JP3752496B2 - Signal correction method, wobble signal correction circuit, and optical disc apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a signal correction method, a wobble signal correction circuit, and an optical disc apparatus. More specifically, the present invention corrects a wobble signal detected based on reflected light from a recording surface of an optical disc on which spiral or concentric tracks are formed. The present invention relates to a signal correction method, a wobble signal correction circuit, and an optical disc apparatus including the wobble signal correction circuit.
[0002]
[Prior art]
In recent years, with the advancement of digital technology and the improvement of data compression technology, CD (compact disc), CD as a medium for recording information such as music, movies, photos and computer software (hereinafter also referred to as “content”) An optical disc such as a DVD (digital versatile disc) that can record data equivalent to about 7 times the data on a disc having the same diameter as a CD has been attracting attention. The optical disk device to be used has become widespread. CD-ROMs, CD-Rs (CD-recordables) and CD-RWs (CD-rewritables) are examples of CD-type optical disks, and DVD-ROMs, DVD-RAMs, DVD-s are examples of DVD-type optical disks. R (DVD-recordable), DVD-RW (DVD-rewritable), DVD + R (DVD + recordable), DVD + RW (DVD + rewritable), and the like are commercially available.
[0003]
In general, grooves called so-called grooves are formed on recording surfaces of so-called write-once optical disks such as CD-R, DVD-R, and DVD + R, and so-called rewritable optical disks such as CD-RW, DVD-RW, and DVD + RW. Has been. Then, by making the groove meander (wobble), a signal (wobble signal) including various incidental information is recorded on the track. In an optical disc device, a recording surface of an optical disc is irradiated with laser light through an objective lens, and laser light reflected by the recording surface is received by a photodetector, and a wobble signal is output from the output signal (photoelectric conversion signal) of the photodetector. Is detected. The auxiliary information includes a signal synchronized with the rotational speed of the optical disk, track address information, and the like. In the optical disk apparatus, the rotational speed of the optical disk is controlled based on the detected wobble signal, and the objective lens The position is controlled. Thus, the wobble signal is a very important signal.
[0004]
However, since the optical disc has a high recording density and the distance between adjacent tracks (track pitch) is narrow, for example, when the wavefront aberration increases, the light spot formed on the recording surface is abbreviated as a target track (hereinafter referred to as “target track”). In some cases, it is difficult to narrow down only to the target track, and a part of the light spot is applied to a track adjacent to the target track (hereinafter abbreviated as “adjacent track”). In this case, crosstalk (crosstalk) from an adjacent track occurs, and the detected wobble signal is a signal in which the wobble signal of the adjacent track is superimposed on the wobble signal of the target track.
[0005]
For example, when a wobble signal is recorded on a track by a phase modulation method such as DVD + R or DVD + RW, the influence of crosstalk is not uniform, and the carrier wave in the wobble signal of the target track (hereinafter referred to as “target track carrier wave for convenience”). ”) And the phase of a carrier wave in an adjacent track wobble signal (hereinafter also referred to as“ adjacent track carrier wave ”for convenience). For example, when the phase of the target track carrier and the phase of the adjacent track carrier are substantially in phase with each other, the amplitude of the carrier wave of the detected wobble signal is large, while the phase of the target track carrier and the phase of the adjacent track carrier are different. When the phases are almost opposite to each other, the amplitude of the carrier wave of the detected wobble signal is small. As an example, as shown in FIG. 17, the relationship between the phase of the target track carrier and the phase of the adjacent track carrier fluctuates substantially periodically.
[0006]
If crosstalk occurs in the wobble signal, the detection accuracy of the incidental information may be lowered, and recording and reproduction may be adversely affected. Accordingly, various methods and apparatuses for reducing the influence of crosstalk in the wobble signal have been devised (see Patent Document 1 and Patent Document 2).
[0007]
[Patent Document 1]
JP 2002-269653 A
[Patent Document 2]
JP 2001-34977 A
[0008]
[Problems to be solved by the invention]
As the use of optical disks becomes common, there is an increasing demand for higher access speed from users. However, when the access speed is further increased, the crosstalk in the wobble signal is increased at the same time. With the methods disclosed in Patent Document 1 and Patent Document 2, the influence of the crosstalk may not be sufficiently reduced. .
[0009]
Furthermore, the devices disclosed in Patent Document 1 and Patent Document 2 may not be able to sufficiently respond to the demand for downsizing and cost reduction of the optical disk device.
[0010]
Recently, an optical disk apparatus using a semiconductor laser (blue laser) having an oscillation wavelength of about 405 nm has been vigorously developed. In an optical disc corresponding to this optical disc apparatus, the track pitch is less than half that of a conventional DVD, and it is expected that the methods disclosed in Patent Document 1 and Patent Document 2 cannot be dealt with.
[0011]
The present invention has been made under such circumstances, and a first object thereof is a signal correction method and a wobble signal correction circuit capable of accurately correcting a wobble signal without incurring an increase in size and cost. Is to provide.
[0012]
A second object of the present invention is to provide an optical disc apparatus capable of accurately accessing an optical disc.
[0013]
[Means for Solving the Problems]
  According to the first aspect of the present invention, a predetermined carrier portion and a phase-modulated wave portion in which the carrier is phase-modulated are detected based on the reflected light from the recording surface of the optical disc on which spiral or concentric tracks are formed. The wobble signal is corrected to generate a first signal by adjusting the amplitude of the wobble signal so that the amplitude of the carrier wave portion matches a desired carrier wave amplitude, and the phase Modulated wave partSo that information including address information can be demodulatedA signal generating step of adjusting the amplitude of the wobble signal to generate a second signal; selecting the first signal at a timing corresponding to the carrier portion in the wobble signal, and the phase modulation in the wobble signal And a selection step of selecting the second signal at a timing corresponding to the wave portion.
[0014]
  According to this, a wobble signal composed of a predetermined carrier wave portion and a phase modulation wave portion obtained by phase-modulating the carrier wave is adjusted by adjusting the amplitude of the wobble signal so that the amplitude of the carrier wave portion matches the desired carrier wave amplitude. The first signal is generated and the phase modulated wave portionSo that information including address information can be demodulatedA second signal is generated by adjusting the amplitude of the wobble signal (signal generation step). Then, the first signal is selected at the timing corresponding to the carrier wave portion in the wobble signal, and the second signal is selected at the timing corresponding to the phase modulation wave portion in the wobble signal (selection step). In this case, for example, the amplitude of the carrier wave portion and the amplitude of the phase modulation wave portion can be adjusted so as to be the amplitude when there is almost no influence of the crosstalk. That is, the wobble signal can be corrected more easily and in a shorter time than in the past. Therefore, the wobble signal can be corrected with high accuracy without resulting in an increase in size and cost.
[0015]
  According to a second aspect of the present invention, a predetermined carrier portion and a phase-modulated wave portion in which the carrier is phase-modulated are detected based on reflected light from the recording surface of an optical disc on which spiral or concentric tracks are formed. A signal correction method for correcting a wobble signal comprising: extracting the carrier wave portion from the wobble signal as a first signal and extracting the phase modulated wave portion as a second signal; Adjusting the amplitude of the first signal to match the desired carrier amplitude, and adjusting the amplitude of the second signalTo be able to demodulate information including address informationA signal correction method comprising: a signal generation step of adjusting; and an adding step of adding the adjusted first signal and the adjusted second signal.
