JP3780585B2 - Digital signal recording / reproducing device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a digital signal recording / reproducing apparatus, and in particular, a digital signal recording / reproducing apparatus capable of eliminating the influence of fluctuations in the level of a reproduced signal on a reference value for data detection, thereby improving the reliability of data detection. About.
[0002]
[Prior art]
A magnetic field modulation method is known as one method of recording data on a magneto-optical disk which is one of data recording media. By irradiating a laser beam and applying a magnetic field, this is magnetized in the direction of the magnetic field applied when the temperature becomes equal to or higher than the Curie point. Further, when reading data, a laser beam having a predetermined polarization plane is irradiated, and the reflected light is decomposed into a P wave component and an S wave component and received. The P wave component and the S wave component have complementary intensities depending on the magnetization polarity. By subtracting the light reception results of the P wave component and the S wave component, a signal is generated according to the magnetization polarity at the irradiation position of the laser beam. A reproduction signal whose level changes (referred to as difference signal or MO signal) is obtained.
[0003]
The magneto-optical disk has a structure in which a perpendicular magnetization film is formed on a substrate such as polycarbonate. When the optical disc is formed, the thickness of the film varies, so that the birefringence changes in each part of the substrate. The magnitude of the birefringence of the substrate is not constant on the disk, and the intensity of the P wave component and the S wave component changes due to the fluctuation of the birefringence. As a result, there has been a problem that the level of the reproduced signal fluctuates.
[0004]
As one of the magneto-optical disk devices, the partial response method is applied to record digital data, and the Viterbi decoding is applied to the reproduction data, thereby increasing the data recording density and error. There is a known improvement in rate. When the direct current level of the reproduction signal input to the Viterbi decoding circuit varies due to birefringence as described above, the error in detecting reproduction data increases. Therefore, it is necessary to suppress the level fluctuation more strongly in the optical disk reproducing apparatus using the partial response method and Viterbi decoding.
[0005]
A magneto-optical disk reproducing circuit has been proposed in which a threshold for data level detection is set by a signal in a reference area provided for each sector. However, since the reference area is provided for each sector, it is insufficient to remove the DC fluctuation accompanying the birefringence fluctuation described above. Therefore, a clamping area (prewrite area PR) is provided at the head of each of the plurality of segments constituting the sector, and `0 'data is recorded in this area, and the reproduction signal low level' L 'of this prewrite area is recorded. A method of clamping the reproduction signal so that 'is constant has been proposed. The method of performing level control using the prewrite area for each segment is used in combination with level control using a reference area.
[0006]
A technique for setting the level detection threshold by the signal in the reference area will be described with reference to FIG. FIG. 12 shows an example of the recording format of the magneto-optical disk. One sector is composed of a plurality of segments, and a servo area is provided at the head of each segment as shown by the hatched area. For example, one segment in one sector is assigned to the reference area, the other one segment is assigned to the address segment, and the remaining segments are assigned to the data segment. In the servo area and the address segment, pits are formed in advance by embossing or the like. In the servo area, pits for tracking control and clock extraction are formed. A pit indicating an address such as a sector address is formed in the address segment. Data is recorded for the data segment.
[0007]
Phase reference data and level detection data are recorded in the reference area. As data for phase matching, data in which `0` and` 1` data are continuous by 2 bits is formed. The phase difference of the clock is corrected at the time of reproduction based on the data for phase matching. The data for level detection is data in which `0 'and` 1' data continue for a predetermined number of bits. The threshold at the time of data detection is set based on the reproduction result of the data for level detection.
[0008]
When the data for level detection is reproduced, a reproduction signal is obtained which is at a low level for a predetermined period corresponding to the bit “0” and then at a high level for a predetermined period corresponding to “1”. The reproduced signal is sampled by a sampling pulse formed based on the phase matching data, and signal levels L1, L2, L3, L4, H1, H2, H3, and H4 are detected. From the detection level, the following equation is calculated.
[0009]
AVLOW = (L1 + L2 + L3 + L4) / 4 (1)
AVHIGH = (H1 + H2 + H3 + H4) / 4 (2)
S = (AVHIGH−AVLOW) / 2 (3)
CEN = (AVHIGH + AVLOW) / 2 (4)
Yk = (RFk−CEN) (5)
[0010]
Through the above calculation, the low level AVLOW of the reproduction signal, the high level AVHIGH of the reproduction signal, the average amplitude S of the reproduction signal, the center level CEN of the reproduction signal, and the amplitude value Yk of the reproduction signal are obtained. Reproduction signal data detection is performed based on these values. For example, when data is recorded by NRZI, ternarization is performed using the above-described values, and Viterbi decoding is performed. Therefore, it is required that these values are not affected by direct current fluctuations due to changes in birefringence.
[0011]
In the reference area, as described above, even if the level necessary for demodulation is detected and the threshold is set, a DC fluctuation occurs after that. Therefore, as a countermeasure, a clamping area (prewrite area) is provided for each segment. Things have been proposed. The configuration of a digital clamp circuit is disclosed in Japanese Patent Laid-Open No. 7-21615, and the configuration of an analog clamp circuit that is considered to detect a direct current level without being affected by defects on the disk is disclosed in Japanese Patent Laid-Open No. 7-320402, It is disclosed in JP-A-7-334928 and JP-A-7-334929.
