WO2010106755A1 - 光ディスク装置、フォーカス制御方法及び集積回路 - Google Patents
光ディスク装置、フォーカス制御方法及び集積回路 Download PDFInfo
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- WO2010106755A1 WO2010106755A1 PCT/JP2010/001598 JP2010001598W WO2010106755A1 WO 2010106755 A1 WO2010106755 A1 WO 2010106755A1 JP 2010001598 W JP2010001598 W JP 2010001598W WO 2010106755 A1 WO2010106755 A1 WO 2010106755A1
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- Prior art keywords
- recording layer
- spherical aberration
- focus
- aberration correction
- interlayer distance
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- G—PHYSICS
- G11—INFORMATION STORAGE
- G11B—INFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
- G11B7/00—Recording or reproducing by optical means, e.g. recording using a thermal beam of optical radiation by modifying optical properties or the physical structure, reproducing using an optical beam at lower power by sensing optical properties; Record carriers therefor
- G11B7/08—Disposition or mounting of heads or light sources relatively to record carriers
- G11B7/085—Disposition or mounting of heads or light sources relatively to record carriers with provision for moving the light beam into, or out of, its operative position or across tracks, otherwise than during the transducing operation, e.g. for adjustment or preliminary positioning or track change or selection
- G11B7/08505—Methods for track change, selection or preliminary positioning by moving the head
- G11B7/08511—Methods for track change, selection or preliminary positioning by moving the head with focus pull-in only
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- G—PHYSICS
- G11—INFORMATION STORAGE
- G11B—INFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
- G11B7/00—Recording or reproducing by optical means, e.g. recording using a thermal beam of optical radiation by modifying optical properties or the physical structure, reproducing using an optical beam at lower power by sensing optical properties; Record carriers therefor
- G11B7/12—Heads, e.g. forming of the optical beam spot or modulation of the optical beam
- G11B7/135—Means for guiding the beam from the source to the record carrier or from the record carrier to the detector
- G11B7/1392—Means for controlling the beam wavefront, e.g. for correction of aberration
- G11B7/13922—Means for controlling the beam wavefront, e.g. for correction of aberration passive
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- G—PHYSICS
- G11—INFORMATION STORAGE
- G11B—INFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
- G11B7/00—Recording or reproducing by optical means, e.g. recording using a thermal beam of optical radiation by modifying optical properties or the physical structure, reproducing using an optical beam at lower power by sensing optical properties; Record carriers therefor
- G11B2007/0003—Recording, reproducing or erasing systems characterised by the structure or type of the carrier
- G11B2007/0009—Recording, reproducing or erasing systems characterised by the structure or type of the carrier for carriers having data stored in three dimensions, e.g. volume storage
- G11B2007/0013—Recording, reproducing or erasing systems characterised by the structure or type of the carrier for carriers having data stored in three dimensions, e.g. volume storage for carriers having multiple discrete layers
Definitions
- the present invention relates to an optical disk apparatus for recording and reproducing information by irradiating a recording surface of an optical disk having a plurality of layers to record and reproduce information, a focus control method for controlling the focus of the light beam applied to the optical disk, and the light beam applied to the optical disk.
- the present invention relates to an integrated circuit that controls the focus.
- Measures for increasing the recording capacity of an optical disc include increasing the density of the optical disc and increasing the number of recording layers.
- Blu-ray Disc increases the numerical aperture (NA) of the objective lens from 0.6 to 0.85 and shortens the laser wavelength from 650 nm to 405 nm to increase the density of the optical disc and to record.
- NA numerical aperture
- the recording capacity of one optical disk is set to 50 GB.
- this spherical aberration correction operation there is a case where an operation of changing the focal position of the light beam from the current recording layer to another recording layer is performed.
- the operation of changing the focal position of the light beam from the current recording layer to another recording layer is generally called a focus jump.
- Spherical aberration not only degrades reproduction and recording performance, but also degrades the quality of servo signals for performing focus control and tracking control.
- the spherical aberration is corrected so as to be in an optimum state at an intermediate position between the current recording layer and the destination target recording layer prior to the focus jump.
- a technique for correcting the aberration so as to be in an optimum state in the target recording layer at the movement destination is disclosed.
- a stable focus jump operation can be realized by such a procedure.
- Patent Document 2 discloses a technique for executing a focus jump by correcting spherical aberration so as to be in an optimum state in a target recording layer at a movement destination prior to the focus jump.
- a stable focus jump operation can be realized by such a procedure.
- the thickness between the surface and the recording layer closest to the surface must be at least 50 ⁇ m in order to ensure the reproduction and recording performance against dust and fingerprints on the surface on which the light beam is incident.
- the thickness between the surface and the recording layer farthest from the surface cannot be increased greatly.
- the thickness between the surface and the recording layer farthest from the surface is 100 ⁇ m.
- the distance between the recording layers cannot be equal (if the distance between the recording layers is equal, the reflected light from the focused recording layer and the recording layer that is two distances away from the focused recording layer) Interference with the reflected light from the back side).
- the interlayer distance between the recording layers cannot be so narrow (the interference between adjacent recording layers increases, so the minimum interlayer distance is about 10 ⁇ m).
- FIG. 11 is a diagram showing a layer structure of a multilayer optical disc.
- An optical disc 31 shown in FIG. 11 includes a first recording layer L0 farthest from the surface 201 on which the light beam is incident, a second recording layer L1 second farthest from the surface 201, and a third farthest third from the surface 201.
- Recording layer L2 the fourth recording layer L3 closest to the surface 201, the cover layer 203 disposed between the fourth recording layer L3 and the surface 201, the third recording layer L2 and the fourth recording layer L4.
- the first intermediate layer 204 disposed between the recording layer L3, the second intermediate layer 205 disposed between the second recording layer L1 and the third recording layer L2, and the first recording A third intermediate layer 206 disposed between the layer L0 and the second recording layer L1; and a fourth intermediate layer 207 disposed between the first recording layer L0 and the label surface 202. .
- the innermost recording layer when viewed from the light beam incident side is referred to as a first recording layer L0.
- the second recording layer L1, the third recording layer L2, and the second recording layer L2 are sequentially arranged from the first recording layer L0 toward the optical disc surface side.
- This is called a fourth recording layer L3.
- the interlayer distance between the first recording layer L0 and the second recording layer L1 is 17 ⁇ m
- the interlayer distance between the second recording layer L1 and the third recording layer L2 is 20 ⁇ m
- the interlayer distance between the third recording layer L2 and the fourth recording layer L3 is 13 ⁇ m
- the interlayer distance between the fourth recording layer L3 and the surface 201 is 50 ⁇ m.
- Patent Document 3 proposes a layer structure of a multilayer optical disc having four recording layers.
- FIGS. 12A to 12D show focus error signals obtained when a light beam is incident on the multilayer optical disc.
- FIGS. 12A to 12D are diagrams showing focus error signals detected when spherical aberration is optimized for each recording layer of the multilayer optical disc.
- FIG. 12A is a diagram showing a focus error signal obtained in a state where the spherical aberration is optimally adjusted with respect to the first recording layer L0
- FIG. 12B shows the second recording layer L1.
- FIG. 12C is a diagram showing a focus error signal obtained when the spherical aberration is optimally adjusted
- FIG. 12C is a focus obtained when the spherical aberration is optimally adjusted with respect to the third recording layer L2.
- FIG. 12D is a diagram illustrating a focus error signal obtained in a state where the spherical aberration is optimally adjusted with respect to the fourth recording layer L3.
- a focus error signal 301 is a focus error signal corresponding to the first recording layer L0
- a focus error signal 302 is a focus error signal corresponding to the second recording layer L1.
- the focus error signal 303 is a focus error signal corresponding to the third recording layer L2
- the focus error signal 304 is a focus error signal corresponding to the fourth recording layer L3.
- the focus error signal of the recording layer in which the spherical aberration is not optimized is greatly deteriorated, and stable focus control cannot be realized in this state.
- FIG. 13 is a diagram showing a configuration of a conventional optical disc apparatus.
- a reproduction signal quality indicator generator 28 a disk motor 29, a microcomputer 51, and a control unit 52.
- the optical pickup 11 irradiates the optical disk 31 with a light beam and reads information recorded on the optical disk 31.
- the optical pickup 11 irradiates the optical disc 31 with a light beam and records information on the optical disc 31.
- the focus actuator drive circuit 21 displaces the objective lens 1 of the optical pickup 11 in a direction substantially perpendicular to the optical disk 31.
- the optical disk apparatus shown in FIG. 13 records information on the optical disk 31 or reproduces information recorded on the optical disk 31.
- the light beam emitted from the laser light source 9 provided in the optical pickup 11 is converted into a parallel light beam by the collimator lens 8.
- the parallel light beam passes through the spherical aberration correction unit 7, the polarization beam splitter 10, and the 1 ⁇ 4 wavelength plate 6, and is converged on the information recording surface (recording film) of the optical disk 31 by the objective lens 1.
- Reflected light from the optical disk 31 passes through the objective lens 1 and the quarter-wave plate 6, is reflected by the polarization beam splitter 10, and reaches the light receiving unit 5.
- the optical disk 31 is rotationally driven by a disk motor 29.
- the light receiving unit 5 converts the reflected light from the optical disk 31 into an electrical signal.
- the output of the light receiving unit 5 is supplied to a focus error signal generator 25, a tracking error signal generator 26, and an RF signal generator 27.
- the focus error signal generator 25 detects a misalignment between the focus position of the light beam irradiated on the optical disc 31 and the information recording surface of the optical disc 31 based on the output of the light receiving unit 5, and the detected misalignment is detected. Output as a focus error signal.
- the focus error signal can be generated by an astigmatism method, for example.
- the tracking error signal generator 26 detects a positional deviation between a light beam spot formed on the information recording surface of the optical disc 31 and a track on the information recording surface of the optical disc 31 based on the output of the light receiving unit 5.
- the detected positional deviation is output as a tracking error signal.
- the tracking error signal can be generally generated by a push-pull method.
- the focus error signal and tracking error signal are supplied to the control unit 52.