[0016]
  According to this, a wobble signal composed of a predetermined carrier wave portion and a phase modulation wave portion obtained by phase-modulating the carrier wave is extracted from the wobble signal as the first signal, and the phase modulation wave portion is the first wave modulation wave portion. 2 is extracted (extraction process). Then, the amplitude of the first signal is adjusted to match the desired carrier amplitude, and the amplitude of the second signal isTo be able to demodulate information including address informationIt is adjusted (signal generation process). Further, the adjusted first signal and the adjusted second signal are added (adding step). In this case, for example, the amplitude of the carrier wave portion and the amplitude of the phase modulation wave portion can be adjusted so as to be the amplitude when there is almost no influence of the crosstalk. That is, the wobble signal can be corrected more easily and in a shorter time than in the past. Therefore, the wobble signal can be corrected with high accuracy without resulting in an increase in size and cost.
[0019]
  According to a third aspect of the present invention, a predetermined carrier portion and a phase-modulated wave portion in which the carrier is phase-modulated are detected based on reflected light from a recording surface of an optical disc on which spiral or concentric tracks are formed. A wobble signal correction circuit for correcting a wobble signal consisting of: a carrier wave adjustment circuit for adjusting an amplitude of the wobble signal so that an amplitude of the carrier wave part matches a desired carrier wave amplitude; and the phase modulation wave partSo that information including address information can be demodulatedA phase modulation wave adjustment circuit for adjusting the amplitude of the wobble signal; an output signal of the carrier wave adjustment circuit is selected at a timing corresponding to the carrier wave portion in synchronization with the wobble signal, and corresponds to the phase modulation wave portion; A signal selection circuit that selects an output signal of the phase modulation wave adjustment circuit at timing.
[0020]
  According to this, the wobble signal detected based on the reflected light from the recording surface of the optical disc is supplied to the carrier wave adjustment circuit and the phase modulation wave adjustment circuit, respectively. The wobble signal supplied to the carrier adjustment circuit has the carrier part amplitudeDesiredIt is adjusted to have an amplitude. On the other hand, the wobble signal supplied to the phase modulation wave adjustment circuit has the amplitude of the phase modulation wave portion.DesiredIt is adjusted to have an amplitude. Then, the output signal of the carrier wave adjustment circuit and the output signal of the phase modulation wave adjustment circuit are respectively supplied to the signal selection circuit. The signal selection circuit synchronizes with the wobble signal, selects the output signal of the carrier wave adjustment circuit at a timing corresponding to the carrier wave part, and selects the output signal of the phase modulation wave adjustment circuit at a timing corresponding to the phase modulation wave part. Yes. That is, the signal selection circuit extracts the carrier wave portion from the output signal of the carrier wave adjustment circuit, and extracts the phase modulation wave portion from the output signal of the phase modulation wave adjustment circuit. In this way, the wobble signal can be corrected so that both the carrier wave portion and the phase-modulated wave portion have a desired amplitude with a simpler circuit configuration than the prior art. Therefore, the wobble signal can be corrected with high accuracy without resulting in an increase in size and cost.
[0021]
  According to a fourth aspect of the present invention, a predetermined carrier portion and a phase-modulated wave portion in which the carrier is phase-modulated are detected based on reflected light from the recording surface of an optical disc on which spiral or concentric tracks are formed. A wobble signal correction circuit for correcting a wobble signal comprising: extracting the carrier wave portion from the wobble signal and outputting it as a first signal; extracting the phase modulated wave portion from the wobble signal; A signal extraction circuit that outputs the second signal; a carrier adjustment circuit that adjusts an amplitude of the first signal so that an amplitude of the first signal matches a desired carrier amplitude; and the second signalSo that information including address information can be demodulatedA wobble signal correction circuit comprising: a phase modulation wave adjustment circuit that adjusts an amplitude of the second signal; and an addition circuit that adds an output signal of the carrier wave adjustment circuit and an output signal of the phase modulation wave adjustment circuit. .
[0022]
  According to this, the wobble signal detected based on the reflected light from the recording surface of the optical disc is extracted by the signal extraction circuit into the carrier wave portion and the phase modulation wave portion, and the carrier wave portion is output as the first signal. In addition, the phase modulation wave portion is output as the second signal. The first signal is adjusted by the carrier wave adjustment circuit so that the amplitude matches the desired carrier wave amplitude, and the second signal is adjusted by the phase modulation wave adjustment circuit.Information including address information can be demodulated from the second signalAdjusted. Further, the first signal adjusted by the carrier wave adjustment circuit and the second signal adjusted by the phase modulation wave adjustment circuit are added by the adding means. That is, the wobble signal is corrected so that both the carrier wave portion and the phase modulation wave portion have a desired amplitude with a simpler circuit configuration than the conventional one. Therefore, the wobble signal can be corrected with high accuracy without resulting in an increase in size and cost.
[0025]
  Claims above3 and 4In each wobble signal correction circuit according to claim 1,5As described above, the carrier wave adjustment circuit can be an auto gain control amplifier circuit.
[0026]
  Claims above3~5In each wobble signal correction circuit according to claim 1,6As described above, the phase modulation wave adjustment circuit can be a fixed gain amplifier circuit.
[0027]
  In this case, as in the wobble signal correction circuit according to claim 7, the gain of the fixed gain amplifier circuit is the wobble signal of the target track.InWhen the phase of the carrier wave portion and the phase of the carrier wave portion in the wobble signal of the track adjacent to the target track are opposite to each other,Information including address information can be demodulated from the phase modulation wave portionIt can be assumed that it is set as follows.
[0028]
  Claims above3~5In each wobble signal correction circuit according to claim 1,8As described above, the phase modulation wave adjustment circuit can be a variable gain amplifier circuit.
[0029]
  In this case, the claim9As described above, the gain of the variable gain amplifier circuit can be set based on vendor information of the optical disc.
[0030]
  Claims above8In the wobble signal correction circuit according to claim 1,10As described above, the gain of the variable gain amplifier circuit can be set based on the maximum amplitude of the carrier wave portion in the wobble signal.
[0031]
  Claim11The invention described in 1 is an optical disc apparatus that performs at least reproduction of information recording, reproduction, and erasure with respect to an optical disc on which a spiral or concentric track is formed on a recording surface. An optical pickup device that irradiates a light beam and receives reflected light from the recording surface; and a wobble signal detected from an output signal of the optical pickup device is corrected.3~10An optical disk device comprising: the wobble signal correction circuit according to any one of the above; and a processing device that performs at least reproduction of information recording, reproduction, and erasure via the optical pickup device.
[0032]
  According to this, the claim3~10Since the wobble signal correction circuit according to any one of the above items is provided, for example, even when the crosstalk of the wobble signal is large, the address information and the synchronization signal can be obtained with high accuracy. Accordingly, as a result, it is possible to accurately perform access including at least reproduction among recording, reproduction and erasure of information on the optical disc.
