected by the PAM detection circuit 73, and demodulates the ID information in cooperation with the ID data demodulation circuit 75. The error detection circuit 76 detects whether the demodulated data is normal.
The processing of the first embodiment in the control circuit 74 and the error detection circuit 76 will be described with reference to the flowchart of FIG. Each of the control circuit 74 and the error detection circuit 76 incorporates a microcomputer, for example, and performs the process illustrated in FIG.
[0060]
Normal detection processing of first ID information
In step 01 (S01), the control circuit 74 determines whether or not the first address mark AM1 detected by the address mark (AM) detection circuit 72 is normal. If the first address mark AM1 is normal, the control circuit 74 reads the first ID information from the ID data buffer 71 and inputs it to the ID data demodulation circuit 75 in step 02 (S02). To demodulate the first ID information. In step 03 (S03), the error detection circuit 76 determines whether or not the demodulated first ID information is normal.
[0061]
If the demodulated ID information is normal, the error detection circuit 76 resets the error flag in step 04 (S04), and sends the demodulated ID information to the controller 8 and the tracking control circuit 16. The normally demodulated ID information is used for tracking control in the tracking control circuit 16.
[0062]
When the first address mark AM is detected incorrectly (impossible)
In step 01 (S01), when the control circuit 74 detects that the detection of the first address mark AM1 in the address mark (AM) detection circuit 72 is defective, the control circuit 74 in step 05 (S05) (PAM) It is determined whether or not the first auxiliary synchronization signal PAM1 detected by the detection circuit 73 is normal. When the first auxiliary synchronization signal PAM1 is normal, the control circuit 74 reads ID information from the ID data buffer 71 and inputs it to the ID data demodulation circuit 75 in step 06 (S06). 1 ID information is demodulated. In step 07 (S07), the error detection circuit 76 determines whether or not the demodulated first ID information is normal. If the demodulated first ID information is normal, the process of step 04 (S04) described above is performed. Also in this case, the first ID information is normally demodulated. That is, even if the first address mark AM1 is destroyed by scratch or the like, the first ID information can be demodulated using the first auxiliary synchronization signal PAM1.
[0063]
In the present embodiment, since the data recorded in the address area is temporarily stored in the ID data buffer 71, not only the first ID information can be demodulated after the confirmation of the first address mark AM1, but also It is possible to demodulate the first ID information by confirming normal detection of the first auxiliary synchronization signal PAM1 read after the first ID information. That is, in the present embodiment, the positions of the first address mark AM1, the first ID information, and the first auxiliary synchronization signal PAM1 are not restricted in the signal processing described above.
[0064]
When the first ID information cannot be demodulated
When the first ID information cannot be demodulated in step 03, step 05, or step 07, the control circuit 74 detects the second address mark AM2 detected by the address mark (AM) detection circuit 72 in step 08 (S08). Whether or not is normal. If the address mark AM2 is normal, the control circuit 74 reads the second ID information from the ID data buffer 71 and inputs it to the ID data demodulation circuit 75 in step 09 (S09). Is demodulated. In step 10 (S10), the error detection circuit 76 determines whether or not the demodulated second ID information is normal.
[0065]
When the demodulated second ID information is normal, the process of step 04 (S04) described above is performed. Also in this case, the second ID information is normally demodulated. That is, even if the first address mark AM1, the first ID information, the first auxiliary synchronization signal PAM, and the like are destroyed by scratches, the second address mark AM2 and the second ID information are used. 2 ID information can be demodulated. Since the second ID information is the same as the first ID information, the normally demodulated second ID information is used for tracking control in the tracking control circuit 16.
[0066]
In the case of detection failure (impossible) of the second address mark AM
When the control circuit 74 detects that the detection of the second address mark AM2 in the address mark (AM) detection circuit 72 is defective in step 08 (S08), the control circuit 74 detects the auxiliary synchronization signal in step 11 (S11). (PAM) It is determined whether or not the second auxiliary synchronization signal PAM2 detected by the detection circuit 73 is normal. When the second auxiliary synchronization signal PAM2 is normal, the control circuit 74 reads the ID information from the ID data buffer 71 and inputs it to the ID data demodulation circuit 75 in step 12 (S12). 2 ID information is demodulated. In step 13 (S13), the error detection circuit 76 determines whether or not the demodulated second ID information is normal. When the demodulated second ID information is normal, the process of step 04 (S04) described above is performed. Also in this case, the second ID information is normally demodulated. That is, even if the second address mark AM2 is destroyed by scratch or the like, the second ID information can be demodulated using the second auxiliary synchronization signal PAM2.