- the control unit 52 performs signal processing such as phase compensation on the focus error signal and the tracking error signal to generate a control signal.
- the focus actuator drive circuit 21 drives the focus actuator 2 by supplying a drive signal to the focus actuator 2 provided in the optical pickup 11 in accordance with a control signal from the control unit 52.
- the tracking actuator drive circuit 22 drives the tracking actuator 3 by supplying a drive signal to the tracking actuator 3 provided in the optical pickup 11 in accordance with a control signal from the control unit 52.
- the focus actuator 2 drives the objective lens 1 in accordance with a drive signal from the focus actuator drive circuit 21.
- the tracking actuator 3 drives the objective lens 1 in accordance with a drive signal from the tracking actuator drive circuit 22.
- control unit 52 controls the focus actuator drive circuit 21 that drives the focus actuator 2 in accordance with the focus error signal, thereby forming a servo loop for focus control. Further, the control unit 52 controls the tracking actuator drive circuit 22 that drives the tracking actuator 3 according to the tracking error signal, thereby forming a servo loop for tracking control. In this way, servo control is executed.
- the RF signal generator 27 generates an RF signal based on the output of the light receiving unit 5, and outputs the RF signal to the reproduction signal quality indicator generator 28. Based on the RF signal obtained from the RF signal generator 27, the reproduction signal quality index generator 28 generates a reproduction signal quality index indicating the reproduction performance of the reproduction signal. Examples of the reproduction signal quality index include jitter and error rate.
- the reproduction signal quality indicator generated by the reproduction signal quality indicator generator 28 is supplied to the microcomputer 51.
- the spherical aberration correction actuator drive circuit 23 corrects spherical aberration by supplying a drive signal to the spherical aberration correction unit 7 in accordance with a control signal from the microcomputer 51.
- the correction amount of the spherical aberration can be determined according to the distance from the optical disk surface to each recording layer determined by, for example, the standard of the optical disk.
- the microcomputer 51 supplies a drive command value for performing a focus jump operation to the control unit 52.
- a drive signal based on this drive command value is supplied to the focus actuator drive circuit 21, and the focus actuator 2 is driven.
- FIG. 14 shows changes in the focus error signal 401, the focus actuator drive output 402, and the signal 403 indicating the spherical aberration correction amount during the conventional interlayer movement.
- the state L420 represents a state where the spherical aberration corresponding to the first recording layer L0 is optimal
- the state L421 represents the state where the spherical aberration corresponding to the second recording layer L1 is optimal
- the state L422 is A state in which the spherical aberration corresponding to the third recording layer L2 is optimal is represented
- a state L423 represents a state in which the spherical aberration corresponding to the fourth recording layer L3 is optimal.
- the signal 403 indicating the spherical aberration correction amount has a state L422 as an initial state.
- the optical disc apparatus starts a spherical aberration correction operation at timing T102.
- the optical disc apparatus adjusts the spherical aberration correction amount from the state L422 to the state L421 while operating the focus control from the timing T102 to the timing T104.
- the focus control is lost at the timing T103 in the middle of changing the spherical aberration correction amount from the state L422 to the state L421.
- the spot position of the light beam passes through the surface of the optical disc, and the focus jump operation fails.
- the increase in the number of recording layers increases the interlayer distance from the recording layer closest to the surface to the recording layer farthest from the surface. Therefore, a wide range of spherical aberration correction corresponding to this interlayer distance is possible. Necessary.
- a mode in which the spherical aberration correction element is moved by a stepping motor is generally used.
- the size of the optical pickup is limited, and the stepping motor having a high output becomes large, so that it is difficult to fit in the optical pickup.
- the stepping motor that drives the spherical aberration correction element is small in size and low in output, and it is difficult to increase the driving speed of the spherical aberration correction element. Furthermore, since the drive control of the stepping motor is generally performed with a trapezoidal speed profile that gradually accelerates or decelerates to prevent step-out, the drive time becomes long if the drive and stop are continuously performed.
- the present invention has been made to solve the above-described problems, and an object of the present invention is to provide an optical disc apparatus, a focus control method, and an integrated circuit that can perform a focus jump stably.
- An optical disc apparatus is an optical disc apparatus that reads information recorded on the optical disc or records information on the optical disc by irradiating an optical disc having a plurality of recording layers with a light beam.
- a spherical aberration correction unit that corrects a spherical aberration generated in a light spot on the recording layer, a focus control unit that focuses the light beam on a predetermined recording layer, and a current recording position of the focal point of the light beam
- the focus jump for controlling the spherical aberration correction by the spherical aberration correction unit and the movement of the in-focus position by the focus jump unit And a control unit.
- the light spot on the recording layer is generated based on the interlayer distance between the current recording layer and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved. Correction of spherical aberration and movement of the focal position of the light beam are controlled.
- the correction of spherical aberration and the focal position Therefore, the influence of the adjacent recording layer on the focus error signal can be considered, and the focus jump can be performed stably.
- FIG. 6 is a flowchart for explaining a procedure of a focus jump from the second recording layer to the third recording layer in the first embodiment.
- FIG. 6 is a diagram illustrating changes in a focus error signal, a focus actuator drive output, and a signal indicating a spherical aberration correction amount during interlayer movement from the second recording layer to the third recording layer in the first embodiment.
- FIG. 6 is a diagram illustrating changes in a focus error signal, a focus actuator drive output, and a signal indicating a spherical aberration correction amount during interlayer movement from a third recording layer to a second recording layer in the first embodiment.
- FIG. 10 is a diagram illustrating changes in a focus error signal, a focus actuator drive output, and a signal indicating a spherical aberration correction amount during interlayer movement from the second recording layer to the third recording layer in the second embodiment.
- FIG. 10 is a diagram illustrating changes in a focus error signal, a focus actuator drive output, and a signal indicating a spherical aberration correction amount during interlayer movement from a third recording layer to a second recording layer in the second embodiment.
- FIG. 10 is a diagram illustrating changes in a focus error signal, a focus actuator drive output, and a signal indicating a spherical aberration correction amount during interlayer movement from a third recording layer to a second recording layer in the second embodiment.
- FIG. 10 is a diagram illustrating changes in a focus error signal, a focus actuator drive output, and a signal indicating a spherical aberration correction amount during interlayer movement from a third recording layer to a second recording layer in the third embodiment.
- Embodiment 4 it is a figure which shows the change of the signal which shows a focus error signal, a focus actuator drive output, and a spherical aberration correction amount at the time of the interlayer movement from the 4th recording layer to the 1st recording layer. It is a figure which shows the layer structure of a multilayer optical disk.
- (A) is a figure which shows the focus error signal obtained in the state which adjusted spherical aberration optimally with respect to the 1st recording layer
- (B) is optimal spherical aberration with respect to the 2nd recording layer
- (C) is a diagram showing a focus error signal obtained in a state where spherical aberration is optimally adjusted with respect to the third recording layer
- D) is a diagram showing a focus error signal obtained in a state where the spherical aberration is optimally adjusted with respect to the fourth recording layer.
- It is a figure which shows the structure of the conventional optical disk apparatus. It is a figure which shows the change of the signal which shows a focus error signal, the focus actuator drive output, and the spherical aberration correction amount at the time of the conventional interlayer movement.
- FIG. 1 is a block diagram showing the configuration of the optical disc apparatus according to Embodiment 1 of the present invention.
- the optical pickup 11 includes an objective lens 1, a focus actuator 2, a tracking actuator 3, a light receiving unit 5, a quarter wavelength plate 6, a spherical aberration correction unit 7, a collimator lens 8, a laser light source 9, and a polarization beam splitter 10.
- the optical pickup 11 irradiates the optical disk 31 with a light beam and reads information recorded on the optical disk 31.
- the optical pickup 11 irradiates the optical disc 31 with a light beam and records information on the optical disc 31.
- the focus actuator drive circuit 21 displaces the objective lens 1 of the optical pickup 11 in a substantially vertical direction (optical axis direction) with respect to the optical disc 31.
- the optical disc apparatus shown in FIG. 1 records information on the optical disc 31 or reads information recorded on the optical disc 31 by irradiating the optical disc 31 having a plurality of recording layers with a light beam.
- the light beam emitted from the laser light source 9 provided in the optical pickup 11 is converted into a parallel light beam by the collimator lens 8.
- the parallel light beam passes through the spherical aberration correction unit 7, the polarization beam splitter 10, and the 1 ⁇ 4 wavelength plate 6, and is converged on the information recording surface (recording film) of the optical disk 31 by the objective lens 1.
- Reflected light from the optical disk 31 passes through the objective lens 1 and the quarter-wave plate 6, is reflected by the polarization beam splitter 10, and reaches the light receiving unit 5.
- the optical disk 31 is rotationally driven by a disk motor 29.
- the light receiving unit 5 converts the reflected light from the optical disk 31 into an electrical signal.
- the output of the light receiving unit 5 is supplied to a focus error signal generator 25, a tracking error signal generator 26, and an RF signal generator 27.
- the focus error signal generator 25 detects a misalignment between the focus position of the light beam irradiated on the optical disc 31 and the information recording surface of the optical disc 31 based on the output of the light receiving unit 5, and the detected misalignment is detected. Output as a focus error signal.
- the focus error signal can be generated by an astigmatism method, for example.
- the tracking error signal generator 26 detects a positional deviation between a light beam spot formed on the information recording surface of the optical disc 31 and a track on the information recording surface of the optical disc 31 based on the output of the light receiving unit 5.
- the detected positional deviation is output as a tracking error signal.
- the tracking error signal can be generally generated by a push-pull method.
- the focus error signal and tracking error signal are supplied to the control unit 52.
- the control unit 52 performs signal processing such as phase compensation on the focus error signal and the tracking error signal, and generates a control signal for controlling the focus actuator drive circuit 21 and the tracking actuator drive circuit 22.
- the control unit 52 focuses the light beam on a predetermined recording layer. Further, the control unit 52 moves the focal position of the light beam from the current recording layer to another recording layer.
- the focus actuator drive circuit 21 drives the focus actuator 2 by supplying a drive signal to the focus actuator 2 provided in the optical pickup 11 in accordance with a control signal from the control unit 52.