[0033]
  Claim12The invention described in 1 is an optical disc apparatus that performs at least reproduction of information recording, reproduction, and erasure with respect to an optical disc on which a spiral or concentric track is formed on a recording surface. An optical pickup device that irradiates a light beam and receives reflected light from the recording surface; and a wobble signal detected from an output signal of the optical pickup device is corrected.8A setting unit for setting a gain of the variable gain amplifier circuit; and a processing device for performing at least reproduction of data recording, reproduction and erasure via the optical pickup device. An optical disk device.
[0034]
  According to this, the setting means claims8The gain of the variable gain amplifier circuit in the wobble signal correction circuit described in (1) is set. For example, even when the wobble signal has a large crosstalk, the wobble signal correction circuit corrects the wobble signal with high accuracy. Therefore, it is possible to obtain address information, a synchronization signal, and the like with high accuracy, and as a result, it is possible to accurately perform access including at least reproduction among recording, reproduction, and erasure of information on the optical disc.
[0035]
  In this case, the claim13And a memory for storing optimum gain of the variable gain amplifier circuit for each vendor information; vendor information acquisition means for acquiring vendor information of the optical disk; and the setting means. Can extract the gain corresponding to the vendor information acquired by the vendor information acquisition means from the memory, and set the gain to the gain of the variable gain amplifier circuit.
[0036]
  Claims above12In the optical disc device according to claim 1,14As described above, the setting means has an amplitude of the carrier wave portion in the wobble signal.Maximum valueThe gain of the variable gain amplifier circuit can be set based on the above.
[0038]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS. FIG. 1 shows a schematic configuration of an optical disc apparatus 20 according to an embodiment of the present invention.
[0039]
The optical disk apparatus 20 shown in FIG. 1 includes a spindle motor 22, an optical pickup apparatus 23, a laser control circuit 24, an encoder 25, a motor driver 27, a reproduction signal processing circuit 28, a servo controller 33, and the like. A buffer RAM 34, a buffer manager 37, an interface 38, a flash memory 39, a CPU 40, a RAM 41, and the like are provided. In addition, the connection line in FIG. 1 shows the flow of a typical signal and information, and does not represent all the connection relationships of each block. In this embodiment, as an example, it is assumed that the optical disc apparatus 20 is compatible with an optical disc conforming to the DVD standard.
[0040]
The optical pickup device 23 is a device for irradiating the recording surface on which the spiral or concentric tracks of the optical disk 15 are formed with laser light and receiving reflected light from the recording surface. As shown in FIG. 2 as an example, the optical pickup device 23 includes a light source unit 51, a collimator lens 52, a beam splitter 54, an objective lens 60, two detection lenses (58, 72), and two light receivers (59, 59). 73), a reflection mirror 71, and a drive system (focusing actuator, tracking actuator and seek motor (all not shown)).
[0041]
The light source unit 51 includes a semiconductor laser 51a as a light source that emits laser light having a wavelength of 660 nm. In the present embodiment, the maximum intensity emission direction of the light beam of the laser light emitted from the light source unit 51 (hereinafter abbreviated as “light beam”) is defined as the + X direction.
[0042]
The collimating lens 52 is disposed on the + X side of the light source unit 51 and makes the light beam emitted from the light source unit 51 substantially parallel light.
[0043]
The reflection mirror 71 is disposed in the vicinity of the collimating lens 52 and reflects a part of the light beam emitted from the light source unit 51 in the −Z direction as a monitoring light beam.
[0044]
The beam splitter 54 is disposed on the + X side of the collimating lens 52 and transmits the light beam that has been made substantially parallel light by the collimating lens 52 as it is. Further, the beam splitter 54 branches a light beam (return light beam) reflected by the optical disk 15 and incident via the objective lens 60 in the −Z direction.
[0045]
The objective lens 60 is disposed on the + X side of the beam splitter 54 and condenses the light beam transmitted through the beam splitter 54 on the recording surface of the optical disc 15.
[0046]
The detection lens 58 is disposed on the −Z side of the beam splitter 54 and condenses the return light beam branched in the −Z direction by the beam splitter 54 on the light receiving surface of the light receiver 59. The light receiver 59 generates a current signal corresponding to the amount of received light by photoelectric conversion and outputs it to the reproduction signal processing circuit 28. Note that the output signal of the light receiver 59 includes wobble signal information, reproduction data information, focus error information, track error information, and the like.
[0047]
The detection lens 72 is disposed on the −Z side of the reflection mirror 71 and condenses the monitoring light beam reflected by the reflection mirror 71 in the −Z direction on the light receiving surface of the light receiver 73. The light receiver 73 generates a current signal corresponding to the amount of received light by photoelectric conversion, and outputs the current signal to the laser control circuit 24 as a power monitor signal.
[0048]
As shown in FIG. 3, the reproduction signal processing circuit 28 includes an I / V amplifier 28a, a servo signal detection circuit 28b, a wobble signal detection circuit 28c, an RF signal detection circuit 28d, a decoder 28e, a wobble signal correction circuit 28f, and the like. It is composed of
[0049]
The I / V amplifier 28a converts a current signal, which is an output signal of the light receiver 59, into a voltage signal and amplifies it with a predetermined gain.
[0050]
The servo signal detection circuit 28b detects a servo signal (such as a focus error signal and a track error signal) based on the output signal of the I / V amplifier 28a. The servo signal detected here is output to the servo controller 33.
[0051]
The wobble signal detection circuit 28c detects a wobble signal based on the output signal of the I / V amplifier 28a. The RF signal detection circuit 28d detects an RF signal based on the output signal of the I / V amplifier 28a.
[0052]
The wobble signal correction circuit 28f corrects the wobble signal detected by the wobble signal detection circuit 28c. Details of the wobble signal correction circuit 28f will be described later.
[0053]
The decoder 28e extracts ADIP (Address In Pregroove) information, a synchronization signal, and the like from the wobble signal corrected by the wobble signal correction circuit 28f. The extracted ADIP information is output to the CPU 40. The decoder 28e performs demodulation processing, error detection processing, and the like on the RF signal detected by the RF signal detection circuit 28d, and then stores the data as reproduction data in the buffer RAM 34 via the buffer manager 37. The decoder 28e performs a predetermined error correction process when an error is detected in the error detection process.
[0054]
Further, the decoder 28e monitors the wobble state of the track and outputs information relating to the phase modulation wave portion to the wobble signal correction circuit 28f as the phase modulation signal Sphase. In the present embodiment, for example, the phase modulation signal Sphase is set to be 0 (low level) corresponding to the carrier wave portion and to 1 (high level) corresponding to the phase modulation wave portion (FIG. 5). reference). Since the phase-modulated wave portion appears at a fixed period, for example, when the optical disk is loaded, the phase-modulated signal is obtained by obtaining the number of clocks of the carrier wave portion and the number of clocks of the phase-modulated wave portion in the wobble signal Sphase can be easily generated.
[0055]
Here, the detailed configuration of the wobble signal correction circuit 28f will be described with reference to FIG. As shown in FIG. 4 as an example, the wobble signal correction circuit 28f includes a fixed gain amplifier circuit f1 as a phase modulation wave adjustment circuit, an auto gain control amplifier (AGC amplifier) circuit f2 as a carrier wave adjustment circuit, and a signal selection circuit. As a selector f3.