[0012]
FIG. 13 shows an enlarged example of the configuration of the servo area provided at the head of the data segment. In the example of FIG. 13, the servo area has a length of 24 SCK (SCK means a servo clock generated based on a read signal of the servo area). When the positions defined by the servo clock are represented by the first, second, third,..., 24th positions, segment marks are formed using the seventh position from the third position. A mark 1 is formed at the 11th and 12th positions, and a mark 2 is formed at the 16th and 17th positions. These marks 1 and 2 are called track marks.
[0013]
The mark 1 is formed by embossing at a position shifted by 1/4 · Tp (Tp: track pitch) in one direction (for example, the inside) of the disk radial direction with respect to the track center, and the mark 2 is formed with respect to the track center. Thus, it is formed by embossing at a place shifted by 1/4 · Tp (Tp: track pitch) in the other direction (for example, the outside) of the disk radial direction. These marks 1 and 2 are wobbling pits. The reading position can be matched with the track center by controlling the reading position of the laser beam so that the level of the reproduction signal when the laser beam crosses these marks becomes equal.
[0014]
One frame is composed of a plurality of segments, for example, 14 segments. One of the 14 segments is an address segment in which address data is recorded in advance, and the other 13 segments are data segments capable of recording data. Is done. One sector has a predetermined size, for example, 2 Kbytes, and one sector includes a plurality of address segments and data segments. The segment mark is provided to identify the type of segment, and when the data segment is the head of the sector, when the data segment is the last of the sector, or otherwise.
[0015]
Further, the post write area PO (4DCK) of the data segment is positioned before the servo area, and the prewrite area PR (12DCK) of the data segment is positioned after the servo area. In the prewrite area PR, `0` data is recorded as described in the above-mentioned document. Up to the post write area PO, data is recorded on the basis of the data clock DCK. In the servo area, pits are formed in advance on the basis of the servo clock SCK. After the prewrite area PR, on the basis of the data clock DCK. Data is recorded. The grooves are provided in parallel with the tracks in the data recordable area.
[0016]
FIG. 13 also shows a reproduction RF signal in the servo area. The reproduction RF signal corresponding to the prewrite area PR becomes low level “L”, and a clamp pulse CLM1 is generated during the low level “L” period. The clamp circuit composed of an analog circuit or a digital circuit generates a low level signal. The clamping operation is performed so that 'L' becomes constant.
[0017]
[Problems to be solved by the invention]
As described above, the previously proposed clamping for each segment is to clamp the reproduction signal at a low level. As a result, the fluctuation of the low level “L” of the reproduction signal of one sector can be suppressed as shown in FIG. Further, in FIG. 14, the threshold for data detection is fixed to a predetermined value Th <sub>0</sub> set in the reference area, as indicated by a one-dot chain line. However, the gain of the reproduction signal varies due to fluctuations in the birefringence of the disk medium. In order to correctly detect data, the threshold should also change following the gain fluctuation as shown by the broken line in FIG. Therefore, the previously proposed method has a problem that the threshold important for data detection cannot be set appropriately, and the error increases. Further, in the previously proposed method of clamping for each segment, the DC level of the segment cannot be made completely constant, and a clamping error remains as shown in FIG. There is a problem that an error remaining in the characteristics of the clamp circuit is directly reflected in an error in data detection. Furthermore, there has been a problem that the fluctuation of the gain of the reproduction signal has an adverse effect on the setting of the reference value required for data detection or Viterbi decoding.
[0018]
Accordingly, an object of the present invention is to provide a digital signal recording / reproducing apparatus in which the influence of an error in a reference value remaining after clamping a reproduction signal on data detection is reduced.
[0019]
[Means for Solving the Problems]
The present invention provides a digital signal recording / reproducing apparatus having a data structure in which a sector is constituted by a plurality of segments , a clamping area is provided for each segment , and a reference area is provided for each sector .
Reading means for reading data from the recording medium;
A reproduction signal is supplied from the reading means, and the average value of the high level and low level of the reproduction signal in the reference area is used as a threshold setting value. The low level and high level are synchronized with the data clock recorded in the clamping area. Clamping means for clamping the average level of data that alternately repeats to the threshold setting value for each sector ;
Will receive a reproduced signal clamped by the clamping means has a correction means for correcting the values of the threshold and gain for each segment, and a data detector for detecting data from the corrected reproduction signal by the correction means,
The correction means detects the threshold difference between the threshold setting value and the threshold detected for each segment, and detects the gain difference between the gain setting value detected for each sector and the gain detected for each segment,
A digital signal recording / reproducing apparatus characterized by correcting a threshold for each segment with a threshold difference and correcting a gain for each segment with a gain difference .