[0067]
When the control circuit 74 determines that the second auxiliary synchronization signal PAM2 is not normally detected in step 11, and the error detection circuit 76 determines that the ID information is not demodulated normally in step 10 or step 13 The error detection circuit 76 sets an error flag in step 14 (S14). In this case, normal ID information is not demodulated.
[0068]
As described above, in the present embodiment, (1) whether the first address mark AM1 or the first auxiliary synchronization signal PAM1 can be normally detected and the first ID information is normally demodulated (2 ) The second address mark AM2 or the second auxiliary synchronization signal PAM2 can be detected normally, and the second ID information only needs to be demodulated normally, and the reliability of demodulation of the ID information is greatly increased.
[0069]
In the present embodiment, by adding the auxiliary synchronization signal PAM having a relatively short data length, the reliability of the synchronization signal can be improved, and the address area does not need to be specially expanded. In other words, the reliability of the synchronization signal can be increased by adding a small amount of data.
[0070]
Further, in the present embodiment, since the data recorded in the address area is temporarily stored in the ID data buffer 71, not only the first ID information can be demodulated after the confirmation of the first address mark AM1, but also It is possible to demodulate the first ID information by confirming normal detection of the first auxiliary synchronization signal PAM1 read after the first ID information. That is, in the present embodiment, the positions of the first address mark AM1, the first ID information, and the first auxiliary synchronization signal PAM1 are not restricted in the signal processing described above. Similarly, the positional relationship among the second address mark AM2, the second ID information, and the second auxiliary synchronization signal PAM2 is not restricted.
[0071]
As a result, the data format illustrated in FIG. 1B can be arbitrarily arranged as far as demodulation of ID information is concerned. The example will be described later as a second embodiment with reference to FIG.
[0072]
Data arrangement and data pattern in address area of magneto-optical disk 1
Based on the facts described above, the arrangement and pattern of data stored in one address area of the land portion of the magneto-optical disk 1 will be described.
[First VFO1, first address mark AM1, first land ID information ID11, first land, recorded in one address area of the land portion of the magneto-optical disk 1 illustrated in FIG. CRC1 and first auxiliary synchronization signal PAM1] ([second VFO2, second address mark AM2, second land ID information ID11, second CRC2 and second auxiliary synchronization signal PAM2] It is desirable that the first address mark AM1 and the first auxiliary synchronization signal PAM1 are arranged at positions separated from each other. The reason is that if they are separated by a predetermined distance, the first address mark AM1 and the first auxiliary synchronization signal PAM1 are not destroyed at the same time due to scratches and the like, and the reliability is improved. In the example illustrated in FIG. 1B, the first ID information is arranged between the first address mark AM1 and the first auxiliary synchronization signal PAM1, and the first address mark AM1 and the first auxiliary mark signal PAM1. It is separated from the one auxiliary synchronization signal PAM1 by a distance where ID information is stored.
In other words, it can be said that the first address mark AM1 and the first auxiliary synchronization signal PAM1 are distributed at positions before and after the ID information.
[0073]
It is preferable that the data patterns of the address mark AM1 and the auxiliary synchronization signal PAM1 are different. This is because the identification in the address mark (AM) detection circuit 72 and the auxiliary synchronization signal (PAM) detection circuit 73 that reads and detects data from the ID data buffer 71 becomes clear.
[0074]
Modification of the first embodiment
The auxiliary synchronization signal PAM is not limited to one, and a plurality of auxiliary synchronization signals PAM can be recorded for one ID information. Two or more auxiliary synchronization signals PAM can be recorded arbitrarily in the unused portion of the address area. In such a case, the control circuit 74 performs the process of step 05 by the number of auxiliary synchronization signals PAM.