[0056]
  The fixed gain amplifier circuit f1 amplifies the wobble signal Sa from the wobble signal detection circuit 28c with an amplification factor corresponding to the set gain, and outputs the amplified signal as a signal Sc. Note that the gain of the fixed gain amplifier circuit f1 is obtained by, for example, preliminarily experimenting with the phase of the target track carrier and the phase of the adjacent track carrier.AntiphaseThe amplitude of the phase modulation wave portion in the output signal Sc of the fixed gain amplifier circuit f1 is the desired amplitude (phase modulation wave amplitude).MatchIt is set to be. In the present embodiment, the desired phase modulation wave amplitude is, for example, a demodulated signal including predetermined information such as address information when the phase modulation wave portion adjusted by the fixed gain amplifier circuit f1 is demodulated by the decoder 28e. It is assumed that the amplitude satisfies the condition that can be obtained.
[0057]
The AGC amplifier circuit f2 includes a variable gain amplifier circuit f21, an amplitude detection circuit f22, and a gain control circuit f23.
[0058]
  The variable gain amplifier circuit f21 adjusts the amplitude of the wobble signal Sa from the wobble signal detection circuit 28c according to the gain indicated by the gain control circuit f23. The amplitude detection circuit f22 detects the amplitude of the carrier wave portion in the output signal Sb of the variable gain amplifier circuit f21 and outputs it to the gain control circuit f23. The gain control circuit f23 determines the amplitude of the carrier wave part in the output signal Sb of the variable gain amplifier circuit f21 based on the detection result in the amplitude detection circuit f22.Constant amplitudeThe gain of the variable gain amplifier circuit f21 is controlled so as to be (desired carrier wave amplitude). In the present embodiment, the desired carrier amplitude is assumed to be an amplitude that satisfies the condition that the phase shift of the synchronization signal obtained from the carrier portion of the wobble signal is within an allowable range.
[0059]
The selector f3 selects one of the output signal Sb of the variable gain amplifier circuit f21 (that is, the output signal of the AGC amplifier circuit f2) Sb and the output signal Sc of the fixed gain amplifier circuit f1 in synchronization with the phase modulation signal Sphase. , Output as a signal Sd. As an example in the present embodiment, the selector f3 selects the output signal Sb of the AGC amplifier circuit f2 when the phase modulation signal Sphase is 0 (low level), and a fixed gain amplifier circuit when the phase modulation signal Sphase is 1 (high level). It is assumed that the output signal Sc of f1 is set to be selected. That is, the selector f3 selects the output signal Sb of the AGC amplifier circuit f2 at a timing corresponding to the carrier wave portion in the wobble signal, and selects the output signal Sc of the fixed gain amplifier circuit f1 at a timing corresponding to the phase modulation wave portion. .
[0060]
Next, the operation of the wobble signal correction circuit 28f configured as described above will be described.
[0061]
  First, the phase of the target track carrier and the phase of the adjacent track carrier are mutuallySame phaseThis case will be described with reference to the timing chart of FIG. 5 as an example.
[0062]
The wobble signal Sa detected by the wobble signal detection circuit 28c is input to the fixed gain amplifier circuit f1 and the AGC amplifier circuit f2, respectively. Here, as shown in FIG. 5 as an example, the wobble signal Sa has an amplitude of a carrier wave portion larger than a desired carrier wave amplitude D due to the influence of crosstalk from adjacent tracks.
[0063]
  The wobble signal Sa input to the AGC amplifier circuit f2 is adjusted to reduce the amplitude because the amplitude of the carrier wave portion is larger than the desired carrier wave amplitude D (signal Sb). As a result, the amplitude of the carrier part isDesiredHowever, the amplitude of the phase modulation wave portion is smaller than the desired phase modulation wave amplitude.
[0064]
  The wobble signal Sa input to the fixed gain amplifier circuit f1 is amplified with the gain (signal Sc). As a result, the amplitude of the carrier wave portion becomes larger than the desired carrier wave amplitude D, but the amplitude of the phase modulated wave portion isDesiredThe amplitude of the phase modulation wave.
[0065]
  In the selector f3, in synchronization with the phase modulation signal Sphase, the signal Sb is selected at a timing corresponding to the carrier wave portion, and the signal Sc is selected at a timing corresponding to the phase modulation wave portion (signal Sd). As a result, both the carrier part and the phase modulation wave partDesiredA signal with an amplitude of. That is, the influence of crosstalk is corrected.
[0066]
  Next, the phase of the target track carrier and the phase of the adjacent track carrier are mutuallyAntiphaseThis case will be described with reference to the timing chart of FIG. 6 as an example.
[0067]
The wobble signal Sa detected by the wobble signal detection circuit 28c is input to the fixed gain amplifier circuit f1 and the AGC amplifier circuit f2, respectively. Here, as shown in FIG. 6 as an example, the wobble signal Sa has an amplitude of a carrier wave portion smaller than a desired carrier wave amplitude D due to the influence of crosstalk from adjacent tracks.
[0068]
  The wobble signal Sa input to the AGC amplifier circuit f2 is adjusted to increase the amplitude because the amplitude of the carrier wave portion is smaller than the desired carrier wave amplitude D (signal Sb). As a result, the amplitude of the carrier part isDesiredThe amplitude of the phase modulated wave portion is larger than the desired phase modulated wave amplitude.
[0069]
The wobble signal Sa input to the fixed gain amplifier circuit f1 is amplified with the gain (signal Sc). Here, the phase modulation wave portion has a desired phase modulation wave amplitude, but the carrier wave portion amplitude remains smaller than the desired carrier wave amplitude D.
[0070]
  In the selector f3, in synchronization with the phase modulation signal Sphase, the signal Sb is selected at a timing corresponding to the carrier wave portion, and the signal Sc is selected at a timing corresponding to the phase modulation wave portion (signal Sd). As a result, both the carrier part and the phase modulation wave partDesiredA signal with an amplitude of. That is, the influence of crosstalk is corrected. The output signal Sd of the selector f3 is supplied to the decoder 28e.
[0071]
Returning to FIG. 1, the servo controller 33 generates a focus control signal for correcting the focus shift based on the focus error signal from the servo signal detection circuit 28b. Further, the servo controller 33 generates a tracking control signal for correcting the track deviation based on the track error signal from the servo signal detection circuit 28b. Each control signal generated here is output to the motor driver 27 when the servo is on, and is not output when the servo is off. Servo-on and servo-off are set by the CPU 40.
[0072]
The motor driver 27 outputs a focusing actuator drive signal to the optical pickup device 23 based on the focus control signal, and outputs a tracking actuator drive signal to the optical pickup device 23 based on the tracking control signal. That is, tracking control and focus control are performed by the servo signal detection circuit 28b, the servo controller 33, and the motor driver 27. The motor driver 27 outputs drive signals for the spindle motor 22 and the seek motor, respectively, based on a control signal from the CPU 40.
[0073]
The buffer RAM 34 has a buffer area for temporarily storing data to be recorded on the optical disk (recording data), data reproduced from the optical disk (reproduction data), and a variable area for storing various program variables. Have.
[0074]
The buffer manager 37 manages data input / output to / from the buffer RAM 34. Then, the CPU 40 is notified when the amount of data stored in the buffer area reaches a predetermined amount.