- the tracking actuator drive circuit 22 drives the tracking actuator 3 by supplying a drive signal to the tracking actuator 3 provided in the optical pickup 11 in accordance with a control signal from the control unit 52.
- the focus actuator 2 drives the objective lens 1 in accordance with a drive signal from the focus actuator drive circuit 21.
- the tracking actuator 3 drives the objective lens 1 in accordance with a drive signal from the tracking actuator drive circuit 22.
- control unit 52 controls the focus actuator drive circuit 21 that drives the focus actuator 2 in accordance with the focus error signal, thereby forming a servo loop for focus control. Further, the control unit 52 controls the tracking actuator drive circuit 22 that drives the tracking actuator 3 according to the tracking error signal, thereby forming a servo loop for tracking control. In this way, servo control is executed.
- the RF signal generator 27 generates an RF signal based on the output of the light receiving unit 5, and outputs the RF signal to the reproduction signal quality indicator generator 28. Based on the RF signal obtained from the RF signal generator 27, the reproduction signal quality index generator 28 generates a reproduction signal quality index indicating the reproduction performance of the reproduction signal. Examples of the reproduction signal quality index include jitter and error rate.
- the reproduction signal quality indicator generated by the reproduction signal quality indicator generator 28 is supplied to the microcomputer 51.
- the spherical aberration correction actuator drive circuit 23 corrects spherical aberration by supplying a drive signal to the spherical aberration correction unit 7 in accordance with a control signal from the microcomputer 51.
- the correction amount of the spherical aberration can be determined according to the distance from the optical disk surface to each recording layer determined by the standard of the multilayer optical disk, for example.
- the spherical aberration correction unit 7 corrects spherical aberration generated in the light spot on the recording layer by moving a spherical aberration correction element (for example, a collimator lens) with a stepping motor.
- a spherical aberration correction element for example, a collimator lens
- the spherical aberration correction unit 7 is not limited to a collimator lens and a stepping motor.
- the spherical aberration correction unit 7 may correct the spherical aberration with a liquid crystal.
- the microcomputer 51 supplies a drive command value for performing a focus jump operation to the control unit 52.
- a drive signal based on this drive command value is supplied to the focus actuator drive circuit 21, and the focus actuator 2 is driven.
- the microcomputer 51 includes an interlayer distance information acquisition unit 53 and a focus jump control unit 60.
- the interlayer distance information acquisition unit 53 acquires interlayer distance information of each recording layer that the optical disc 31 has.
- the focus jump control unit 60 acquires the interlayer distance between the current recording layer acquired by the interlayer distance information acquisition unit 53 and the recording layer adjacent to the direction opposite to the direction in which the focal position of the light beam is moved.
- the spherical aberration correction by the spherical aberration correction actuator drive circuit 23 and the movement of the in-focus position by the focus actuator drive circuit 21 are controlled based on the above.
- the focus jump control unit 60 uses the spherical aberration correction actuator drive circuit 23 based on the interlayer distance between the current recording layer and the recording layer existing within a predetermined distance range from the current recording layer. The correction of the spherical aberration and the movement of the in-focus position by the focus actuator drive circuit 21 are controlled.
- the focus jump control unit 60 includes an interlayer movement procedure determination unit 54 and an interlayer movement procedure instruction unit 55.
- the interlayer movement procedure determination unit 54 determines the interlayer distance between the current recording layer acquired by the interlayer distance information acquisition unit 53 and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved. Based on the above, it is determined which of the spherical aberration correction by the spherical aberration correction actuator drive circuit 23 and the movement of the in-focus position by the focus actuator drive circuit 21 is performed first. That is, the interlayer movement procedure determination unit 54, based on the interlayer distance information acquired by the interlayer distance information acquisition unit 53, a drive command value for performing a focus jump operation supplied to the control unit 52, and spherical aberration correction actuator drive The procedure for outputting the drive signal supplied to the circuit 23 is determined.
- the interlayer movement procedure instruction unit 55 Based on the determination result of the interlayer movement procedure determination unit 54, the interlayer movement procedure instruction unit 55 outputs a drive signal to the control unit 52 and the spherical aberration correction actuator drive circuit 23. That is, when it is determined by the interlayer movement procedure determination unit 54 that the spherical aberration is corrected first, the interlayer movement procedure instruction unit 55 corrects the spherical aberration generated in the light spot on the recording layer as the movement destination. The spherical aberration correction actuator drive circuit 23 is instructed. Thereafter, the interlayer movement procedure instruction unit 55 instructs the control unit 52 to move the focused position of the light beam from the current recording layer to another recording layer.
- the interlayer movement procedure instruction unit 55 moves the focal position of the light beam from the current recording layer to another recording layer.
- the control unit 52 is instructed.
- the interlayer movement procedure instruction unit 55 instructs the spherical aberration correction actuator drive circuit 23 to correct the spherical aberration generated in the light spot on the movement-destination recording layer.
- control unit 52 and the microcomputer 51 are preferably configured of one or more digital circuits.
- the control unit 52 and the microcomputer 51 can be integrated on a single semiconductor integrated circuit board (single semiconductor chip).
- the spherical aberration correction unit 7 and the spherical aberration correction actuator drive circuit 23 correspond to an example of a spherical aberration correction unit
- the focus actuator drive circuit 21 and the control unit 52 correspond to an example of a focus control unit.
- the focus actuator drive circuit 21 and the control unit 52 correspond to an example of a focus jump unit
- the interlayer distance information acquisition unit 53 corresponds to an example of an interlayer distance acquisition unit
- the focus jump control unit 60 corresponds to an example of a focus jump control unit.
- the focus actuator drive circuit 21 corresponds to an example of a drive unit.
- the optical disc 31 is a four-layer optical disc having four recording layers.
- the optical disc 31 includes a first recording layer L0 farthest from the surface 201 on which the light beam is incident, a second recording layer L1 second from the surface 201, and a third recording layer L2 third from the surface 201.
- the first intermediate layer 204 disposed between the second recording layer L1, the second intermediate layer 205 disposed between the second recording layer L1 and the third recording layer L2, the first recording layer L0 and the first recording layer L0.
- a third intermediate layer 206 disposed between the second recording layer L1 and a fourth intermediate layer 207 disposed between the first recording layer L0 and the label surface 202.
- the cover layer 203, the first intermediate layer 204, the second intermediate layer 205, the third intermediate layer 206, and the fourth intermediate layer 207 are transparent.
- the distance between the recording layers is limited for the following reasons.
- the thickness between the surface and the recording layer closest to the surface must be at least 50 ⁇ m in order to ensure the reproduction and recording performance against dust and fingerprints on the surface on which the light beam is incident.
- the thickness between the surface and the recording layer farthest from the surface cannot be increased greatly.
- the thickness between the surface and the recording layer farthest from the surface is 100 ⁇ m.
- the distance between the recording layers cannot be equal (if the distance between the recording layers is equal, the reflected light from the focused recording layer and the recording layer that is two distances away from the focused recording layer) Interference with the reflected light from the back side).
- the interlayer distance between the recording layers cannot be so narrow (the interference between adjacent recording layers increases, so the minimum interlayer distance is about 10 ⁇ m).
- the distance between the recording layers is not uniform.
- the distance between the recording layers varies within the range satisfying the above conditions (1) to (4) due to manufacturing variations.
- the distance between the first recording layer L0 and the surface 201 is 100 ⁇ m
- the distance between the second recording layer L1 and the surface 201 is 83 ⁇ m
- the third The distance between the recording layer L2 and the surface 201 is 63 ⁇ m
- the distance between the fourth recording layer L3 and the surface 201 is 50 ⁇ m.
- the interlayer distance between the first recording layer L0 and the second recording layer L1 is 17 ⁇ m
- the interlayer distance between the second recording layer L1 and the third recording layer L2 is 20 ⁇ m
- the interlayer distance between the third recording layer L2 and the fourth recording layer L3 is 13 ⁇ m
- the interlayer distance between the fourth recording layer L3 and the surface 201 is 50 ⁇ m.
- FIG. 12A is a diagram showing a focus error signal obtained in a state in which the spherical aberration is optimally adjusted with respect to the first recording layer L0, and the focus error signal 301 of the first recording layer L0. The amplitude of is the largest.
- FIG. 12B is a diagram illustrating a focus error signal obtained in a state where the spherical aberration is optimally adjusted with respect to the second recording layer L1
- FIG. 12C is a diagram illustrating the third recording layer.
- FIG. 12D is a diagram showing a focus error signal obtained in a state where the spherical aberration is optimally adjusted with respect to the layer L2, and FIG. 12D is a state where the spherical aberration is optimally adjusted with respect to the fourth recording layer L3. It is a figure which shows the focus error signal obtained.
- the optical disc apparatus according to Embodiment 1 is provided between the current recording layer in which the light beam is focused and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved.
- the procedure between the focus jump operation and the spherical aberration correction operation is switched based on the interlayer distance.
- FIG. 2 is a flowchart for explaining a focus jump procedure from the second recording layer L1 to the third recording layer L2 in the first embodiment.
- step S ⁇ b> 1 the interlayer distance information acquisition unit 53 acquires interlayer distance information of each recording layer of the optical disc 31.
- the interlayer distance information acquisition unit 53 determines the type of the optical disk 31 when the optical disk 31 is loaded, and determines the interlayer distance between the recording layers according to the determined type. A method for acquiring interlayer distance information by the interlayer distance information acquiring unit 53 will be described later.
- the interlayer movement procedure determination unit 54 determines that the interlayer distance between the current recording layer and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved is the current distance. It is determined whether or not the distance between the recording layer and the recording layer adjacent in the direction in which the focal position of the light beam is moved is smaller. In the present embodiment, the interlayer movement procedure determination unit 54 determines that the interlayer distance D1 between the second recording layer L1 and the first recording layer L0 is the second recording layer L1 and the third recording layer L2. It is determined whether or not the distance is less than the interlayer distance D2.