[0020]
In the reference area, a low level and a high level are detected, and data is detected based on an intermediate threshold between these values. The gain of the reproduction signal is also used for data detection or data decoding. The first data unit (sector) is composed of a plurality of second data units (segments). Predetermined data for clamping is recorded in the clamping area of each segment. The clamp means clamps the reproduction signal so as to suppress the DC level fluctuation in each segment. In the reproduction signal after the clamping, the fluctuation of the threshold and the gain are monitored. Then, these values are corrected by adding the variation to the set threshold and gain. Therefore, it is possible to eliminate the influence of threshold and gain fluctuations on data detection.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. First, an optical disk medium according to this embodiment will be described. The optical disk is, for example, an MO (magneto-optical) disk having a diameter of 3.5 inches, and a spiral track is formed on one surface thereof. The present invention is not limited to the MO disk, and can be applied to other types of optical disk recording / reproducing devices such as phase change optical disks, and the tracks may be formed concentrically. Furthermore, the present invention can also be applied to a recording / reproducing apparatus such as an optical disc or a double-sided optical disc that has a recordable area and a reproduction-dedicated area independently on one surface of one optical disc. Furthermore, the present invention is not limited to a disk-shaped recording medium, but can also be applied to the case where a tape-shaped recording medium capable of optical recording and reproduction such as a magneto-optical tape is used. Furthermore, the present invention can be applied to a digital signal recording / reproducing apparatus using a magnetic recording medium.
[0022]
The MO disk in one embodiment of the present invention is of the sample servo system. That is, although not shown, on the disk, an address segment and a servo area are provided on each track at positions that are intermittent in the track direction and aligned in the disk radial direction. In this embodiment, the amount of user data in one sector is defined as 2 Kbytes (2,048 bytes).
[0023]
FIG. 1 shows an example of a physical data structure of data recorded on a disc in this embodiment. As shown in FIG. 1, one track is composed of 100 frames (frame 0 to frame 99), and each frame is composed of 14 segments (one address segment and 13 data segments). Therefore, one frame is 1400 segments. The head of each frame is an address segment, and the remaining 13 segments are data segments. One track includes 1300 data segments of data segment 0 to data segment 1299 and 100 address segments.
[0024]
The address segment has a length of 216 SCK with reference to the servo clock SCK. The servo area (24SCK) is located at the beginning of the segment, the next 10SCK is blank, the next 84SCK is the address area, and the ALPC (Automatic Laser Power Control) area (98SCK) is at the end of the address segment. Is provided. The address segment is previously formed on the disk by embossing or the like. The ALPC area is used to control the reading laser power to a predetermined value.
[0025]
The data segment is also the same length (216 SCK) as the address segment, and the servo area (24 SCK) formed by embossing or the like is positioned at the head. When the data clock is expressed by DCK after the servo area, a pre-write area PR having a length of 12 DCK, a data area, and a post-write area PO having a length of 4DCK are arranged.
[0026]
The prewrite area PR functions as a clamping area that secures a distance necessary for preheating the disk so as to have a stable temperature for data recording and suppresses DC fluctuation due to birefringence. The post-write area PO is provided in order to eliminate the remaining unerased recorded data during overwriting and to secure a distance that avoids data interference caused by the edge of the groove. This groove is not used for tracking control, but for reducing the adverse effects on disk forming, and has a depth of, for example, λ / 8 (λ: laser wavelength).
[0027]
FIG. 2 shows a sector format. The data of each sector includes 2,048 bytes of user data, an error correction code redundant code (256 bytes), an error detection CRC code (8 bytes), and user-defined data (40 bytes). A total of 2,352 bytes are included. Then, an address segment and 66 bytes of reference data are added in front of the data area, and one sector has a size of 2,418 bytes.
[0028]
The reference data has a 4-byte 8T pattern and a 12-byte 2T pattern repeated four times so as to indicate the waveform of the reproduced RF signal, and a 2-byte margin for setting the detected information. It consists of an all `0 'pattern. This reference data is recorded in the same manner as user data. The 2T pattern is used to correct a DC pit position shift due to a change in recording power during reproduction. The 8T pattern is used to set a threshold for detecting a ternary value of a reproduction signal.
[0029]
With reference to FIG. 3, for example, a servo area provided in a data segment will be described. As described above, the servo area has a length of 24 SCK. The post write area PO (4DCK) of the data segment is positioned before the servo area, and the prewrite area PR (12DCK) of the data segment is positioned after the servo area. Up to the post write area PO, data is recorded on the basis of the data clock DCK. In the servo area, pits are formed in advance on the basis of the servo clock SCK. After the prewrite area PR, on the basis of the data clock DCK. Data is recorded. The grooves are provided in parallel with the tracks in the data recordable area.
[0030]
The address segment and the data segment have the same servo area configuration. That is, when the position in the servo area is defined as the first position to the 24th position based on the servo clock SCK, segment marks are recorded from the third position to the seventh position, and the eleventh and twelfth positions are recorded. Mark 1 is recorded at the position, and mark 2 is recorded at the 16th and 17th positions. These marks 1 and 2 form track marks. The track mark is used for tracking error detection and clock recovery. The segment mark distinguishes between an address segment and a data segment, and distinguishes the head of the sector, the end of the sector, and other data segments.
[0031]
The reason why the length of mark 1 and mark 2 is two servo clocks is to reduce the number of mirror parts where pits are not formed, thereby making it difficult for ghost pits to occur during disk molding. This is because the reproduction RF signal is stably obtained. In addition, by separating the mark 1 and the mark 2 from each other by a predetermined interval, for example, 5 SCK or more, interference between the reproduction RF signals corresponding to the pits can be reduced.