[0075]
The encoder 25 takes out the recording data stored in the buffer RAM 34 through the buffer manager 37 based on an instruction from the CPU 40, performs data modulation and addition of an error correction code, and outputs a write signal to the optical disc 15. Generate. The write signal generated here is output to the laser control circuit 24.
[0076]
The laser control circuit 24 generates a drive signal for the semiconductor laser 51a based on the write signal from the encoder 25, the light emission characteristics of the semiconductor laser 51a, the power monitor signal, the clock signal from the reproduction signal processing circuit 28, and the like. In other words, the power of the laser beam irradiated on the optical disk 15 is controlled.
[0077]
In an optical disc, data is recorded on the recording surface by the lengths of mark areas and space areas having different reflectivities and combinations thereof.
[0078]
For example, when the optical disk 15 is a DVD + R that is a write-once optical disk containing an organic dye on the recording surface, the power of laser light emitted from the light source unit 51 (hereinafter also referred to as “light emission power”) when the mark area is formed. ) Is increased to heat and dissolve the organic dye, and the disk substrate portion in contact therewith is altered and deformed. On the other hand, when the space area is formed, the light emission power is made as small as that during reproduction so that the disk substrate is not altered or deformed. As a result, the reflectance in the mark area is lower than that in the space area. The light emission power when forming the mark area is also called recording power.
[0079]
When the optical disk 15 is a DVD + RW that is a rewritable optical disk including a special alloy on the recording surface, when the mark area is formed, the special alloy is heated to a first temperature and then rapidly cooled to be amorphous. It is in a state. On the other hand, when forming the space region, the special alloy is heated to the second temperature (<first temperature) and then gradually cooled to a crystalline state. As a result, the reflectance in the mark area is lower than that in the space area. The temperature control of such a special alloy is performed by controlling the light emission power of the laser beam. In order to remove the influence of heat storage, the light emission power for forming the mark region is divided into a plurality of pulses (multiple pulses). The peak value of the light emission power converted into multipulses is also called recording power. The rule for making the emission power into multipulses is called a recording strategy.
[0080]
The interface 38 is a two-way communication interface with a host and, as an example, is compliant with the ATAPI (AT Attachment Packet Interface) standard.
[0081]
The flash memory 39 includes a program area and a data area, and a program written in a code readable by the CPU 40 is stored in the program area. The data area stores information related to the light emission characteristics of the semiconductor laser 51a, information related to the seek operation (hereinafter also referred to as “seek information”), recording strategy information, and the like.
[0082]
The CPU 40 controls the operation of each unit in accordance with a program stored in the program area of the flash memory 39, and stores data necessary for the control in the variable area of the buffer RAM 34 and the RAM 41.
[0083]
<Recording process>
Next, processing (recording processing) in the optical disc apparatus 20 when a recording request command from the host is received will be briefly described with reference to FIG. The flowchart of FIG. 7 corresponds to a series of processing algorithms executed by the CPU 40. When a recording request command is received from the host, the start address of the program corresponding to the flowchart of FIG. Starts.
[0084]
In the first step 501, a control signal for controlling the rotation of the spindle motor 22 based on the recording speed is output to the motor driver 27, and the reproduction signal processing circuit 28 is notified that a recording request command has been received from the host. . Further, the buffer manager 37 is instructed to store the data (recording data) received from the host in the buffer RAM 34.
[0085]
In the next step 503, referring to the signal extracted from the wobble signal corrected as described above and synchronized with the rotation speed of the optical disk 15, it is confirmed that the rotation of the optical disk 15 has reached a predetermined linear velocity. Servo-on is set for the servo controller 33. Thereby, tracking control and focus control are performed as described above. Note that tracking control and focus control are performed as needed until the recording process is completed.
[0086]
In the next step 505, OPC (Optimum Power Control) is performed based on the recording speed to obtain the optimum recording power. That is, while changing the recording power stepwise, predetermined data is trial-written in a trial writing area called PCA (Power Calibration Area), and then the data is sequentially reproduced. For example, the asymmetry detected from the RF signal When the value almost coincides with a target value obtained in advance through experiments or the like, it is determined that the recording quality is the highest, and the recording power at that time is set as the optimum recording power. Further, the peak level (Lp) and the bottom level (Lb) of the RF signal at the highest recording quality are acquired, and the β value is calculated based on the following equation (1). Then, the calculated β value is set as a target β value and stored in the RAM 41.
[0087]
β = (Lp + Lb) / (Lp−Lb) (1)
[0088]
In the next step 507, the current address is acquired based on the ADIP information extracted from the corrected wobble signal.
[0089]
In the next step 509, a difference (address difference) between the current address and the target address extracted from the recording request command is calculated.
[0090]
In the next step 511, it is determined whether seek is necessary based on the address difference. Here, the threshold value stored in the flash memory 39 is referred to as one of the seek information, and if the address difference exceeds the threshold value, the determination here is affirmed and the process proceeds to step 513.
[0091]
In step 513, a seek motor control signal corresponding to the address difference is output to the motor driver 27. As a result, the seek motor is driven to perform a seek operation. Then, the process returns to step 507.
[0092]
If it is determined in step 511 that the address difference does not exceed the threshold value, the determination here is denied and the process proceeds to step 515.
[0093]
In step 515, it is determined whether or not the current address matches the target address. If the current address does not match the target address, the determination here is denied and the routine proceeds to step 517.
[0094]
In this step 517, the current address is acquired based on the ADIP information. Then, the process returns to step 515.
[0095]
Thereafter, the processing from step 515 to step 517 is repeated until the determination at step 515 is affirmed.
[0096]
If the current address matches the target address, the determination at step 515 is affirmed, and the routine proceeds to step 519.
[0097]
In step 519, the encoder 25 is allowed to write. As a result, the recording data is written to the optical disk 15 via the encoder 25, the laser control circuit 24, and the optical pickup device 23. When all the recording data is written, a predetermined end process is performed, and then the recording process is ended.
[0098]
During the writing of the recording data, the β value is calculated based on the RF signal from the area written immediately before, and compared with the target β value stored in the RAM 41, based on the difference between them. Then, so-called running OPC is performed as needed to correct the recording power.
[0099]
《Reproduction processing》
Further, processing (reproduction processing) in the optical disc apparatus 20 when a reproduction request command is received from the host will be described with reference to FIG. The flowchart in FIG. 8 corresponds to a series of processing algorithms executed by the CPU 40. When a reproduction request command is received from the host, the start address of the program corresponding to the flowchart in FIG. Starts.
[0100]
In the first step 701, a control signal for controlling the rotation of the spindle motor 22 based on the reproduction speed is output to the motor driver 27, and the reproduction signal processing circuit 28 is notified that a reproduction request command has been received from the host. .
[0101]
In the next step 703, a signal synchronized with the rotation speed of the optical disk 15 extracted from the corrected wobble signal is referred to. When it is confirmed that the rotation of the optical disk 15 has reached a predetermined linear velocity, the servo controller 33 Set servo-on for. Thereby, tracking control and focus control are performed as described above. Note that tracking control and focus control are performed as needed until the reproduction process is completed.
[0102]
In the next step 705, the current address is acquired based on the ADIP information extracted from the corrected wobble signal.