- step S3 the interlayer movement procedure determination unit 54 moves the current recording layer and the focal position of the light beam. It is determined whether or not the distance between the recording layers adjacent in the opposite direction is greater than a predetermined threshold. In the present embodiment, the interlayer movement procedure determination unit 54 determines whether or not the interlayer distance D1 is greater than a predetermined threshold ThD.
- the threshold ThD represents an interlayer distance that does not affect the detection of the focus error signal of the current recording layer.
- step S4 the interlayer movement procedure instruction unit 55 determines the light on the recording layer (third recording layer L2) as the movement destination.
- the spherical aberration correction actuator drive circuit 23 is instructed to correct the spherical aberration generated in the spot.
- the spherical aberration correction actuator drive circuit 23 drives the spherical aberration correction unit 7 and corrects the spherical aberration generated in the light spot on the recording layer (third recording layer L2) as the movement destination.
- step S5 the interlayer movement procedure instruction unit 55 moves the focal position of the light beam from the current recording layer (second recording layer L1) to another recording layer (third recording layer L2).
- the control unit 52 is instructed as follows.
- the control unit 52 outputs a drive signal to the focus actuator drive circuit 21, and the focus actuator drive circuit 21 drives the focus actuator 2 to set the in-focus position of the light beam to the current recording layer (second recording layer L1). To another recording layer (third recording layer L2).
- step S6 If it is determined that the interlayer distance D1 is greater than or equal to the interlayer distance D2 (NO in step S2), or if it is determined that the interlayer distance D1 is less than or equal to the predetermined threshold ThD (NO in step S3), step S6 , The interlayer movement procedure instruction unit 55 moves the focus position of the light beam from the current recording layer (second recording layer L1) to another recording layer (third recording layer L2). To instruct.
- the control unit 52 outputs a drive signal to the focus actuator drive circuit 21, and the focus actuator drive circuit 21 drives the focus actuator 2 to set the in-focus position of the light beam to the current recording layer (second recording layer L1). To another recording layer (third recording layer L2).
- step S7 the interlayer movement procedure instruction unit 55 causes the spherical aberration correction actuator drive circuit 23 to correct the spherical aberration that occurs in the light spot on the movement-destination recording layer (third recording layer L2). Instruct.
- the spherical aberration correction actuator drive circuit 23 drives the spherical aberration correction unit 7 and corrects the spherical aberration generated in the light spot on the recording layer (third recording layer L2) as the movement destination.
- FIG. 3 shows a focus error signal 401, a focus actuator drive output 402, and a signal 403 indicating a spherical aberration correction amount when moving the layer from the second recording layer L1 to the third recording layer L2 in the first embodiment. It is a figure which shows the change of.
- the state L420 represents a state where the spherical aberration corresponding to the first recording layer L0 is optimal
- the state L421 represents the state where the spherical aberration corresponding to the second recording layer L1 is optimal
- the state L422 is A state in which the spherical aberration corresponding to the third recording layer L2 is optimal is represented
- a state L423 represents a state in which the spherical aberration corresponding to the fourth recording layer L3 is optimal.
- the signal 403 indicating the spherical aberration correction amount has a state L421 as an initial state.
- the interlayer distance D1 between the first recording layer L0 and the second recording layer L1 is 17 ⁇ m, and the second recording layer L1 and the third recording layer L1
- the distance D2 between the recording layers L2 is 20 ⁇ m, and the second recording layer L1 is sufficiently separated from any adjacent recording layers. Therefore, as shown in FIG. 12B, the focus error signals 301, 302, and 303 obtained in the first recording layer L0, the second recording layer L1, and the third recording layer L2 are sufficiently separated. You can see that it is made.
- a stable focus jump is realized by adjusting the spherical aberration in advance according to the recording layer of the movement destination and then performing a focus jump operation. can do.
- the signal 403 indicating the spherical aberration correction amount is in the state L421.
- the interlayer movement procedure determination unit 54 determines the interlayer distance D1 between the first recording layer L0 and the second recording layer L1, and the second recording layer L1 and the third recording layer L2. Switching between the procedures of the focus jump operation and the spherical aberration correction operation is determined based on the interlayer distance D2.
- the interlayer distance between the recording layers is acquired by the interlayer distance information acquisition unit 53.
- the interlayer distance information acquisition unit 53 acquires the interlayer distance based on, for example, the standard value of the optical disk 31 currently loaded.
- the interlayer distance information acquisition unit 53 stores the standard value of the interlayer distance in advance and stores the stored standard value. By reading, the interlayer distance can be acquired.
- the interlayer movement procedure instruction unit 55 at time T13, the spherical surface corresponding to the third recording layer L2 that is the movement destination.
- the spherical aberration correction actuator drive circuit 23 is instructed to correct the spherical aberration according to the aberration correction amount. From timing T13 to timing T14, the spherical aberration correction actuator drive circuit 23 adjusts the spherical aberration correction amount to the optimum state L422 for the third recording layer L2 while operating the focus control.
- the spherical aberration correction unit 7 includes a spherical aberration correction element (for example, a collimator lens) and a stepping motor. Therefore, the spherical aberration correction amount represents the position of the spherical aberration correction element where the spherical aberration is optimal.
- the interlayer movement procedure instruction unit 55 stores each recording layer in advance in association with the position of the spherical aberration correcting element where the spherical aberration is optimal.
- the interlayer movement procedure instructing unit 55 reads the position of the spherical aberration correction element at which the spherical aberration is optimal in the recording layer at the movement destination, and sends it to the spherical aberration correction actuator drive circuit 23 so that the spherical aberration correction element moves to the read position.
- a drive signal is output.
- the interlayer movement procedure instruction unit 55 drives the focus actuator via the control unit 52 so as to move the focal position of the light beam from the second recording layer L1 to the third recording layer L2.
- the circuit 21 is instructed.
- the focus actuator drive circuit 21 performs a focus jump that moves the focal position of the light beam from the second recording layer L1 to the third recording layer L2.
- the microcomputer 51 confirms whether or not the focus control is operating correctly, and completes the interlayer movement operation.
- the focus control is confirmed based on the reproduction signal quality indicator generated by the reproduction signal quality indicator generator 28.
- the spherical aberration correction amount does not necessarily need to be in the optimum state L422 for the third recording layer L2.
- the spherical aberration correction amount may be an intermediate state between the state L421 and the state L422.
- the second recording layer L1 By performing the focus jump operation to the third recording layer L2, a stable focus jump operation from the second recording layer L1 to the third recording layer L2 can be realized.
- FIG. 4 shows the focus error signal 401, the focus actuator drive output 402, and the signal 403 indicating the spherical aberration correction amount during the interlayer movement from the third recording layer L2 to the second recording layer L1 in the first embodiment. It is a figure which shows the change of. In FIG. 4, the description of the same reference numerals as those in FIG. 3 is omitted.
- the signal 403 indicating the spherical aberration correction amount has the initial state L422 where the spherical aberration corresponding to the third recording layer L2 is optimal.
- the interlayer distance D2 between the second recording layer L1 and the third recording layer L2 is 20 ⁇ m
- the third recording layer L2 and the fourth recording layer L2 The interlayer distance D3 between the recording layer L3 is 13 ⁇ m
- the third recording layer L2 has a large interlayer distance with one of the two adjacent recording layers, and the interlayer with the other recording layer. The distance is getting narrower.
- the focus error signal 302 obtained in the second recording layer L1 and the focus error signal 303 obtained in the third recording layer L2 are sufficiently separated, but the third The focus error signal 303 obtained in the recording layer L2 and the focus error signal 304 obtained in the fourth recording layer L3 are not sufficiently separated because the interlayer distance is small. Therefore, when the interlayer distance between the third recording layer L2 and the fourth recording layer L3, which is the recording layer on the side opposite to the movement destination, is smaller than a predetermined distance, the focus jump operation is performed first. A stable focus jump can be realized by adjusting the spherical aberration according to the recording layer of the movement destination.
- the signal 403 indicating the spherical aberration correction amount is in the state L422.
- the interlayer movement procedure determination unit 54 determines switching between the procedures of the focus jump operation and the spherical aberration correction operation based on the interlayer distance D2 and the interlayer distance D3.
- the interlayer movement procedure instruction unit 55 sets the focal point position of the light beam to the third recording layer at timing T23.
- the focus actuator drive circuit 21 is instructed via the controller 52 to move from L2 to the second recording layer L1. From timing T23 to T24, the focus actuator drive circuit 21 performs a focus jump that moves the focal position of the light beam from the third recording layer L2 to the second recording layer L1.
- the microcomputer 51 confirms whether or not the focus control is operating correctly.
- the interlayer movement procedure instruction unit 55 instructs the spherical aberration correction actuator drive circuit 23 to correct the spherical aberration according to the spherical aberration correction amount corresponding to the second recording layer L1 that is the movement destination. To do.
- the spherical aberration correction actuator drive circuit 23 adjusts the spherical aberration correction amount to the optimum state L421 for the second recording layer L1 while operating the focus control.
- the microcomputer 51 confirms whether or not the focus control is operating correctly, and completes the interlayer movement operation.
- step S2 of FIG. 2 when it is determined that the interlayer distance D1 is greater than or equal to the interlayer distance D2, the process proceeds to step S6 and a focus jump operation is performed.
- the present invention is not particularly limited to this, If it is determined that the interlayer distance D1 is greater than or equal to the interlayer distance D2, the process may proceed to step S4 and the spherical aberration may be corrected.
- the interlayer distance D1 and the interlayer distance D2 are compared, and the interlayer distance D1 and the threshold ThD are compared.
- the present invention is not particularly limited to this, and the interlayer distance D1 and The interlayer distance D1 and the threshold value ThD may be compared without comparing the interlayer distance D2.
- the interlayer movement procedure determination unit 54 compares the interlayer distance between the current recording layer and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved, with a predetermined threshold value. If the interlayer distance is larger than the threshold value, the spherical aberration is corrected and then the focal position is moved. If the interlayer distance is less than the threshold value, the focal position is moved and then the spherical aberration is corrected. Do.