[0032]
In the previously proposed method of clamping for each segment, data of `0 'is recorded in the prewrite area PR as shown in FIG. 13, whereas in one embodiment of the present invention, prewrite is performed. In the area PR, data of a 12-bit pattern (010101010101) in which “0” and “1” are alternately repeated in synchronization with the data clock is recorded. Therefore, the reproduction signal obtained when the prewrite area PR is read has a substantially sine wave shape. In an actual apparatus, a reproduction signal having a very low frequency close to a direct current may be generated, unlike a sine wave as shown in the figure, due to the limitation of the frequency band during reproduction.
[0033]
Since the data in the prewrite area PR is a pattern in which “0” and “1” are repeated, the average level can be made constant by a clamp circuit described later. The average level is a level detection threshold Th. The clamp circuit for each segment samples and holds the reproduction signal of the prewrite area PR. For this purpose, the sampling pulse CLM1 preferably has a pulse width of 2DCK or more in order to improve S / N. In the example of FIG. 3, a sampling pulse having a width of 4DCK is shown.
[0034]
After the clamping process performed based on the reproduction signal of the prewrite area PR, when the threshold set value set in the reference area in one sector is represented by Th <sub>0</sub> , as shown in FIG. The high level “H” and the low level “L” of the signal change around the threshold Th <sub>0</sub> . As described above, if the data pattern of the prewrite area PR is recorded so that the average value is intermediate between the high level 'H' and the low level 'L', the data pattern for level detection is not affected by the gain fluctuation. It is possible to appropriately set the threshold value. Note that the pattern of data recorded in the prewrite area PR is not limited to the pattern in which the above-described `0` and` 1` are repeated, but the modification of the data pattern will be described later.
[0035]
FIG. 5 shows the configuration of an optical disk apparatus when the present invention is applied to an MO disk. In FIG. 5, reference numeral 1 denotes an optical disc having the above-described format. The optical disk 1 is rotated at a constant rotational speed (for example, 2400 rpm) by the spindle motor 2 and the spindle controller 3. The optical disc 1 is irradiated with laser light from the optical pickup 4. Although not shown, the optical pickup 4 includes a laser source, an optical system such as an objective lens and a beam splitter, a detector that detects light reflected by the optical disc 1, and the like. The amount of laser light from the laser source is controlled by the laser controller 5. At the time of recording, laser light is emitted in pulses.
[0036]
In this embodiment, since the optical disk 1 is an MO disk and employs a magnetic field modulation method, a magnetic head 6 is provided, and recording data is supplied to a magnet driver 7 that drives the magnetic head 6. The recording data is generated by the data encoder 9. Data transferred from an external host computer 10 via an interface such as SCSI is supplied to the data encoder 8 via the controller 9. Commands such as write and read are also supplied to the controller 9 from the host computer 10. Then, the recording data is recorded by the magnetic head 6 by the NRZI method. This embodiment employs the NRZI system, which corresponds to the class IV PR (1, -1) of the partial response system. In the case of the NRZI system, the reproduction data takes three values (1, 0, −1). On the playback side, errors can be corrected by applying Viterbi decoding.
[0037]
As a method for recording a digital signal on an MO disk, there are an optical modulation method and a magnetic field modulation method. The light modulation method is a method in which laser light is modulated with recording data while an external magnetic field is applied in a certain direction. The magnetic field modulation method includes a simple magnetic field modulation method in which an external magnetic field is modulated with recording data while irradiating a laser beam with a constant light amount, and a laser strobe that modulates the magnetic field with recording data and emits laser light in pulses. There is a magnetic field modulation method. One embodiment of the present invention is a laser strobe magnetic field modulation method, but the present invention can use any of these recording methods.
[0038]
The reading position by the optical pickup 4 can be displaced in the radial direction. Specifically, there are coarse adjustment means that handle large radial displacements and fine adjustment means that handle small displacements. A coarse adjustment means is constituted by a linear motor or the like, and a fine adjustment means (tracking means) is constituted by a rotating mirror, a movable objective lens or the like. Further, tracking means in which the position of the optical pickup 4 is fixed and the optical disk 1 is displaced may be employed. Further, a focusing means is provided for adjusting the facing distance between the optical disc 1 and the optical pickup 4 so that the laser beam from the optical pickup 4 is correctly focused on the disc.
[0039]
When the optical disc 1 is loaded by a loading mechanism (not shown), the spindle motor 2 starts to rotate, and when the optical disc 1 reaches a specified rotational speed, the optical pickup 4 moves to the GCP area on the inner or outer peripheral side of the optical disc 1. The reading position is controlled so as to read. In this GCP area, the focus is pulled in, and then a recording or reproducing operation is performed.
[0040]
The reproduction RF signal detected by the detector of the optical pickup 4 is supplied to the IV conversion and matrix calculation unit 11. Since the detector output signal is generated as a current, a voltage output is formed by IV conversion. Further, by performing matrix calculation, a sum signal (also referred to as an RF signal) RFs, a difference signal (also referred to as an MO signal) RFd, a focus error signal FE, and the like are generated. A focus error signal FE is supplied to the servo control unit 12. The servo control unit 12 generates a signal for driving the focusing means in the optical pickup 4 in order to make the laser beam focus appropriate.