[0103]
In the next step 707, a difference (address difference) between the current address and the target address extracted from the reproduction request command is calculated.
[0104]
In the next step 709, it is determined whether or not seeking is necessary in the same manner as in step 511. If a seek is necessary, the determination here is affirmed and the routine proceeds to step 711.
[0105]
In step 711, a seek motor control signal corresponding to the address difference is output to the motor driver 27. Then, the process returns to step 705.
[0106]
On the other hand, in step 709, if seek is not necessary, the determination here is denied and the routine proceeds to step 713.
[0107]
In this step 713, it is determined whether or not the current address matches the target address. If the current address does not match the target address, the determination here is denied and the routine proceeds to step 715.
[0108]
In step 715, the current address is acquired based on the ADIP information. Then, the process returns to step 713.
[0109]
Thereafter, the processing from step 713 to 715 is repeated until the determination in step 713 is affirmed.
[0110]
If the current address matches the target address, the determination at step 713 is affirmed, and the routine proceeds to step 717.
[0111]
In step 717, the reproduction signal processing circuit 28 is instructed to read. Thus, the reproduction data is acquired by the reproduction signal processing circuit 28 and stored in the buffer RAM 34. This reproduced data is transferred to the host via the buffer manager 37 and the interface 38 in units of sectors. When the reproduction of the data designated by the host is completed, a predetermined termination process is performed and the reproduction process is terminated.
[0112]
As is clear from the above description, in the optical disc device 20 according to the present embodiment, a processing device is realized by the CPU 40 and a program executed by the CPU 40. However, it goes without saying that the present invention is not limited to this. That is, the above embodiment is merely an example, and at least a part of the processing device realized by the processing according to the program by the CPU 40 may be configured by hardware, or all may be configured by hardware. good.
[0113]
  The signal correction method according to the present invention is implemented by the processing operation in the wobble signal correction circuit 28f.That is, a signal generation process is performed by the fixed gain amplifier circuit f1 and the AGC amplifier circuit f2, and a selection process is performed by the selector f3.
[0114]
  As described above, according to the wobble signal correction circuit 28f according to the present embodiment, the wobble signal detected by the wobble signal detection circuit 28c is transmitted to the fixed gain amplifier circuit f1 (phase modulation wave adjustment circuit) and the AGC amplifier circuit f2 ( The carrier wave adjusting means). The wobble signal supplied to the fixed gain amplifier circuit f1 is adjusted so that the amplitude of the phase modulation wave portion becomes a desired phase modulation wave amplitude. On the other hand, the wobble signal supplied to the AGC amplifier circuit f2 is adjusted so that the amplitude of the carrier wave portion becomes a desired carrier wave amplitude. The output signal of the fixed gain amplifier circuit f1(Second signal)And an output signal of the AGC amplifier circuit f2(First signal)Are respectively supplied to the selector f3 (signal selection means). The selector f3 selects the output signal of the AGC amplifier circuit f2 at the timing corresponding to the carrier wave portion in synchronization with the phase modulation signal Sphase, and the output signal of the fixed gain amplifier circuit f1 at the timing corresponding to the phase modulation wave portion. This is selected and output to the decoder 28e. That is, in the selector f3, a carrier wave portion adjusted to a desired carrier amplitude is extracted from the output signal of the AGC amplifier circuit f2, and the phase modulated wave adjusted to the desired phase modulated wave amplitude from the output signal of the fixed gain amplifier circuit f1. Part is extracted. In this case, for example, the amplitude of the carrier wave portion and the amplitude of the phase modulation wave portion can be adjusted so as to be the amplitude when there is almost no influence of the crosstalk. In this way, the wobble signal can be corrected so that both the carrier wave portion and the phase-modulated wave portion have a desired amplitude with a simpler circuit configuration than the prior art. Therefore, the wobble signal can be corrected with high accuracy without resulting in an increase in size and cost.
[0115]
Further, since the AGC amplifier circuit f2 is used as the carrier wave adjustment circuit, the wobble signal correction circuit can be configured with inexpensive general-purpose parts.
[0116]
In addition, since the fixed gain amplifier circuit f1 is used as the phase modulation wave adjustment circuit, the wobble signal correction circuit can have a simple circuit configuration.
[0117]
  In addition, according to the optical disk device 20 according to the present embodiment, the wobble signal is accurately corrected by the wobble signal correction circuit 28f, and therefore, access including at least reproduction among recording, reproduction, and erasure of information on the optical disk is accurately performed. It can be carried out. further,Wobble signal correction circuitThe downsizing of the optical disk apparatus can also promote the downsizing of the optical disk device itself and the reduction of power consumption. For example, when used as a portable device, it is easy to carry and can be used for a long time.
[0118]
  In the wobble signal correction circuit 28f of the above embodiment, the gain of the fixed gain amplifier circuit f1 is such that the phase of the target track carrier and the phase of the adjacent track carrier are mutuallyAntiphaseWhen the amplitude of the phase modulation wave portion in the output signal of the fixed gain amplifier circuit f1 is equal to the desired phase modulation wave amplitude,MatchAlthough the case where it is set to be described has been described, the present invention is not limited to this. Further, when the phase modulation wave portion whose desired phase modulation wave amplitude is adjusted by the fixed gain amplifier circuit f1 is demodulated by the decoder 28e, a demodulated signal including predetermined information such as address information can be obtained. Although the case where the amplitude satisfies the above has been described, the present invention is not limited to this. In short, it is only necessary that the carrier wave in the target track and the carrier wave in the adjacent track can be correctly extracted from the wobble signal in which predetermined information such as address information is corrected, regardless of the phase relationship.
[0119]
Further, in the wobble signal correction circuit 28f of the above embodiment, the case where the AGC amplifier circuit is used as the carrier wave adjustment circuit has been described, but the present invention is not limited to this. In short, it suffices if the wobble signal can be corrected so that the phase shift of the synchronization signal is within the allowable range.
[0120]
Furthermore, although the case where the fixed gain amplifier circuit is used as the phase modulation wave adjustment circuit has been described in the wobble signal correction circuit 28f of the above embodiment, the present invention is not limited to this. In short, it is sufficient that the wobble signal can be corrected so that predetermined information such as address information can be obtained. For example, as shown in FIGS. 9 to 14, a variable gain amplifier circuit f1 'may be used as the phase modulation wave adjustment circuit.
[0121]
In this case, the gain of the variable gain amplifier circuit f1 ′ may be set in the same manner as the gain of the fixed gain amplifier circuit f1, but as shown in FIGS. A gain of f1 ′ may be set. That is, the setting means is realized by the CPU 40 in FIGS.
[0122]
In this case, the CPU 40 can obtain a wobble signal with almost optimum correction by setting a gain corresponding to the vendor information of the optical disc (see FIG. 9). At this time, for each vendor information, the gain of the variable gain amplifier circuit f1 'when the amplitude of the phase modulation wave becomes a desired amplitude is obtained in advance by experiments or the like, and stored in the data area of the flash memory 39 or the like. The vendor information of the optical disk is usually acquired based on the ADIP information when the optical disk is loaded (mounted) on the optical disk device 20.