- control unit 52 may deactivate tracking control before correcting the spherical aberration. Similar to the focus error signal, the signal amplitude of the tracking error signal varies greatly due to spherical aberration. Therefore, if spherical aberration is corrected while tracking control is being performed, tracking control becomes unstable. After the focus jump operation for moving to another recording layer is completed and it is confirmed that the focus control is correctly performed, the control unit 52 desirably starts the tracking control.
- control unit 52 may change the tracking control gain based on the spherical aberration correction amount.
- the control unit 52 may correct the focus gain before the focus jump based on the interlayer distance and the spherical aberration correction amount before the focus jump. In this case, the focus control before the focus jump can be further stabilized.
- control unit 52 may correct the focus gain after the focus jump based on the interlayer distance and the spherical aberration correction amount before the focus jump. In this case, the focus control after the focus jump can be further stabilized.
- control unit 52 may correct the common focus gain before and after the focus jump. In this case, there is an effect that the gain switching process before and after the focus jump becomes unnecessary.
- the interlayer distance information of each recording layer used here is determined according to the distance from the optical disk surface to each recording layer, which is determined in advance by the standard of the optical disk.
- the interlayer distance information acquisition unit 53 is obtained when the focus actuator 2 is driven in a vertical direction (optical axis direction) with respect to the optical disc 31 at a predetermined speed, and the light beam is incident on the information recording surface of the optical disc 31.
- Interlayer distance information of each recording layer may be acquired based on the detection timing of the focus error signal.
- the interlayer distance information acquisition unit 53 detects the focus error signal generated by the focus error signal generator 25 while driving the objective lens 1 in the optical axis direction at a predetermined speed by the focus actuator driving circuit 21, and focusing Interlayer distance information is acquired based on the detection timing of the error signal.
- the optical disc apparatus further includes a disc discriminating unit that discriminates the type of the optical disc, and the interlayer distance information acquiring unit 53 acquires the inter-layer distance information based on the standard value corresponding to the disc type discriminated by the disc discriminating unit. May be.
- the interlayer distance information acquisition unit 53 stores the type of the optical disc and the interlayer distance information in advance in association with each other, and reads the interlayer distance information corresponding to the type of the optical disc determined by the disc determination unit, Get interlayer distance information.
- the interlayer distance information acquisition unit 53 may acquire interlayer distance information based on the spherical aberration correction amount at the position where the amplitude of the tracking error signal generated in each recording layer of the optical disc is maximized.
- the interlayer distance information acquisition unit 53 acquires interlayer distance information based on the spherical aberration correction amount that provides the best reproduction signal quality index generated by reproducing the recorded area of each recording layer of the optical disc. May be.
- the method for acquiring the interlayer distance information is not limited to the above method, and information corresponding to the interlayer distance of each recording layer may be obtained by some means. There is a possibility that the distance between the recording layers varies due to manufacturing variations of the multilayer optical disk. However, if an optimum spherical aberration correction amount is obtained for each recording layer, a more stable focus jump operation is possible.
- control unit 52 may correct the focus gain according to the change amount of the spherical aberration correction amount when performing the focus jump operation.
- the amplitude of the focus error signal decreases and the focus gain decreases.
- a stable focus jump operation can be realized regardless of the interlayer distance of the recording layer.
- the spherical aberration correction amount in the focus jump is varied according to the distance between the two recording layers adjacent to the current recording layer on which the focus control is performed.
- FIG. 5 is a block diagram showing a configuration of the optical disc apparatus according to Embodiment 2 of the present invention.
- the optical pickup 11 includes an objective lens 1, a focus actuator 2, a tracking actuator 3, a light receiving unit 5, a quarter wavelength plate 6, a spherical aberration correction unit 7, a collimator lens 8, a laser light source 9, and a polarization beam splitter 10.
- the microcomputer 51 includes an interlayer distance information acquisition unit 53 and a focus jump control unit 60.
- the focus jump control unit 60 includes a spherical aberration correction amount calculation unit 56 and an interlayer movement procedure instruction unit 57.
- the spherical aberration correction amount calculation unit 56 calculates the interlayer distance between the current recording layer in which the light beam is focused and the recording layer adjacent in the direction in which the focal position of the light beam is moved, and the current recording layer. And a spherical aberration correction amount for correcting the spherical aberration based on the distance between adjacent recording layers in the direction opposite to the direction in which the focal position of the light beam is moved.
- the interlayer movement procedure instruction unit 57 instructs the spherical aberration correction actuator drive circuit 23 to correct the spherical aberration according to the spherical aberration correction amount calculated by the spherical aberration correction amount calculation unit 56, and the focal position of the light beam Is moved from the current recording layer to the other recording layer, and the spherical aberration correction actuator drive circuit 23 is instructed to correct the spherical aberration in the other recording layer after the movement.
- the spherical aberration correction actuator drive circuit 23 drives the spherical aberration correction unit 7 so as to correct the spherical aberration according to the spherical aberration correction amount calculated by the spherical aberration correction amount calculation unit 56.
- the spherical aberration correction amount calculation unit 56 corresponds to an example of a spherical aberration correction amount calculation unit
- the interlayer movement procedure instruction unit 57 corresponds to an example of an instruction unit.
- FIG. 6 shows a focus error signal 401, a focus actuator drive output 402, and a signal 403 indicating a spherical aberration correction amount during the interlayer movement from the second recording layer L1 to the third recording layer L2 in the second embodiment. It is a figure which shows the change of.
- the signal 403 indicating the spherical aberration correction amount is in the state L421.
- the spherical aberration correction amount calculation unit 56 acquires the spherical aberration correction amount when performing the focus jump by using the second recording layer L1 and the first recording layer acquired by the interlayer distance information acquisition unit 53. The calculation is based on the interlayer distance between the layer L0 and the interlayer distance between the second recording layer L1 and the third recording layer L2.
- the spherical aberration correction amount calculation unit 56 calculates a spherical aberration correction position that represents a position for correcting the spherical aberration, and corrects the spherical aberration so that the spherical aberration is minimized at the calculated spherical aberration correction position. Calculate the amount.
- the spherical aberration correction position calculated by the spherical aberration correction amount calculation unit 56 represents how many ⁇ m away from the surface of the optical disc 31 the spherical aberration correction amount is adjusted during the focus jump.
- the interlayer distance from the surface to the third recording layer L2 is SAtgt
- the interlayer distance from the second recording layer L1 to the third recording layer L2 is ⁇ SA1
- the second recording layer L1 to the first recording layer L1 is SAtgt
- the spherical aberration correction amount calculation unit 56 sets the spherical aberration correction position SAtgt2 at the time of focus jump to the following equation (1). Calculate using.
- SAtgt2 SAtgt + ( ⁇ SA1 / ⁇ SA2) ⁇ K (1)
- the spherical aberration correction position SAtgt2 is calculated by the following equation (2). Is done.
- a state L424 represents a state in which the spherical aberration correction amount is optimally adjusted at the spherical aberration correction position of 74.8 ⁇ m from the surface.
- the interlayer movement procedure instruction unit 57 instructs the spherical aberration correction actuator drive circuit 23 to correct the spherical aberration according to the spherical aberration correction amount calculated by the spherical aberration correction amount calculation unit 56. .
- the spherical aberration correction actuator drive circuit 23 adjusts the spherical aberration correction amount to the state L424 while operating the focus control.
- the spherical aberration correction unit 7 includes a spherical aberration correction element (for example, a collimator lens) and a stepping motor. Therefore, the spherical aberration correction amount represents the position of the spherical aberration correction element where the spherical aberration is optimal.
- the spherical aberration correction amount calculation unit 56 stores in advance the distance from the surface of the optical disc and the position of the spherical aberration correction element that optimizes the spherical aberration in association with each other.
- the spherical aberration correction amount calculation unit 56 reads the distance from the surface of the optical disk, that is, the position of the spherical aberration correction element at which the spherical aberration is optimal at the calculated spherical aberration correction position, and the spherical aberration correction element moves to the read position. Thus, a drive signal is output to the spherical aberration correction actuator drive circuit 23.
- the interlayer movement procedure instruction unit 57 drives the focus actuator via the control unit 52 so as to move the focal position of the light beam from the second recording layer L1 to the third recording layer L2.
- the circuit 21 is instructed.
- the focus actuator drive circuit 21 performs a focus jump that moves the focal position of the light beam from the second recording layer L1 to the third recording layer L2.
- the microcomputer 51 confirms whether or not the focus control is operating correctly.
- the interlayer movement procedure instruction unit 57 instructs the spherical aberration correction actuator drive circuit 23 to correct the spherical aberration in the third recording layer L2 after the movement.
- the spherical aberration correction actuator drive circuit 23 again adjusts the spherical aberration correction amount from the state L424 to the state L422 while operating the focus control.
- the microcomputer 51 confirms whether or not the focus control is operating correctly, and completes the interlayer movement operation.
- FIG. 7 shows a focus error signal 401, a focus actuator drive output 402, and a signal 403 indicating a spherical aberration correction amount when the interlayer is moved from the third recording layer L2 to the second recording layer L1 in the second embodiment. It is a figure which shows the change of.
- the signal 403 indicating the spherical aberration correction amount is in the state L422.
- the spherical aberration correction amount calculation unit 56 acquires the spherical aberration correction amount when performing the focus jump by using the third recording layer L ⁇ b> 2 and the second recording layer acquired by the interlayer distance information acquisition unit 53. Calculation is made based on the interlayer distance between the layer L1 and the interlayer distance between the third recording layer L2 and the fourth recording layer L3.
- the spherical aberration correction amount calculator 56 calculates a spherical aberration correction position for correcting the spherical aberration, and corrects the spherical aberration so as to minimize the spherical aberration at the calculated spherical aberration correction position. Is calculated.
- the interlayer distance from the surface to the second recording layer L1 is SAtgt
- the interlayer distance from the third recording layer L2 to the second recording layer L1 is ⁇ SA1
- the third recording layer L2 to the fourth recording layer L4 is K
- the spherical aberration correction amount calculation unit 56 sets the spherical aberration correction position SAtgt2 at the time of focus jump to the following equation (3). Calculate using.