[0041]
The sum signal RFs is supplied to the A / D converter 14 via the clamp circuit 13, and the output signal of the A / D converter 14 is supplied to the PLL unit 15. The PLL unit 15 generates a servo clock SCK synchronized with the reproduction signal of the track mark in the servo area and a data clock DCK synchronized with the recording data. The servo clock SCK and the data clock DCK are supplied to the timing generator 22. The servo clock SCK is supplied to the A / D converter 14 as a sampling clock.
[0042]
The difference signal RFd is supplied to the A / D converter 17 via the clamp circuit 16. A data clock DCK is supplied as a sampling clock of the A / D converter 17, and an output signal of the A / D converter 17 is supplied to the data detection unit 18. The data detection unit 18 is supplied with the data synchronization signal DSY from the timing generation unit 22. In the data detection unit 18, waveform equalization processing is performed by a digital equalizer, the reproduction signal is ternarized, and an error in the detection signal is corrected by Viterbi decoding. Further, the data detection unit 18 demodulates the digital modulation and binarizes the demodulated output. The reproduced data taken out from the output of the data detector 18 is transferred to the host computer 10 through the controller 9.
[0043]
The digital output of the sum signal RFs is supplied to the tracking error generator 23. Sampling pulses from the timing generator 22 are supplied to the tracking error generator 23. The tracking error generator 23 samples the level of the reproduction signal (sum signal RFs) of the track marks (mark 1 and mark 2) in the servo area, and tracks the difference in amplitude between the reproduction signals corresponding to the mark 1 and mark 2 An error signal TE is output. A tracking error signal TE is supplied to the servo control unit 12. The servo control unit 12 generates a tracking drive signal that drives the tracking means in the optical pickup 4 so that the tracking error signal TE becomes zero.
[0044]
An example of the configuration of the clamp circuit 16 is shown in FIG. The clamp circuit 13 has the same configuration. Reference numeral 31 denotes an input terminal to which the difference signal RFd is supplied, and reference numeral 32 denotes a buffer circuit to which the input difference signal RFd is supplied. The reproduction signal via the buffer circuit 32 is supplied to one input terminal of the differential amplifier 33 and also supplied to the sample hold circuit 34 shown by a broken line.
[0045]
The sample hold circuit 34 includes a switch circuit 35, a series circuit of a resistor 36 and a capacitor 37 connected between the output side of the switch circuit 35 and the ground, and a buffer circuit 38 for taking out the terminal voltage of the capacitor 37. The A sample and hold circuit 44 surrounded by a broken line is connected to the sample and hold circuit 34. Similar to the sample and hold circuit 34, the sample and hold circuit 44 includes a switch circuit 45, a resistor 46, a capacitor 47, and a buffer circuit 48. An output signal via the buffer circuit 48 of the sample hold circuit 44 is supplied to the other input terminal of the differential amplifier 33.
[0046]
At the output of the differential amplifier 33, a difference signal in which the fluctuation of the DC level is suppressed is obtained. This difference signal is supplied to the A / D converter 17, and the output signal of the A / D converter 17 is taken out to the output terminal 39. As described above, the output signal of the A / D converter 17 is supplied to the data detection unit 18. Further, the output signal of the A / D converter 17 is supplied to the digital comparator 40 and the average value generation circuit 41.
[0047]
The output of the average value generation circuit 41 is supplied as the other input of the digital comparator 40. The digital comparator 40 is configured to obtain a difference between the value of the sample data from the A / D converter 17 and the average value and compare the absolute value with a threshold value. When the absolute value of the difference is smaller than the threshold value, a comparison output of `1 'is generated. When the absolute value of the difference is greater than or equal to the threshold value, a comparison output of` 0' is generated.
[0048]
The output of the digital comparator 40 is supplied as one input to the AND gate 42. A clamp pulse CLM2 generated by the timing generator 22 is supplied to the other input of the AND gate 42. The switch circuit 45 is controlled by the clamp pulse CLM2 ′ that has passed through the AND gate. The clamp pulse CLM2 is generated within a period during which the prewrite area PR as the clamp area is reproduced, and has a pulse width of, for example, 2 clocks or more.
[0049]
Further, the clamp pulse CLM2 is delayed by one clock of the data clock DCK by the D flip-flop 43. The clamp pulse CLM1 is formed by delaying the clamp pulse CLM2 by one clock. An example of the clamp pulse CLM1 is shown in FIG. The switch circuit 35 is controlled by the clamp pulse CLM1. Also, the clamp pulse CLM1 is supplied to the average value generation circuit 41, and among the output signals of the A / D converter 17, signals having the same timing as the clamp pulse CLM1 are taken into the average value generation circuit 41. The average value generation circuit 41 generates an average value of a plurality of captured data.
[0050]
The operation of the clamp circuit 16 described above will be described with reference to the timing chart of FIG. As shown in FIG. 7A, the data recorded on the optical disc 1 is a series of data segments, and a servo area is added at the head of each segment as indicated by a hatched line. The segment may be an address segment. A prewrite area PR as a clamping area is provided in the servo area. For convenience of explanation, n-3, n-2, n-1, n, n + 1, and n + 2 are numbered for the prewrite area shown in FIG. FIG. 7 is a timing chart in the case where a defect exists in the nth prewrite area. The defect means a sudden change in the level of a reproduction signal caused by a scratch, a fingerprint or the like on the disc. The clamp circuit 16 takes measures against defects in addition to the clamp operation.