[0075]
The pickup 3 in FIG. 2 corresponds to the ID information reading means of the present invention, and the ID data buffer 71 in the ID information decoding circuit 7 corresponds to the storage means of the present invention, and the address mark (AM) detection. The circuit 72 and the auxiliary synchronizing signal (PAM) detecting circuit 73 correspond to the synchronizing signal detecting means of the present invention, and the control circuit 74, the ID data demodulating circuit 75 and the error detecting circuit 76 correspond to the decoding means of the present invention. ing.
[0076]
Second embodiment
An optical rotary recording medium and ID information reproducing apparatus as a second embodiment of the present invention will be described with reference to FIGS. 1C, 2, 3 and 4.
[0077]
In one address area of the land portion of the magneto-optical disk 1 illustrated in FIG. 1C, [first VFO1, first address mark AM1, first land ID information ID11, first CRC1], [Second VFO1, second address mark AM2, second land ID information ID11, second CRC2] and [common auxiliary synchronization signal PAM] are recorded.
Compared with the data structure of FIG. 1B, the data structure illustrated in FIG. 1C has one common auxiliary synchronization signal PAM arranged at the end and records the auxiliary synchronization signal PAM for each ID information. Not done. Such data arrangement is performed, for example, when there is no data recording area in the address area. However, in order to improve the reliability of the ID information, two pieces of ID information are recorded.
[0078]
Considering the data arrangement in FIG. 1C, the first address mark AM1 and the common auxiliary synchronization signal PAM are at a distance from each other, and are not easily affected by scratches or the like at the same time. Similarly, the second address mark AM2 and the common auxiliary synchronization signal PAM are located away from each other and have a feature that they are not easily affected by scratches or the like.
[0079]
Also in the second embodiment, the first ID information ID11 and the second ID information ID11 are the same ID information as in the first embodiment. Further, the first VFO1 and the second VFO2 followed by continuous data for reproducing the clock by performing phase synchronization (PLL) are the same data. Further, the first address mark AM1 and the second address mark AM2 as the synchronization signal have the same data pattern.
[0080]
The method for recording such address information on the magneto-optical disk 1 is the same as that in the first embodiment.
[0081]
Reproduction method and apparatus
The apparatus and method of the second embodiment for reading and reproducing data in the address area (header area) described above with reference to FIG.
Also in the second embodiment, the ID information is demodulated in the magneto-optical recording / reproducing apparatus illustrated in FIG. 2 and the ID information decoding circuit 7 illustrated in FIG. However, due to the difference in data arrangement, the control circuit 74 and the error detection circuit 76 perform the processing of the flowchart illustrated in FIG. Others are the same as in the first embodiment.
[0082]
Comparing the flowchart of FIG. 5 with the flowchart of FIG. 4, in FIG. 4, the normal detection state of the first auxiliary synchronization signal PAM1 is determined in step 05, and the normal detection state of the second auxiliary synchronization signal PAM2 is determined in step 11. In FIG. 5, the determined part determines that the normal detection state of the common auxiliary synchronization signal PAM is determined in step 05a, and the normal detection state of the common auxiliary synchronization signal PAM is also determined in step 11a. It is only different. Other processes are the same as those described above with reference to FIG.
[0083]
As described above, also in the second embodiment, as in the first embodiment, (1) the first address mark AM1 or the common auxiliary synchronization signal PAM can be normally detected, and the first ID information is normal. (2) The second address mark AM2 or the common auxiliary synchronization signal PAM can be normally detected and the second ID information can be normally demodulated, and the reliability of demodulation of the ID information can be improved. Increases very much.
[0084]
The common auxiliary synchronization signal PAM is not limited to the end of the address area, and can be recorded at an arbitrary position spaced apart from the first address mark AM1 and the second address mark AM2.
[0085]
Other effects of the second embodiment are the same as the effects of the first embodiment.
[0086]
The data patterns of the address marks AM1, AM2 and the auxiliary synchronization signal PAM are preferably different. This is because the identification in the address mark (AM) detection circuit 72 and the auxiliary synchronization signal (PAM) detection circuit 73 that reads and detects data from the ID data buffer 71 becomes clear.