- SAtgt2 SAtgt ⁇ ( ⁇ SA1 / ⁇ SA2) ⁇ K (3)
- the spherical aberration correction position SAtgt2 is calculated by the following equation (4). Is done.
- a state L425 represents a state in which the spherical aberration correction amount is optimally adjusted at the spherical aberration correction position 67.6 ⁇ m from the surface.
- the interlayer movement procedure instruction unit 57 instructs the spherical aberration correction actuator drive circuit 23 to correct the spherical aberration according to the spherical aberration correction amount calculated by the spherical aberration correction amount calculation unit 56. .
- the spherical aberration correction actuator drive circuit 23 adjusts the spherical aberration correction amount to the state L425 while operating the focus control.
- the interlayer movement procedure instruction unit 57 drives the focus actuator via the control unit 52 so as to move the focal position of the light beam from the third recording layer L2 to the second recording layer L1.
- the circuit 21 is instructed.
- the focus actuator drive circuit 21 performs a focus jump that moves the focal position of the light beam from the third recording layer L2 to the second recording layer L1.
- the microcomputer 51 confirms whether or not the focus control is operating correctly.
- the interlayer movement procedure instruction unit 57 instructs the spherical aberration correction actuator drive circuit 23 to correct the spherical aberration in the second recording layer L1 after the movement.
- the spherical aberration correction actuator drive circuit 23 adjusts the spherical aberration correction amount again from the state L425 to the state L421 while operating the focus control.
- the microcomputer 51 confirms whether or not the focus control is operating correctly, and completes the interlayer movement operation.
- the adjacent recording layer includes the surface of the optical disc.
- the spherical aberration correction amount calculation unit 56 calculates the spherical aberration correction position SAtgt2 at the time of focus jump using the following equation (5). .
- SAtgt2 SAtgt ⁇ ( ⁇ SA1 / ⁇ SA2) ⁇ K (5)
- the threshold of the interlayer distance ignoring the influence from other recording layers is 30 ⁇ m
- the interlayer distance ⁇ SA2 from the fourth recording layer L3 to the surface exceeds this threshold. That the interlayer distance ⁇ SA2 is sufficiently large and the influence of the adjacent recording layer on the focus error signal can be ignored is equivalent to the fact that ⁇ SA2 can be treated as infinite.
- the spherical aberration correction position SAtgt2 is It is calculated by the following equation (6).
- the spherical aberration correction amount is 63 ⁇ m from the surface, that is, the spherical aberration is corrected at the third recording layer L2.
- the focus jump may be executed with the amount adjusted to be optimum.
- the method of determining the spherical aberration correction amount is not limited to the determination method shown in the second embodiment, and may be changed according to the characteristics of the optical pickup.
- the spherical aberration correction amount calculation unit 56 prepares a table representing the spherical aberration correction amount corresponding to the interlayer distance of each recording layer in advance, and determines the spherical aberration correction amount by referring to the table. Also good. The spherical aberration correction amount calculation unit 56 only needs to be able to appropriately determine the spherical aberration correction amount according to the interlayer distance between the recording layers of the multilayer optical disc.
- the movement to the recording layer adjacent to the current recording layer in the multilayer optical disc has been described so far.
- the first embodiment and the embodiment are also described.
- Form 2 is applicable.
- the focus jump control unit 60 is adjacent when moving the in-focus position from the current recording layer in which the light beam is focused to another recording layer that is m (m is an integer of 2 or more) layers away.
- the spherical aberration correction by the spherical aberration correction actuator drive circuit 23 and the movement of the focus position by the focus actuator drive circuit 21 are controlled so that the operation of moving the focus position to the recording layer is repeated m times.
- the spherical aberration correction operation and the focus jump operation are individually operated.
- the spherical aberration correction operation is continued without interrupting the spherical aberration correction operation.
- the focus jump operation is performed as it is.
- FIG. 8 is a block diagram showing a configuration of the optical disc apparatus according to Embodiment 3 of the present invention.
- the optical pickup 11 includes an objective lens 1, a focus actuator 2, a tracking actuator 3, a light receiving unit 5, a quarter wavelength plate 6, a spherical aberration correction unit 7, a collimator lens 8, a laser light source 9, and a polarization beam splitter 10.
- the microcomputer 51 includes an interlayer distance information acquisition unit 53, a spherical aberration correction amount monitoring unit 58, and a focus jump control unit 60.
- the focus jump control unit 60 includes a spherical aberration correction amount calculation unit 56 and an interlayer movement procedure instruction unit 57.
- the spherical aberration correction amount monitoring unit 58 monitors the spherical aberration correction amount by the spherical aberration correction unit 7.
- the spherical aberration correction unit 7 moves a spherical aberration correction element (for example, a collimator lens) with a stepping motor.
- the spherical aberration correction amount detects the position of the spherical aberration correction element on the optical path through which the light beam in the optical pickup passes, that is, the position of the spherical aberration correction element driven by the stepping motor. Can be obtained.
- the spherical aberration correction amount monitoring unit 58 can simultaneously monitor the spherical aberration correction amount at any time while performing the spherical aberration correction operation by the stepping motor. Therefore, the spherical aberration correction amount monitoring unit 58 monitors the position of the spherical aberration correction element of the spherical aberration correction unit 7. In the third embodiment as well, the spherical aberration correction amount represents the position of the spherical aberration correction element where the spherical aberration is optimal.
- the spherical aberration correction amount calculation unit 56 is based on the interlayer distance between the current recording layer in which the light beam is focused and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved. Thus, a spherical aberration correction amount for correcting the spherical aberration is calculated. In addition, when the spherical aberration correction amount calculation unit 56 moves the focal point position to another recording layer that is two or more layers away from the current recording layer, each spherical aberration when moving the focal point position to an adjacent recording layer A correction amount is calculated.
- the spherical aberration correction amount calculation unit 56 moves the focal position to another recording layer that is two or more layers away from the current recording layer, the current recording layer in which the light beam is focused, and the light beam The distance between the recording layers adjacent to each other in the direction in which the in-focus position is moved, and the distance between the current recording layer and the recording layer adjacent in the direction opposite to the direction in which the in-focus position of the light beam is moved. Based on the interlayer distance, each spherical aberration correction amount when moving the focal position to the adjacent recording layer is calculated.
- the interlayer movement procedure instruction unit 57 starts correcting spherical aberration so that the spherical aberration is optimized in the other recording layer of the movement destination, and corrects spherical aberration until the spherical aberration is optimized in the other recording layer.
- the spherical aberration correction amount of the spherical aberration correction unit 7 monitored by the amount monitoring unit 58 reaches the spherical aberration correction amount calculated by the spherical aberration correction amount calculation unit 56, the focal point position is moved to the adjacent recording layer. Instruct the focus actuator drive circuit 21 as follows.
- the spherical aberration correction amount calculation unit 56 corresponds to an example of a spherical aberration correction amount calculation unit
- the interlayer movement procedure instruction unit 57 corresponds to an example of an instruction unit
- a spherical aberration correction amount monitoring unit. 58 corresponds to an example of a monitoring unit.
- FIG. 9 shows a focus error signal 401, a focus actuator drive output 402, and a signal 403 indicating a spherical aberration correction amount when moving the layer from the third recording layer L2 to the second recording layer L1 in the third embodiment. It is a figure which shows the change of.
- the signal 403 indicating the spherical aberration correction amount is in the state L422.
- the spherical aberration correction amount calculation unit 56 acquires the spherical aberration correction amount when performing the focus jump by using the third recording layer L2 and the second recording layer acquired by the interlayer distance information acquisition unit 53. Calculation is made based on the interlayer distance between the layer L1 and the interlayer distance between the third recording layer L2 and the fourth recording layer L3.
- the spherical aberration correction amount calculator 56 calculates a spherical aberration correction position for correcting the spherical aberration, and corrects the spherical aberration so as to minimize the spherical aberration at the calculated spherical aberration correction position. Is calculated.
- the focus jump is executed in a state where the spherical aberration amount is adjusted to be optimal at the spherical aberration correction position of 69 ⁇ m from the surface.
- the calculation formula of the spherical aberration correction position in the third embodiment is the same as that described in the second embodiment, a description thereof will be omitted.
- the interlayer movement procedure instruction unit 57 instructs the spherical aberration correction actuator drive circuit 23 to correct the spherical aberration according to the spherical aberration correction amount corresponding to the second recording layer L1 that is the movement destination.
- the spherical aberration correction actuator drive circuit 23 starts the spherical aberration correction operation so that the spherical aberration correction amount becomes the state L421 while operating the focus control.
- the interlayer movement procedure instruction unit 57 detects that the signal 403 indicating the spherical aberration correction amount has reached the state L425, performs the focus jump operation while continuing the spherical aberration correction operation, and performs the light beam operation. Are moved from the third recording layer L2 to the second recording layer L1.
- the interlayer movement procedure instructing unit 57 determines that the spherical aberration correction amount of the spherical aberration correction unit 7 monitored by the spherical aberration correction amount monitoring unit 58 is spherical until the spherical aberration is optimized for the second recording layer L1. It is determined whether or not the spherical aberration correction amount (spherical aberration correction amount corresponding to the spherical aberration correction position SAtgt2) calculated by the aberration correction amount calculation unit 56 has been reached.
- the interlayer movement procedure instruction unit 57 sets the adjacent second recording layer L1.
- the focus actuator drive circuit 21 is instructed to move the in-focus position.
- the interlayer movement procedure instructing unit 57 determines the spherical aberration of the spherical aberration correction unit 7 monitored by the spherical aberration correction amount monitoring unit 58 until the spherical aberration is optimized for the second recording layer L1. It is determined whether or not the position of the correction element has reached the position of the spherical aberration correction element calculated by the spherical aberration correction amount calculation unit 56 (the position of the spherical aberration correction element corresponding to the spherical aberration correction position SAtgt2).
- the interlayer movement procedure instruction unit 57 sets the second The focus actuator drive circuit 21 is instructed to move the in-focus position to the recording layer L1.
- the microcomputer 51 confirms whether or not the focus control is operating correctly.
- the spherical aberration correction amount reaches the state L421 at timing T56, the spherical aberration correction actuator drive circuit 23 completes the spherical aberration correction operation.