[0051]
The difference signal RFd shown in FIG. 7B is supplied to the input terminal 31 of the clamp circuit 16. The signal RFd has a direct current level variation and includes an abrupt level change DF corresponding to the defect. The switch circuit 35 is controlled to be turned on by the clamp pulse CLM1 shown in FIG. 7C, and the sample and hold circuit 34 generates an output signal as shown in FIG. 7D. Since the level change DF due to the defect is also sample-held, an abnormal level sample-hold output is generated after the nth prewrite area.
[0052]
The digital comparator 40 compares the output of the average value generation circuit 41 with the reproduction level of the prewrite area from the A / D converter 17. The average value generation circuit 41 generates an average value of a plurality of continuous reproduction levels, for example, four reproduction levels. For example, an average value of the reproduction levels of the n-4th, n-3th, n-2th, and n-1th prewrite areas is formed, and the average value and the reproduction level of the n-1th prewrite area Are compared in the digital comparator 40. Since the difference between the two reproduction levels is smaller than the threshold value, a comparison output of “1” is generated as shown in FIG. 7E.
[0053]
Since this comparison output is supplied to the AND gate 42, a clamp pulse CLM2 'is generated at the output of the AND gate 42 as shown in FIG. 7F. The switch circuit 45 is turned on by the clamp pulse CLM2 ′. Accordingly, the output of the sample hold circuit 34 is sampled and held by the sample hold circuit 44. That is, the output of the sample hold circuit 34 is transferred to the sample hold circuit 44.
[0054]
In the next segment, there is an abnormal level due to a defect in the nth prewrite area. In the digital comparator 40, the difference between the abnormal level and the average reproduction level of the (n-3) th, (n-2) th, (n-1) th, and nth prewrite areas becomes larger than the threshold value. As a result, the comparison output of the digital comparator 40 becomes `0` as shown in FIG. 7E, the clamp pulse CLM2 is prohibited by the AND gate 42, and the clamp pulse CLM2 'is not generated as shown in FIG. 7F. Therefore, the switch circuit 45 is not turned on, and the output level of the sample hold circuit 44 is the level before being held, as shown in FIG. 7G.
[0055]
In this way, the sample and hold output supplied from the sample and hold circuit 44 to the differential amplifier 33 is not affected by the defect. By supplying the output of the sample hold circuit 44 shown in FIG. 7G to the differential amplifier 33, the output of the differential amplifier 33 is a difference signal in which the fluctuation of the DC level is suppressed as shown in FIG. 7H. Is obtained.
[0056]
As described above, in the embodiment of the present invention, as the data pattern of the prewrite area PR, the average value is recorded between the high level 'H' and the low level 'L'. A difference signal in which the fluctuation of the intermediate level is suppressed can be obtained from the clamp circuit 16. Since this intermediate level is used as a threshold for level detection, it is possible to prevent the threshold from being affected by gain fluctuations (see FIG. 4).
[0057]
In the present invention, the configurations of the clamp circuits 13 and 16 are not limited to those shown in FIG. For example, countermeasures against defects are not always necessary, and a configuration using one sample and hold circuit is also possible. Furthermore, a digital circuit configuration that performs clamping after A / D conversion can also be used.
[0058]
In the data detection unit 18 connected to the A / D converter 17, as described above, waveform equalization processing is performed by a digital equalizer, the reproduction signal is ternarized, and an error in the detection signal is corrected by Viterbi decoding. The digital modulation is demodulated. The data detection unit 18 sets the center level of the reproduction signal in the reference area as the threshold Th <sub>0</sub> . The reference area is arranged in units of sectors as shown in FIG. The DC level fluctuation in the sector is suppressed by the clamp circuit 16 described above.
[0059]
However, it is difficult to completely match the center level with the set threshold Th <sub>0</sub> by the clamping operation performed based on the reproduction level of the prewrite area for each segment, and a clamping error remains. Also, the clamp circuit 16 suppresses fluctuations in the DC level, and cannot correct gain fluctuations, and gain fluctuations cause an increase in data detection or Viterbi decoding errors. In consideration of these points, in the embodiment of the present invention, the data detection unit 18 corrects the threshold and the gain so that the Viterbi decoding in the data detection unit 18 is correctly performed.
[0060]
FIG. 8 is a flowchart showing threshold correction and gain correction processing performed by the data detection unit 18. It should be noted that threshold correction and gain correction can be performed not only by the software processing represented by the flowchart but also by hardware or a combination of software and hardware.
[0061]
In step ST1 in FIG. 8, the correction process starts when the sector reproducing operation is started. Next, the threshold Th <sub>0</sub> and the gain G <sub>0</sub> (average amplitude) are detected in the reference area of one sector (step ST2). These values can be detected in the same manner as in the past based on the 8T pattern in the reference area.
[0062]
Next, the segment number i is incremented, and the threshold variation ΔTh <sub>i</sub> and the gain variation ΔG <sub>i</sub> are detected in each segment. FIG. 9A shows changes in the envelope of the reproduction signal (difference signal). In FIG. 9, for simplicity, one sector is composed of a plurality of segments numbered i = 0 to iend, the reference segment is included in the first segment (i = 0) of the sector, An example in which the prewrite areas PR <sub>0</sub> , PR <sub>1</sub> ,... Are located is shown, and the reproduction signal corresponding to the servo area is ignored.