[0087]
Third embodiment
An optical rotary recording medium and ID information reproducing apparatus as a third embodiment of the present invention will be described with reference to FIGS. 1 (D), 2, 3 and 4. FIG.
[0088]
[VFO, address mark AM, land ID information ID11, CRC, auxiliary synchronization signal PAM] is recorded in one address area of the land portion of the magneto-optical disk 1 illustrated in FIG.
Compared with the data structures of FIGS. 1B and 1C, the data structure illustrated in FIG. 1D has ID information recorded only for one synchronization signal, and correspondingly one ID information, Only one auxiliary synchronization signal PAM is recorded. Such a data arrangement is an example when there is no margin of the data recording area in the address area or when it is desired to increase the data recording capacity of the data area (FIG. 1A). However, an auxiliary synchronization signal PAM is added to increase the reliability of the synchronization signal.
[0089]
Considering the data arrangement in FIG. 1D, the address mark AM and the auxiliary synchronization signal PAM are at positions separated from each other with the ID information interposed therebetween, and are not easily affected by scratches or the like at the same time.
[0090]
Also in the third embodiment, as in the first embodiment, the address mark AM as the synchronization signal and the auxiliary synchronization signal PAM have different data patterns.
[0091]
The method for recording such address information on the magneto-optical disk 1 is the same as that in the first embodiment.
[0092]
Reproduction method and apparatus
An apparatus and method according to a third embodiment for reading and reproducing data in the address area (header area) described above with reference to FIG.
Also in the third embodiment, the ID information is demodulated in the magneto-optical recording / reproducing apparatus illustrated in FIG. 2 and the ID information decoding circuit 7 illustrated in FIG. However, due to the difference in data arrangement, the control circuit 74 and the error detection circuit 76 perform the processing of the flowchart illustrated in FIG. Others are the same as those of the first embodiment and the second embodiment.
[0093]
Comparing the flowchart of FIG. 6 with the flowchart of FIG. 4 shows that one piece of ID information is demodulated, and therefore, only steps 01 to 07 of FIG. 4 are illustrated in FIG. The operations in steps 01 to 07 in FIG. 6 are the same as the operations described with reference to FIG.
[0094]
In the third embodiment, if the address mark AM or the auxiliary synchronization signal PAM can be detected normally and the ID information is demodulated normally, the normal ID information can be demodulated.
[0095]
Also in the third embodiment, it is preferable that the data patterns of the address mark AM and the auxiliary synchronization signal PAM are different. This is because the identification in the address mark (AM) detection circuit 72 and the auxiliary synchronization signal (PAM) detection circuit 73 that reads and detects data from the ID data buffer 71 becomes clear.
[0096]
In the above-described embodiment, the magneto-optical disk 1 is exemplified as the optical rotary recording medium of the present invention. The present invention can be applied to various optical rotary recording media such as a phase change disc, a read-only optical disc, and a CD.
In the above-described embodiment, the land portion of the magneto-optical disk 1 has been described. However, the embodiment can be applied only to the groove portion or both the land portion and the groove portion.
[0097]
【The invention's effect】
According to the present invention, an optical rotary recording medium having a high synchronization signal reliability can be provided.
[0098]
Further, according to the present invention, an ID information reproducing apparatus having a high reliability and a relatively simple circuit configuration can be provided from such an optical rotary recording medium.
[0099]
Further, according to the present invention, it is possible to provide an ID information reproducing method with high reliability and relatively easy processing from such an optical rotary recording medium.
[Brief description of the drawings]
FIGS. 1A to 1D are graphs showing data arrangement in an address area of a magneto-optical disk as first to third embodiments of an optical rotary recording medium of the present invention.
FIG. 2 is a block diagram of an embodiment of an ID information reproducing apparatus of the present invention.
FIG. 3 is a configuration diagram of an ID information decoding circuit in the ID information reproducing apparatus illustrated in FIG. 2;
FIG. 4 is a flowchart showing processing as a first embodiment performed by the ID information decoding circuit illustrated in FIG. 3;
FIG. 5 is a flowchart showing processing as a second embodiment performed by the ID information decoding circuit illustrated in FIG. 3;
FIG. 6 is a flowchart showing processing as a third embodiment performed by the ID information decoding circuit illustrated in FIG. 3;
FIG. 7 is a schematic configuration diagram of a magneto-optical disk.