- the microcomputer 51 confirms whether or not the focus control is operating correctly, and completes the interlayer movement operation.
- a method for monitoring the spherical aberration correction amount in the spherical aberration correction amount monitoring unit 58 a method for monitoring the driving amount of the stepping motor as needed is given, but the present invention is not particularly limited to this.
- a sensor for detecting a spherical aberration correction amount position of the spherical aberration correction element
- the spherical aberration correction amount monitoring unit 58 may detect the amount of spherical aberration by calculating a signal obtained from the light receiving unit 5.
- the focus jump procedure in the third embodiment it is not necessary to temporarily interrupt the spherical aberration correction operation for the focus jump operation, so that higher-speed interlayer movement can be realized.
- the interlayer movement from the current recording layer to another recording layer adjacent to the current recording layer is described.
- a procedure for continuously moving a plurality of recording layers at high speed and stably in the interlayer movement from the current recording layer to a recording layer two or more layers away will be described.
- the focus jump procedure from the fourth recording layer L3 to the first recording layer L0 will be described with reference to FIG.
- FIG. 10 shows a focus error signal 401, a focus actuator drive output 402, and a signal 403 indicating a spherical aberration correction amount when moving the layer from the fourth recording layer L3 to the first recording layer L0 in the fourth embodiment. It is a figure which shows the change of.
- the signal 403 indicating the spherical aberration correction amount is in the state L423.
- the spherical aberration correction amount calculation unit 56 calculates the spherical aberration correction amount when performing the focus jump based on the interlayer distance of each recording layer.
- the spherical aberration correction amount calculator 56 calculates a spherical aberration correction position for correcting the spherical aberration, and corrects the spherical aberration so as to minimize the spherical aberration at the calculated spherical aberration correction position. Is calculated.
- the spherical aberration correction amount represents the position of the spherical aberration correction element at which the spherical aberration is optimal.
- the spherical aberration correction amount calculation unit 56 corrects spherical aberration for each recording layer existing between the current recording layer and the recording layer to which it is moved. A position is calculated, and a spherical aberration correction amount corresponding to the spherical aberration correction position is calculated.
- the spherical aberration correction amount calculator 56 calculates the spherical aberration correction position SAtgt2 in the focus jump operation from the fourth recording layer L3 to the third recording layer L2 using the following equation (7).
- the interlayer distance from the surface to the third recording layer L2 is SAtgt
- the interlayer distance from the fourth recording layer L3 to the third recording layer L2 is ⁇ SA1
- the interlayer distance correction coefficient is K.
- SAtgt2 SAtgt ⁇ ( ⁇ SA1 / ⁇ SA2) ⁇ K (7)
- the spherical aberration correction position SAtgt2 is expressed by the following (8). Calculated by the formula.
- the spherical aberration correction amount calculation unit 56 calculates the spherical aberration correction position SAtgt3 in the focus jump operation from the third recording layer L2 to the second recording layer L1 using the following equation (9).
- the interlayer distance from the surface to the second recording layer L1 is SAtgt
- the interlayer distance from the third recording layer L2 to the second recording layer L1 is ⁇ SA1
- from the third recording layer L2 The interlayer distance to the fourth recording layer L3 is ⁇ SA2
- the interlayer distance correction coefficient is K.
- SAtgt3 SAtgt ⁇ ( ⁇ SA1 / ⁇ SA2) ⁇ K (9)
- the spherical aberration correction position SAtgt3 is expressed by the following (10). Calculated by the formula.
- the spherical aberration correction amount calculation unit 56 calculates the spherical aberration correction position SAtgt4 in the focus jump operation from the second recording layer L1 to the first recording layer L0 using the following equation (11).
- the interlayer distance from the surface to the first recording layer L0 is SAtgt
- the interlayer distance from the second recording layer L1 to the first recording layer L0 is ⁇ SA1
- from the second recording layer L1 is ⁇ SA2
- the interlayer distance to the third recording layer L2 is ⁇ SA2
- the interlayer distance correction coefficient is K.
- SAtgt4 SAtgt ⁇ ( ⁇ SA1 / ⁇ SA2) ⁇ K (11)
- the spherical aberration correction position SAtgt4 is expressed by the following (12). Calculated by the formula.
- the spherical aberration correction actuator drive circuit 23 optimizes the spherical aberration correction amount to the spherical aberration correction position 60.4 ⁇ m from the surface in the focus jump from the fourth recording layer L3 to the third recording layer L2. To the correct state L426. Further, the spherical aberration correction actuator drive circuit 23 is in a state in which the spherical aberration correction amount is optimally set at the spherical aberration correction position of 67.6 ⁇ m from the surface in the focus jump from the third recording layer L2 to the second recording layer L1. Adjust to L427.
- the spherical aberration correction actuator drive circuit 23 is in a state in which the spherical aberration correction amount is optimally set at the spherical aberration correction position of 91.5 ⁇ m from the surface in the focus jump from the second recording layer L1 to the first recording layer L0. Adjust to L428.
- the interlayer movement procedure instruction unit 57 instructs the spherical aberration correction actuator drive circuit 23 to correct the spherical aberration according to the spherical aberration correction amount corresponding to the first recording layer L0 that is the movement destination. To do.
- the spherical aberration correction actuator drive circuit 23 starts the spherical aberration correction operation so that the spherical aberration correction amount becomes the state L420 while operating the focus control.
- the interlayer movement procedure instruction unit 57 detects that the signal 403 indicating the spherical aberration correction amount has reached the state L426, performs the focus jump operation while continuing the spherical aberration correction operation, and performs the light beam operation. Are moved from the fourth recording layer L3 to the third recording layer L2.
- the interlayer movement procedure instructing unit 57 determines that the spherical aberration correction amount of the spherical aberration correction unit 7 monitored by the spherical aberration correction amount monitoring unit 58 is spherical until the spherical aberration becomes optimal for the first recording layer L0. It is determined whether or not the spherical aberration correction amount (spherical aberration correction amount corresponding to the spherical aberration correction position SAtgt2) calculated by the aberration correction amount calculation unit 56 has been reached.
- the interlayer movement procedure instruction unit 57 sets the adjacent third recording layer L2.
- the focus actuator drive circuit 21 is instructed to move the in-focus position.
- the microcomputer 51 confirms whether the focus control is operating correctly.
- the interlayer movement procedure instruction unit 57 detects that the signal 403 indicating the spherical aberration correction amount has reached the state L427, performs the focus jump operation while continuing the spherical aberration correction operation, and performs the light beam operation. Are moved from the third recording layer L2 to the second recording layer L1.
- the interlayer movement procedure instructing unit 57 determines that the spherical aberration correction amount of the spherical aberration correction unit 7 monitored by the spherical aberration correction amount monitoring unit 58 is spherical until the spherical aberration becomes optimal for the first recording layer L0. It is determined whether or not the spherical aberration correction amount (spherical aberration correction amount corresponding to the spherical aberration correction position SAtgt3) calculated by the aberration correction amount calculation unit 56 has been reached.
- the interlayer movement procedure instruction unit 57 sets the adjacent second recording layer L1.
- the focus actuator drive circuit 21 is instructed to move the in-focus position.
- the microcomputer 51 confirms whether the focus control is operating correctly.
- the interlayer movement procedure instruction unit 57 detects that the signal 403 indicating the spherical aberration correction amount has reached the state L428, performs the focus jump operation while continuing the spherical aberration correction operation, and performs the light beam operation. Are moved from the second recording layer L1 to the first recording layer L0.
- the interlayer movement procedure instructing unit 57 determines that the spherical aberration correction amount of the spherical aberration correction unit 7 monitored by the spherical aberration correction amount monitoring unit 58 is spherical until the spherical aberration becomes optimal for the first recording layer L0. It is determined whether or not the spherical aberration correction amount (spherical aberration correction amount corresponding to the spherical aberration correction position SAtgt4) calculated by the aberration correction amount calculation unit 56 has been reached.
- the interlayer movement procedure instruction unit 57 sets the adjacent first recording layer L0.
- the focus actuator drive circuit 21 is instructed to move the in-focus position.
- the microcomputer 51 confirms whether the focus control is operating correctly.
- the spherical aberration correction actuator drive circuit 23 completes the spherical aberration correction operation, and the focus actuator drive circuit 21 completes the interlayer movement operation.
- An optical disc apparatus is an optical disc apparatus that reads information recorded on the optical disc or records information on the optical disc by irradiating an optical disc having a plurality of recording layers with a light beam.
- a spherical aberration correction unit that corrects a spherical aberration generated in a light spot on the recording layer, a focus control unit that focuses the light beam on a predetermined recording layer, and a current recording position of the focal point of the light beam
- the focus jump for controlling the spherical aberration correction by the spherical aberration correction unit and the movement of the in-focus position by the focus jump unit And a control unit.
- the light spot on the recording layer is generated based on the interlayer distance between the current recording layer and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved. Correction of spherical aberration and movement of the focal position of the light beam are controlled.
- the correction of spherical aberration and the movement of the in-focus position are based on the interlayer distance between the current recording layer and the adjacent recording layer in the direction opposite to the direction in which the in-focus position of the light beam is moved. Therefore, the influence of the adjacent recording layer on the focus error signal can be taken into consideration, and the focus jump can be performed stably.
- the focus jump control unit is based on an interlayer distance between the current recording layer and a recording layer adjacent in a direction opposite to a direction in which the focal position of the light beam is moved. It is preferable to determine which of the spherical aberration correction by the spherical aberration correction unit and the movement of the in-focus position by the focus jump unit is performed first.
- the spherical aberration is corrected based on the interlayer distance between the current recording layer and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved. It is determined which of the movements is to be performed first.
- the focal position is moved after correcting the spherical aberration, and when the adjacent recording layer does not affect the focus error signal, the focal position After moving the lens, the spherical aberration can be corrected and the focus jump can be performed stably.
- the focus jump control unit may determine a predetermined distance between an interlayer distance between the current recording layer and a recording layer adjacent in a direction opposite to a direction in which the focal position of the light beam is moved.