[0063]
By the clamping operation based on the data of the prewrite areas PR <sub>0</sub> , PR <sub>1</sub> ,..., The segment after i = 1 is controlled so that the threshold matches Th <sub>0</sub> . In the i = 1 segment, the threshold fluctuation is detected by calculating Th <sub>1</sub> -Th <sub>0</sub> = ΔTh <sub>1</sub> , and the gain fluctuation is detected by calculating G <sub>1</sub> -G <sub>0</sub> = ΔG <sub>1</sub> . In the same manner, the threshold variation ΔTh <sub>i</sub> and the gain variation ΔG <sub>i</sub> are detected in each segment. FIG. 9C shows an example of threshold variation ΔTh <sub>i</sub> .
[0064]
In step ST4 of FIG. 8, the segment number i is compared with the sector number i + 1 added to the final sector number iend to determine whether i <iend + 1. If this relationship is not satisfied (that is, if the segment number i is iend + 1 or more), since the correction processing up to the last segment has been completed, the sector reproduction operation ends (step ST5).
[0065]
In step ST4, when the relationship of i <iend + 1 is established, the process moves to step ST6, and the threshold and gain for data detection of the segment are determined. In step ST6, the processing of the segment (i = 1) next to the segment including the reference area and the processing of the segment (i> 1) are respectively performed. That is, in the case of (i = 1), it is immediately after the threshold Th <sub>0</sub> and the gain G <sub>0</sub> are detected in the reference area, so that these fluctuations are considered to be sufficiently small, and the threshold Th <sub>1</sub> and the gain G <sub>1 of the</sub> segment are considered. Are equal to Th <sub>0</sub> and gain G <sub>0</sub> , respectively.
[0066]
In step ST6, in the i-th segment that satisfies the relationship (i> 1), the threshold and the gain are corrected according to the following equations.
Th <sub>i</sub> ′ = Th <sub>0</sub> + ΔTh <sub>i</sub> / n (6)
G <sub>i</sub> ′ = G <sub>0</sub> + ΔG <sub>i</sub> / n (7)
In these equations, 1 / n is a coefficient for reducing the actual value of the offset in order to reduce the influence of noise. This coefficient is appropriately set in consideration of the S / N of the reproduction signal.
[0067]
Using the threshold Th <sub>i</sub> ′ and the gain G <sub>i</sub> ′ corrected in this manner, the data detection unit 18 performs data detection and Viterbi decoding processing on the data of the i-th segment. Note that the data detection unit 18 does not actually correct the DC level and gain of the reproduction signal, but corrects the threshold and gain as reference values for data detection or Viterbi decoding. If it is assumed that the DC level and gain of the reproduction signal are corrected, the reproduction signal is corrected as shown in FIG. 9D. As can be seen from FIG. 9D, the corrected thresholds Th <sub>1</sub> ′, Th <sub>2</sub> ′,... And the gains G <sub>1</sub> ′, G <sub>2</sub> ′,. The error between <sub>0</sub> and G <sub>0</sub> is smaller.
[0068]
In the embodiment described above, the pattern of data recorded in the prewrite area PR is (010101010101). Another example of the data pattern is shown in FIG. In this other example, in the order of the segments in one sector, all the data of “0” (00... 0) is recorded in the odd-numbered segments, and all the data of “1” (11.・ ・ Record 1).
[0069]
In the clamp circuit, the low level 'L' of the reproduced difference signal is clamped to be constant based on the data of the prewrite area PR of the odd-numbered segment. Further, the low level “L” is monitored in the odd-numbered segment, and the high level “H” is monitored in the even-numbered segment. Thereby, the threshold Th is obtained by the calculation of (H + L) / 2 for the unit of two consecutive segments, and the difference (threshold fluctuation amount) ΔTh between this value and Th <sub>0</sub> set in the reference area is detected. The Further, the gain G is obtained for the unit of two consecutive segments by the calculation of (H−L) / 2, and the difference (gain fluctuation) ΔG between this value and G <sub>0</sub> set in the reference area is obtained. Detected. By these fluctuations, the threshold and the gain are corrected in the same manner as described above.
[0070]
FIG. 11 shows still another example of the data pattern of the prewrite area PR. In the prewrite area PR of each segment, data “0” is recorded in the first half and data “1” is recorded in the second half. Therefore, pattern data of (00000011111) is recorded in the prewrite area PR.
[0071]
In the clamp circuit, the low level of the reproduced difference signal is clamped at a constant level using the data of `0 'in the first half of each segment. In each segment, the low level “L” and the high level “H” are monitored. Thereby, with respect to the unit of each segment, the threshold Th is obtained by the calculation of (H + L) / 2, and the difference (threshold fluctuation amount) ΔTh between this value and Th ₀ set in the reference area is detected. Further, the gain G is obtained for the unit of two consecutive segments by the calculation of (H−L) / 2, and the difference (gain fluctuation) ΔG between this value and G ₀ set in the reference area is obtained. Detected. By these fluctuations, the threshold and the gain are corrected in the same manner as described above.
[0072]
Note that the data pattern recorded in the prewrite area PR is not limited to the above-described example, and a data pattern adapted to the data detection method can be employed.