8 is a configuration diagram of a land portion and a groove portion of the magneto-optical disk illustrated in FIG. 7. FIG.
FIGS. 9A to 9C are graphs showing the data arrangement in the address area of the magneto-optical disk illustrated in FIG.
[Explanation of symbols]
1. Magneto-optical disk 1
2. Spindle servo circuit
3. Pickup
4. Servo circuit
5. Coil for generating external magnetic field
6. Laser power control circuit
7. ID information decoding circuit
71..ID data buffer
72 .. Address mark (AM) detection circuit
73 .. Auxiliary synchronization signal (PAM) detection circuit
74 .. Control circuit
75..ID data demodulation circuit
76..Error detection circuit
8. Controller
9. Error correction code addition circuit
10. Modulation circuit
11. Magnet drive circuit
12. Equalizer
13. RF signal binarization circuit
14. Data demodulating circuit
15..Data error correction decoding circuit
16 .. Tracking control circuit
17. Spindle motor

Claims (14)

Land, and / or, in one address information recording region of an optical rotating recording medium having a groove, along a rotational direction of the rotary optical recording medium, with respect to one ID information, the first synchronization signal, The ID information and the second synchronization signal at a position separated from the estimated distance at which the defect occurs in the optical rotary recording medium with respect to the position where the first synchronization signal is recorded , in this order , and The first synchronization signal, the ID information, and the second synchronization signal are recorded as at least one set,
The first synchronization signal recorded at a position before the ID information along the rotation direction of the optical rotary recording medium is a synchronization signal used for demodulating the ID information;
The second synchronization signal recorded at a position after the ID information along the rotation direction of the optical rotary recording medium is the ID when the first synchronization signal cannot be detected normally. A synchronization signal used for demodulating information.
Optical rotating recording medium. The first synchronization signal and the second synchronization signal have different signal patterns.
The optical rotary recording medium according to claim 1 . When there are a plurality of sets of the first synchronization signal, the ID information, and the second synchronization signal, the information is recorded at a position in front of the area where each set of information of the plurality of sets is recorded. , The signal for phase synchronization is recorded,
The optical rotary recording medium according to claim 1 . In the one-address information recording area of the optical rotary recording medium having lands and / or grooves , along the rotation direction of the optical rotary recording medium,
A first synchronization signal;
First ID information,
A second synchronization signal,
Second ID information,
Common auxiliary sync signal
Are recorded in the above order ,
The common auxiliary synchronization signal is separated from an estimated distance at which a defect occurs in the optical rotary recording medium with respect to a position where the first synchronization signal is recorded and a position where the second synchronization signal is recorded. Is recorded at the position
In order to demodulate the first ID information, the first synchronization signal recorded at a position before the position where the first ID information is recorded along the rotation direction of the optical rotary recording medium. A synchronization signal to be used,
The common auxiliary synchronization signal recorded at a position after the position where the first synchronization signal is recorded along the rotation direction of the optical rotary recording medium is normally detected by the first synchronization signal. A synchronization signal used to demodulate the first ID information when it is not possible,
The second synchronization signal recorded at a position before the position where the second ID information is recorded along the rotation direction of the optical rotary recording medium is the first synchronization signal or the common synchronization signal. A synchronization signal used to demodulate the second ID information when the demodulation of the first ID information performed when the auxiliary synchronization signal is normal is not successful;
The common auxiliary synchronization signal recorded at a position after the position where the first synchronization signal is recorded along the rotation direction of the optical rotary recording medium is normally detected by the second synchronization signal. A synchronization signal used to demodulate the second ID information if it is not possible,
Optical rotating recording medium. The signal pattern of the common auxiliary synchronization signal is different from the first synchronization signal and the second synchronization signal each signal pattern,
The optical rotary recording medium according to claim 4 . From an optical rotary recording medium in which a plurality of synchronization signals are recorded with one recording information separated from each other in one address information recording area of an optical rotary recording medium having lands and / or grooves. ID information reading means for reading the ID information ;
Storage means for storing in the order read out data including the ID information and the plurality of synchronization signals read by the ID information reading means,
Synchronization signal detecting means for detecting the plurality of synchronization signals;
Demodulating means for demodulating ID information stored in the storage means when one of the detected synchronizing signals is normal,
ID information reproducing apparatus. The optical rotary recording medium is
The position where the first synchronization signal, the ID information, and the first synchronization signal are recorded for one ID information in the one address information recording area along the rotational direction of the optical rotary recording medium. In this order, the second synchronization signal is located at a position separated from the estimated distance at which a defect occurs in the optical rotary recording medium, and the first synchronization signal, the ID information, and the second synchronization signal. At least one set is recorded with one set of signals.