[0123]
For example, when the gain corresponding to the vendor information of the optical disk is not stored in the data area of the flash memory 39, the CPU 40 detects the maximum amplitude detected by the amplitude signal detection circuit f22 as shown in FIG. The gain of the variable gain amplifier circuit f1 ′ may be set based on the value. Further, as shown in FIG. 11, the CPU 40 detects the minimum value of the gain in the AGC amplifier circuit f2 from the output signal of the gain control circuit f23, and sets the gain of the variable gain amplifier circuit f1 ′ based on the detection result. You may do it. In these cases, the CPU 40 performs a wobble signal correction test when the optical disk is loaded onto the optical disk device 20, and the maximum amplitude detected by the amplitude signal detection circuit f22 or the minimum gain of the AGC amplifier circuit f2. The gain of the variable gain amplifier circuit f1 ′ may be set based on the value.
[0124]
For example, as shown in FIGS. 12 to 14, a setting circuit f4 that performs at least a part of processing performed by the CPU 40 when setting the gain of the variable gain amplifier circuit f1 ′ is added to the wobble signal correction circuit. Also good. In this case, the setting circuit f4 may set the gain of the variable gain amplifier circuit f1 'based on the vendor information from the CPU 40 (see FIG. 12). Further, the setting circuit f4 may set the gain of the variable gain amplifier circuit f1 'based on the maximum value of the amplitude detected by the amplitude signal detection circuit f22 (see FIG. 13). Furthermore, the setting circuit f4 may detect the minimum value of the gain in the AGC amplifier circuit f2 from the output signal of the gain control circuit f23, and set the gain of the variable gain amplifier circuit f1 ′ based on the detection result ( (See FIG. 14).
[0125]
  In the wobble signal correction circuit 28f of the above embodiment, the amplitude of the carrier wave portion is set to the desired carrier wave amplitude.MatchThe first signal is generated by adjusting the amplitude of the wobble signal so that the amplitude of the phase modulation wave portion is equal to the desired phase modulation wave amplitude.MatchAfter adjusting the amplitude of the wobble signal so as to generate the second signal, the first signal is selected at the timing corresponding to the carrier wave portion in the wobble signal, and the timing corresponding to the phase modulation wave portion in the wobble signal The amplitude of the carrier wave portion and the amplitude of the phase modulation wave portion in the wobble signal are individually adjusted by selecting the second signal in (2), but the present invention is not limited to this.
[0126]
  For example, after extracting the carrier wave part from the wobble signal as the first signal and extracting the phase modulation wave part as the second signal, the amplitude of the first signal is set to the desired carrier wave amplitude.MatchAnd adjusting the amplitude of the second signal to the desired phase modulation wave amplitudeMatchThe amplitude of the carrier wave part and the amplitude of the phase modulation wave part in the wobble signal may be individually adjusted by adjusting each of the adjusted signals. As an example, the wobble signal correction circuit shown in FIG. 15 extracts the carrier wave portion from the wobble signal and outputs the first signal S1 in synchronization with the phase modulation signal Sphase, and also extracts the phase modulation wave portion from the wobble signal. The separator f5 (signal extraction circuit) that outputs the second signal S2 and the amplitude of the first signal S1 is the desired carrier amplitudeMatchAn AGC amplifier circuit f2 (carrier wave adjustment circuit) that adjusts the amplitude of the first signal S1 so that the amplitude of the second signal is a desired phase modulation wave amplitudeMatchA fixed gain amplifier circuit f1 (phase modulation wave adjusting circuit) that adjusts the amplitude of the second signal so as to add, and an adder f6 that adds the output signal S3 of the AGC amplifier f2 and the output signal S4 of the fixed gain amplifier f1 ( Adding circuit). Note that the phase of the target track carrier and the phase of the adjacent track carrier are mutuallySame phaseFIG. 16 shows an example of the waveform of each signal for the above case. The output signal S5 of the adder f6 has a signal waveform substantially similar to the output signal Sd of the selector f3 shown in FIG. In this case, the above-described variable gain amplifier circuit f1 'may be used instead of the fixed gain amplifier circuit f1. The setting circuit f4 described above may be added to the wobble signal correction circuit.
  In this case, the extraction process of the signal correction method according to the present invention is performed by the separator f5, the signal generation process is performed by the AGC amplifier circuit f2 and the fixed gain amplifier circuit f1, and the addition process is performed by the adder f6. The
[0127]
In the above embodiment, the case where the phase modulation signal Sphase is generated by the decoder 28e has been described. However, the present invention is not limited to this. For example, a generation circuit for generating the phase modulation signal Sphase may be added to the wobble signal correction circuit.
[0128]
In the above embodiment, the case where the optical disk device is compatible with a disk compliant with the DVD standard has been described. However, the present invention is not limited to this. For example, the above-described semiconductor laser (blue laser) having an oscillation wavelength of about 405 nm An optical disk device using the above may be used.
[0129]
In the above embodiment, the optical disk apparatus capable of recording and reproducing information has been described. However, the present invention is not limited to this, and any optical disk apparatus capable of reproducing at least information among recording, reproducing and erasing of information may be used. .
[0130]
In the above embodiment, the case where the optical pickup device includes one semiconductor laser has been described. However, the present invention is not limited thereto, and for example, a plurality of semiconductor lasers that emit light beams having different wavelengths may be included. In this case, for example, at least one of a semiconductor laser that emits a light beam with a wavelength of about 405 nm, a semiconductor laser that emits a light beam with a wavelength of about 660 nm, and a semiconductor laser that emits a light beam with a wavelength of about 780 nm may be included. . That is, the optical disk apparatus may be an optical disk apparatus that supports a plurality of types of optical disks that conform to different standards.
[0131]
In the above embodiment, the case where the interface conforms to the ATAPI standard has been described. However, the present invention is not limited to this. For example, ATA (AT Attachment), SCSI (Small Computer System Interface), USB (Universal Serial Bus) 1.0 , USB2.0, IEEE1394, IEEE802.3, serial ATA, and serial ATAPI may be used.
[0132]
【The invention's effect】
As described above, according to the signal correction method and the wobble signal correction apparatus according to the present invention, there is an effect that the wobble signal can be accurately corrected without causing an increase in size and cost.
[0133]
In addition, according to the optical disc apparatus of the present invention, there is an effect that access to the optical disc can be performed with high accuracy.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an optical disc apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram for explaining the configuration of the optical pickup device in FIG. 1;
3 is a block diagram for explaining a configuration of a reproduction signal processing circuit in FIG. 1. FIG.
4 is a block diagram for explaining a configuration of a wobble signal correction circuit in FIG. 3; FIG.
FIG. 5 shows that wobble signal carriers in a target track and adjacent tracks are mutuallySame phase6 is a timing chart for explaining the operation of the wobble signal correction circuit in FIG.
FIG. 6 shows that the carrier waves of the wobble signal in the target track and the adjacent track are mutuallyAntiphase6 is a timing chart for explaining the operation of the wobble signal correction circuit in FIG.
FIG. 7 is a flowchart for explaining a recording process in the optical disc apparatus performed in response to a recording request command from a host.
FIG. 8 is a flowchart for explaining a reproduction process in the optical disc apparatus performed in response to a reproduction request command from a host.