[0073]
【The invention's effect】
According to the present invention, when a threshold for data detection is detected in the reference area in the sector and the fluctuation of the DC component is corrected using the data in the prewrite area PR provided in each segment in the sector, Since a data pattern capable of detecting a low level value and a high level value is recorded in the write area PR, an error of a threshold remaining after clamping can be monitored and the error can be removed. Further, it is possible to remove a gain error necessary for data detection or Viterbi decoding. Therefore, the present invention can reduce errors generated in Viterbi decoding. According to the present invention, in the case of a magneto-optical disk, the allowable range of birefringence can be expanded, and the yield of the magneto-optical disk can be improved.
[Brief description of the drawings]
FIG. 1 is a schematic diagram for explaining a data structure in one embodiment of the present invention.
FIG. 2 is a schematic diagram used for explaining a sector structure and a reference signal in one embodiment of the present invention;
FIG. 3 is a schematic diagram showing an enlarged configuration of a servo area in an embodiment of the present invention.
FIG. 4 is a schematic diagram used for explaining a clamping operation in one embodiment of the present invention.
FIG. 5 is a block diagram of an embodiment of an optical disc apparatus to which the present invention is applied.
FIG. 6 is a block diagram of an example of a clamp circuit in one embodiment of the present invention.
FIG. 7 is a timing chart for explaining the operation of the clamp circuit in one embodiment of the present invention;
FIG. 8 is a flowchart for explaining threshold and gain correction operations in one embodiment of the present invention;
FIG. 9 is a schematic diagram for explaining threshold and gain correction operations in one embodiment of the present invention;
FIG. 10 is a schematic diagram illustrating another example of the data pattern of the prewrite area according to the present invention.
FIG. 11 is a schematic diagram illustrating still another example of the data pattern of the prewrite area according to the present invention.
FIG. 12 is a schematic diagram showing a data pattern of a reference area and a waveform of a reproduction signal of the previously proposed optical disc apparatus.
FIG. 13 is a schematic diagram showing an enlarged configuration of a servo area of the previously proposed optical disc apparatus.
FIG. 14 is a schematic diagram for explaining problems in the previously proposed optical disc apparatus.
FIG. 15 is a schematic diagram for explaining problems in the previously proposed optical disc apparatus.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Optical disk, 4 ... Optical pick-up, 6 ... Magnetic head, 13, 16 ... Clamp circuit, 15 ... PLL part

Claims (3)

Consists sector of a plurality of segments, each clamping area provided in the segment, the digital signal recording and reproducing apparatus to have a data structure in which the reference area is provided for each of the sectors,
Reading means for reading data from the recording medium;
A reproduction signal is supplied from the reading means, and the average value of the high level and low level of the reproduction signal in the reference area is set as a threshold setting value. The low level is synchronized with the data clock recorded in the clamping area. Clamping means for clamping the average level of data alternately repeating high level and high level to the threshold set value for each sector ;
Will receive a reproduced signal clamped by the clamping means has a correction means for correcting the values of the threshold and gain for each of the segments, and data detecting means for detecting data from the corrected reproduced signal by said correction means Prepared,
The correction means detects a threshold difference between the threshold set value and the threshold detected for each segment, and calculates the gain set value detected for each sector and the gain detected for each segment. Detect the gain difference,
A digital signal recording / reproducing apparatus, wherein the threshold for each segment is corrected by the threshold difference, and the gain for each segment is corrected by the gain difference . Consists sector of a plurality of segments, each clamping area provided in the segment, the digital signal recording and reproducing apparatus to have a data structure in which the reference area is provided for each of the sectors,
Reading means for reading data from the recording medium;
The reproduction signal is supplied from the reading means, the average value of the high level and low level of the reproduction signal in the reference area is set as a threshold setting value, and the low level and high level are recorded for each segment recorded in the clamping area. Clamping means for clamping the average level of data alternately repeating to the set value of the threshold every two sectors ;
Will receive a reproduced signal clamped by the clamping means has a correction means for correcting the values of the threshold and gain for each of the segments, and data detecting means for detecting data from the corrected reproduced signal by said correction means Prepared,
The correction means detects a threshold difference between the threshold set value and the threshold detected for each segment, and calculates the gain set value detected for each sector and the gain detected for each segment. Detect the gain difference,
A digital signal recording / reproducing apparatus, wherein the threshold for each segment is corrected by the threshold difference, and the gain for each segment is corrected by the gain difference . Consists sector of a plurality of segments, each clamping area provided in the segment, the digital signal recording and reproducing apparatus to have a data structure in which the reference area is provided for each of the sectors,
Reading means for reading data from the recording medium;
A reproduction signal is supplied from the reading means, the average value of the high level and low level of the reproduction signal in the reference area is set as a threshold value, the clamping area is divided, and the low level and high level are recorded. Clamping means for clamping the average level of the data to the set value of the threshold for each sector ;
Will receive a reproduced signal clamped by the clamping means has a correction means for determining a value of the threshold and gain for each of the segments, and data detecting means for detecting data from the corrected reproduced signal by said correction means Prepared,
The correction means detects a threshold difference between the threshold set value and the threshold detected for each segment, and calculates the gain set value detected for each sector and the gain detected for each segment. Detect the gain difference,
A digital signal recording / reproducing apparatus, wherein the threshold for each segment is corrected by the threshold difference, and the gain for each segment is corrected by the gain difference .

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