The first synchronization signal recorded at a position before the ID information along the rotation direction of the optical rotary recording medium is a synchronization signal used for demodulating the ID information;
The second synchronization signal recorded at a position after the ID information along the rotation direction of the optical rotary recording medium is the ID when the first synchronization signal cannot be detected normally. A synchronization signal used to demodulate information,
The storage means stores the first synchronization signal read by the ID information reading means, the ID information, and the data including the second synchronization signal in the order of reading,
The demodulating means includes
Demodulate the ID information if the first synchronization signal is normal ;
Demodulating the ID information when the first synchronization signal is not normally detected and the second synchronization signal is normally detected;
The ID information reproducing device according to claim 6. The signal pattern of the first synchronization signal and the second synchronization signal is different,
The synchronization signal detecting means identifies the first synchronization signal or the second synchronization signal based on a signal pattern difference between the first synchronization signal and the second synchronization signal ;
The ID information reproducing device according to claim 7. In the 1-address information recording area of the optical rotary recording medium having lands and / or grooves , the first synchronization signal, the ID information, and the second synchronization signal are provided along the rotation direction of the optical rotary recording medium. ID information reading means for reading data including the first synchronization signal, the ID information and the second synchronization signal from the optical rotary recording medium recorded in this order ;
Read out by the ID information reading means, said first synchronizing signal, the data including the ID information and the second synchronization signals, storage means for storing in the order read,
From the data stored in the storage means, and the synchronization signal detection means for detecting the first synchronization signal and the second synchronization signal,
When the detected first synchronization signal is normal, the ID information stored in the storage means is demodulated ; when the first synchronization signal is not normally detected ; and when the second synchronization signal is comprising a demodulating means for demodulating the ID information stored in said storage means when it is detected properly, the ID information reproducing apparatus. Unlike the signal pattern of the first synchronization signal and the second synchronization signal,
The synchronization signal detection unit identifies the first synchronization signal or the second synchronization signal based on a signal pattern difference between the first synchronization signal and the second synchronization signal.
The ID information reproducing device according to claim 9 . In the 1-address information recording area of the optical rotary recording medium having lands and / or grooves , the first synchronization signal, the ID information, and the second synchronization signal are provided along the rotation direction of the optical rotary recording medium. ID information reading step of reading data including the first synchronization signal, the ID information, and the second synchronization signal from the optical rotary recording medium recorded in this order ;
Read out by the ID information reading process, a storage step in which the first synchronization signal, the data including the ID information and the second synchronization signal in the storage means in the order read,
From the data stored in the storage means, and the synchronization signal detection step of detecting the first synchronization signal and the second synchronization signal,
When the detected first synchronization signal is normal, the ID information stored in the storage means is demodulated ; when the first synchronization signal is not normally detected ; and when the second synchronization signal is If it is detected properly, comprising a demodulation step for demodulating the ID information stored in the storage means, ID information reproducing method. Unlike the signal pattern of the first synchronization signal and the second synchronization signal,
In the step of detecting the synchronization signal, the first synchronization signal or the second synchronization signal is identified based on a signal pattern difference between the first synchronization signal and the second synchronization signal.