FIG. 9 is a diagram for explaining a modification example (No. 1) of the wobble signal correction circuit in FIG. 3;
10 is a diagram for explaining a modification (No. 2) of the wobble signal correction circuit in FIG. 3; FIG.
11 is a diagram for explaining a modification (No. 3) of the wobble signal correction circuit in FIG. 3; FIG.
12 is a diagram for explaining a modification (No. 4) of the wobble signal correction circuit in FIG. 3; FIG.
13 is a diagram for explaining a modification (No. 5) of the wobble signal correction circuit in FIG. 3; FIG.
14 is a diagram for explaining a modification (No. 6) of the wobble signal correction circuit in FIG. 3; FIG.
15 is a diagram for explaining a modification (No. 7) of the wobble signal correction circuit in FIG. 3; FIG.
FIG. 16 shows that the carrier waves of the wobble signal in the target track and the adjacent track are mutuallySame phase16 is a timing chart for explaining the operation of the wobble signal correction circuit in FIG. 15 at that time.
FIG. 17 is a waveform diagram for explaining a wobble signal when there is crosstalk.
[Explanation of symbols]
  DESCRIPTION OF SYMBOLS 15 ... Optical disk, 20 ... Optical disk apparatus, 23 ... Optical pick-up apparatus, 28f, 28f ', 28f "... Wobble signal correction circuit, 40 ... CPU (processing apparatus, setting means), f1 ... Fixed gain amplifier circuit (Phase modulation wave adjustment) Circuit), f1 '... variable gain amplifier circuit (phase modulation wave adjustment circuit), f2 ... AGC amplifier circuit (carrier wave adjustment circuit), f3 ... selector (signal selection circuit), f5 ... separator (signal extraction circuit), f6 ... addition (Adder circuit).

Claims (14)

A signal that corrects a wobble signal that is detected based on reflected light from the recording surface of an optical disk on which spiral or concentric tracks are formed, and that includes a predetermined carrier wave portion and a phase modulation wave portion in which the carrier wave is phase-modulated. A correction method,
The first signal is generated by adjusting the amplitude of the wobble signal so that the amplitude of the carrier wave portion matches a desired carrier wave amplitude, and the information including address information can be demodulated from the phase modulation wave portion. A signal generating step of adjusting the amplitude of the wobble signal to generate the second signal;
Selecting the first signal at a timing corresponding to the carrier portion in the wobble signal and selecting the second signal at a timing corresponding to the phase modulation wave portion in the wobble signal. Signal correction method. A signal that corrects a wobble signal that is detected based on reflected light from the recording surface of an optical disk on which spiral or concentric tracks are formed, and that includes a predetermined carrier wave portion and a phase modulation wave portion in which the carrier wave is phase-modulated. A correction method,
Extracting the carrier part from the wobble signal as a first signal and extracting the phase-modulated wave part as a second signal;
A signal generation step of adjusting the amplitude of the first signal to match a desired carrier amplitude and adjusting the amplitude of the second signal so that information including address information can be demodulated;
An addition step of adding the adjusted first signal and the adjusted second signal. A wobble that corrects a wobble signal that is detected based on reflected light from the recording surface of an optical disk on which spiral or concentric tracks are formed, and that includes a predetermined carrier wave portion and a phase modulation wave portion in which the carrier wave is phase-modulated. A signal correction circuit,
A carrier wave adjustment circuit for adjusting the amplitude of the wobble signal so that the amplitude of the carrier wave part matches a desired carrier wave amplitude;
A phase modulation wave adjustment circuit for adjusting the amplitude of the wobble signal so that information including address information can be demodulated from the phase modulation wave portion;
A signal that selects the output signal of the carrier wave adjustment circuit at a timing corresponding to the carrier wave portion in synchronization with the wobble signal and that selects the output signal of the phase modulation wave adjustment circuit at a timing corresponding to the phase modulation wave portion. A wobble signal correction circuit comprising: a selection circuit; A wobble that corrects a wobble signal that is detected based on reflected light from the recording surface of an optical disk on which spiral or concentric tracks are formed, and that includes a predetermined carrier wave portion and a phase modulation wave portion in which the carrier wave is phase-modulated. A signal correction circuit,
A signal extraction circuit for extracting the carrier wave portion from the wobble signal and outputting it as a first signal, and extracting the phase modulated wave portion from the wobble signal and outputting it as a second signal;
A carrier adjustment circuit that adjusts the amplitude of the first signal so that the amplitude of the first signal matches a desired carrier amplitude;
A phase modulation wave adjustment circuit for adjusting an amplitude of the second signal so that information including address information can be demodulated from the second signal;
An addition circuit for adding an output signal of the carrier wave adjustment circuit and an output signal of the phase modulation wave adjustment circuit.   5. The wobble signal correction circuit according to claim 3, wherein the carrier wave adjustment circuit is an auto gain control amplifier circuit.   6. The wobble signal correction circuit according to claim 3, wherein the phase modulation wave adjustment circuit is a fixed gain amplifier circuit. The gain of the fixed gain amplifier circuit, when the said carrier portion in the wobble signal of the track adjacent to the phase and the target track of the carrier portion definitive wobble signal of the target track phase of mutually opposite phases, the phase modulation 7. The wobble signal correction circuit according to claim 6, wherein information including address information can be demodulated from the wave portion .   The wobble signal correction circuit according to claim 3, wherein the phase modulation wave adjustment circuit is a variable gain amplifier circuit.   9. The wobble signal correction circuit according to claim 8, wherein the gain of the variable gain amplifier circuit is set based on vendor information of the optical disc.   9. The wobble signal correction circuit according to claim 8, wherein the gain of the variable gain amplifier circuit is set based on a maximum amplitude of the carrier wave portion in the wobble signal. An optical disc apparatus that performs at least reproduction of information recording, reproduction, and erasure with respect to an optical disc on which a spiral or concentric track is formed on a recording surface,
An optical pickup device that irradiates a recording surface of the optical disc with a light beam and receives reflected light from the recording surface;
The wobble signal correction circuit according to any one of claims 3 to 10, wherein a wobble signal detected from an output signal of the optical pickup device is corrected.
An optical disk apparatus comprising: a processing apparatus that performs at least reproduction of information recording, reproduction, and erasure through the optical pickup apparatus. An optical disc apparatus that performs at least reproduction of information recording, reproduction, and erasure with respect to an optical disc on which a spiral or concentric track is formed on a recording surface,
An optical pickup device that irradiates a recording surface of the optical disc with a light beam and receives reflected light from the recording surface;
The wobble signal correction circuit according to claim 8, wherein a wobble signal detected from an output signal of the optical pickup device is corrected;
Setting means for setting the gain of the variable gain amplifier circuit;
An optical disk device comprising: a processing device that performs at least reproduction of data recording, reproduction, and erasure via the optical pickup device. A memory in which the optimum gain of the variable gain amplifier circuit is stored for each vendor information;
Vendor information acquisition means for acquiring vendor information of the optical disc;
The said setting means extracts the gain corresponding to the vendor information acquired by the vendor information acquisition means from the memory, and sets the gain to the gain of the variable gain amplifier circuit. Optical disk device.   The optical disc apparatus according to claim 12, wherein the setting means sets a gain of the variable gain amplifier circuit based on a maximum value of an amplitude of the carrier wave portion in the wobble signal.

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