The ID information reproducing method according to claim 11 . The first synchronization signal and the first ID information, the second ID, and the second address information recording area of the optical rotary recording medium having a land and / or a groove along the rotational direction of the optical rotary recording medium. A position where the synchronization signal, the second ID information, and the common auxiliary synchronization signal are recorded in the above order, and the first ID information is recorded along the rotation direction of the optical rotary recording medium. The first synchronization signal recorded at a position before the first ID signal is a synchronization signal used for demodulating the first ID information, and the second ID along the rotation direction of the optical rotary recording medium. The second synchronization signal recorded at a position before the position where the information is recorded is a synchronization signal used for demodulating the second ID information, and the common auxiliary synchronization signal is the second synchronization signal. 1 sync signal is recorded Is recorded at a position separated from an estimated distance at which a defect occurs in the optical rotary recording medium with respect to a position where the second synchronization signal is recorded, and the common auxiliary synchronization signal is In order to demodulate the first ID information or the second ID information in place of the synchronization signal that cannot be normally detected when the first synchronization signal or the second synchronization signal cannot be normally detected. From the optical rotary recording medium, which is a synchronization signal to be used, the first synchronization signal, the first ID information, the second synchronization signal, the second ID information, and the common auxiliary synchronization signal ID information reading means for reading out the data to be included;
Data including the first synchronization signal, the first ID information, the second synchronization signal, the first ID information, and the common auxiliary synchronization signal read by the ID information reading unit. Storage means for storing in the read order;
Synchronization data detection means for detecting the first synchronization signal, the second synchronization signal, and the common auxiliary synchronization signal from the data stored in the storage means;
Demodulation means
Have
The demodulating means includes
Demodulating the first ID information stored in the storage means when the detected first synchronization signal is normal;
If the detected common auxiliary synchronization signal can be detected normally when the first synchronization signal cannot be detected normally, the first ID information is demodulated ,
The detected second synchronization signal is normal when the demodulation of the first ID information performed when the first synchronization signal or the common auxiliary synchronization signal is normally detected is not successful. In such a case, the second ID information stored in the storage means is demodulated,
The second ID information stored in the storage means is demodulated when the detected auxiliary synchronization signal is normally detected when the second synchronization signal is not normally detected ;
ID information reproducing apparatus. The first synchronization signal and the first ID information, the second ID, and the second address information recording area of the optical rotary recording medium having a land and / or a groove along the rotational direction of the optical rotary recording medium. A position where the synchronization signal, the second ID information, and the common auxiliary synchronization signal are recorded in the above order, and the first ID information is recorded along the rotation direction of the optical rotary recording medium. The first synchronization signal recorded at a position before the first ID signal is a synchronization signal used for demodulating the first ID information, and the second ID along the rotation direction of the optical rotary recording medium. The second synchronization signal recorded at a position before the position where the information is recorded is a synchronization signal used for demodulating the second ID information, and the common auxiliary synchronization signal is the second synchronization signal. 1 sync signal is recorded Is recorded at a position separated from an estimated distance at which a defect occurs in the optical rotary recording medium with respect to a position where the second synchronization signal is recorded, and the common auxiliary synchronization signal is In order to demodulate the first ID information or the second ID information in place of the synchronization signal that cannot be normally detected when the first synchronization signal or the second synchronization signal cannot be normally detected. From the optical rotary recording medium, which is a synchronization signal to be used, the first synchronization signal, the first ID information, the second synchronization signal, the second ID information, and the common auxiliary synchronization signal An ID information reading step of reading out the data to be included;
Data including the first synchronization signal, the first ID information, the second synchronization signal, the first ID information, and the common auxiliary synchronization signal read in the ID information reading step A storage step of storing the data in the storage means in the read order;
A synchronization signal detection step of detecting the first synchronization signal, the second synchronization signal and the common auxiliary synchronization signal from the data stored in the storage means;
Demodulation process
Have
In the demodulation step,
Demodulating the first ID information stored in the storage means when the detected first synchronization signal is normal;
If the detected common auxiliary synchronization signal can be detected normally when the first synchronization signal cannot be detected normally, the first ID information is demodulated ,
The detected second synchronization signal is normal when the demodulation of the first ID information performed when the first synchronization signal or the common auxiliary synchronization signal is normally detected is not successful. In such a case, the second ID information stored in the storage means is demodulated,
Demodulating the second ID information stored in the storage means when the detected auxiliary synchronization signal is normally detected when the second synchronization signal is not normally detected;
ID information reproduction method.

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