- the focal point is moved after correcting the spherical aberration.
- the focal point is moved. After performing this, it is preferable to correct spherical aberration.
- the interlayer distance between the current recording layer and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved is compared with a predetermined threshold value.
- the focal point is moved after the spherical aberration is corrected.
- the spherical aberration is corrected after the in-focus position is moved.
- the focal position is moved after correcting the spherical aberration, and when the adjacent recording layer does not affect the focus error signal, the focal position After moving the lens, the spherical aberration can be corrected and the focus jump can be performed stably.
- the focus jump control unit is based on an interlayer distance between the current recording layer and a recording layer existing within a predetermined distance range from the current recording layer. It is preferable to control the correction of spherical aberration by the spherical aberration correction unit and the movement of the in-focus position by the focus jump unit.
- the spherical aberration is corrected and the in-focus position is moved based on the interlayer distance between the current recording layer and the recording layer existing within a predetermined distance range from the current recording layer. Since this is controlled, the focus jump can be performed more stably.
- the focus jump control unit includes an interlayer distance between the current recording layer and an adjacent recording layer in a direction in which a focal position of the light beam is moved, and the current recording layer.
- a spherical aberration correction amount for correcting the spherical aberration is calculated based on an interlayer distance between the recording layer adjacent to the layer and a direction opposite to the direction in which the focal position of the light beam is moved;
- the spherical aberration correction unit corrects the spherical aberration according to the calculated spherical aberration correction amount.
- the distance between the current recording layer and the adjacent recording layer in the direction in which the focal position of the light beam is moved, and the current recording layer and the focal position of the light beam are moved.
- a spherical aberration correction amount for correcting spherical aberration is calculated based on the interlayer distance between recording layers adjacent to each other in the direction opposite to the direction. Then, the spherical aberration is corrected according to the calculated spherical aberration correction amount.
- the distance between the current recording layer and the adjacent recording layer in the direction in which the focal position of the light beam is moved is opposite to the direction in which the current recording layer and the focal position of the light beam are moved. Since the spherical aberration correction amount for correcting the spherical aberration is calculated based on the interlayer distance between the recording layers adjacent to each other in the direction, the spherical aberration can be corrected accurately.
- the focus jump control unit calculates a spherical aberration correction position representing a position for correcting the spherical aberration based on the following expression (13), and the spherical surface is corrected at the calculated spherical aberration correction position. It is preferable to calculate a spherical aberration correction amount for correcting the aberration.
- SAtgt2 SAtgt + ( ⁇ SA1 / ⁇ SA2) ⁇ K (13)
- SAtgt2 represents the spherical aberration correction position
- SAtgt represents the distance from the surface of the optical disc to the adjacent recording layer in the direction of moving the focal position of the light beam
- ⁇ SA1 represents the current This represents the distance between the recording layer and the recording layer adjacent in the direction in which the focal position of the light beam is moved
- ⁇ SA2 is the direction in which the current recording layer and the focal position of the light beam are moved.
- K represents a correction coefficient.
- the spherical aberration correction position representing the position for correcting the spherical aberration is calculated based on the above equation (13), and the spherical aberration correction amount for correcting the spherical aberration at the calculated spherical aberration correction position. Therefore, spherical aberration can be corrected more accurately.
- the focus jump control unit instructs the spherical aberration correction unit to correct the spherical aberration in accordance with the calculated spherical aberration correction amount, and the focal position of the light beam It is preferable to instruct the focus jump unit to move from the current recording layer to another recording layer, and to instruct the spherical aberration correction unit to correct spherical aberration in the other recording layer after the movement. .
- the spherical aberration is corrected according to the calculated spherical aberration correction amount, and then the focal position of the light beam is moved from the current recording layer to another recording layer, and then the other after the movement Spherical aberration in the recording layer is corrected.
- the focus jump can be performed more stably by correcting the spherical aberration step by step.
- the focus jump control unit may perform adjacent recording when moving the in-focus position to another recording layer that is m layers away from the current recording layer in which the light beam is focused. It is preferable to control the spherical aberration correction by the spherical aberration correction unit and the movement of the focal point position by the focus jump unit so that the operation of moving the focal point position to the layer is repeated m times.
- the focus jump control unit is based on an interlayer distance between the current recording layer and a recording layer adjacent in a direction opposite to a direction in which the focal position of the light beam is moved.
- a spherical aberration correction amount calculating unit for calculating a spherical aberration correction amount for correcting the spherical aberration, and starting correction of the spherical aberration so that the spherical aberration is optimized in the other recording layer, When the spherical aberration correction amount calculated by the spherical aberration correction amount calculation unit is reached until the spherical aberration is optimized for the other recording layer, the focal point position is moved to the adjacent recording layer. It is preferable that an instruction unit for instructing the focus jump unit is included.
- a correction amount is calculated. Then, when correction of the spherical aberration is started so that the spherical aberration is optimized in the other recording layer, and the calculated spherical aberration correction amount is reached until the spherical aberration is optimized for the other recording layer, The in-focus position is moved to the adjacent recording layer.
- the focal point position can be moved while correcting the spherical aberration, and the interlayer access time can be shortened.
- the spherical aberration correction amount calculating unit moves the focal position to another recording layer that is two or more layers away from the current recording layer, the current recording layer and the light
- An interlayer distance between recording layers adjacent to each other in the direction in which the focal position of the beam is moved, the current recording layer, and a recording layer adjacent in a direction opposite to the direction in which the focal position of the light beam is moved It is preferable to calculate each spherical aberration correction amount when moving the in-focus position to the adjacent recording layer based on the interlayer distance between the two.
- the recording layer adjacent to the current recording layer and the direction in which the focal position of the light beam is moved To the adjacent recording layer based on the distance between the current recording layer and the distance between the current recording layer and the adjacent recording layer in the direction opposite to the direction in which the focal position of the light beam is moved.
- Each spherical aberration correction amount when moving the focal position is calculated.
- the in-focus position can be moved while correcting spherical aberration, and the access time between layers is shortened. can do.
- the optical disc apparatus may further include an interlayer distance acquisition unit that acquires an interlayer distance between the recording layers of the optical disc, and the interlayer distance acquisition unit acquires the interlayer distance based on a standard value of the optical disc. Is preferred. According to this configuration, the interlayer distance can be acquired based on the standard value of the optical disc.
- the optical disc apparatus may further include an interlayer distance acquisition unit that acquires an interlayer distance of each recording layer of the optical disc, wherein the interlayer distance acquisition unit is configured to determine the interlayer distance based on a standard value corresponding to the type of the optical disc. It is preferable to obtain According to this configuration, the interlayer distance can be acquired based on the standard value corresponding to the type of the optical disc.
- an interlayer distance acquisition unit that acquires an interlayer distance of each recording layer of the optical disc, an objective lens that focuses the light beam on the recording layer, and the light beam on a predetermined recording layer
- a drive unit that drives the objective lens in the optical axis direction
- a focus error signal generation that generates a relative distance between the focused position of the light beam and the recording layer of the optical disc as a focus error signal
- the interlayer distance acquisition unit detects the focus error signal generated by the focus error signal generation unit while driving the objective lens in the optical axis direction at a predetermined speed by the driving unit.
- the interlayer distance is acquired based on the detection timing of the focus error signal.
- the generated focus error signal is detected while driving the objective lens in the optical axis direction at a predetermined speed, and the interlayer distance is acquired based on the detection timing of the focus error signal. Therefore, the interlayer distance can be accurately obtained for each optical disc.
- the relative distance between the inter-layer distance acquisition unit for acquiring the inter-layer distance of each recording layer of the optical disc and the focal position of the light beam and the track formed on the optical disc is tracked.
- a tracking error signal generation unit that generates an error signal, and the interlayer distance acquisition unit corrects the spherical aberration at a position where the amplitude of the tracking error signal generated in each recording layer of the optical disc is maximum. It is preferable to obtain the interlayer distance based on
- the interlayer distance is acquired based on the spherical aberration correction amount at the position where the amplitude of the tracking error signal generated in each recording layer of the optical disc is maximum. Therefore, the interlayer distance can be accurately obtained for each optical disc.
- an interlayer distance acquisition unit that acquires an interlayer distance of each recording layer of the optical disk, and a reproduction that reproduces information recorded on each recording layer of the optical disk to generate a reproduction signal quality index
- the interlayer distance acquisition unit corrects the spherical aberration so that the reproduction signal quality index generated by reproducing the recorded area of each recording layer of the optical disc is the best It is preferable to obtain the interlayer distance based on
- the interlayer distance is acquired based on the spherical aberration correction amount that provides the best reproduction signal quality index generated by reproducing the recorded area of each recording layer of the optical disc. Therefore, the interlayer distance can be accurately obtained for each optical disc.
- a focus control method is a focus control method for moving a focal position of a light beam irradiated on an optical disc having a plurality of recording layers from the current recording layer to another recording layer.
- the light spot on the recording layer is generated based on the interlayer distance between the current recording layer and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved. Correction of spherical aberration and movement of the focal position of the light beam are controlled.
- the correction of spherical aberration and the movement of the in-focus position are based on the interlayer distance between the current recording layer and the adjacent recording layer in the direction opposite to the direction in which the in-focus position of the light beam is moved. Therefore, the influence of the adjacent recording layer on the focus error signal can be taken into consideration, and the focus jump can be performed stably.
- An integrated circuit is an integrated circuit for moving the focal position of a light beam irradiated to an optical disc having a plurality of recording layers from the current recording layer to another recording layer,
- a focus control circuit that focuses a light beam on a predetermined recording layer of the optical disc, the current recording layer, and a recording layer adjacent in a direction opposite to the direction in which the focal position of the light beam is moved.
- a focus jump control circuit that controls correction of spherical aberration generated in a light spot on the recording layer and movement of a focal position of the light beam based on an interlayer distance;
- the light spot on the recording layer is generated based on the interlayer distance between the current recording layer and the recording layer adjacent in the direction opposite to the direction in which the focal position of the light beam is moved. Correction of spherical aberration and movement of the focal position of the light beam are controlled.
- the correction of spherical aberration and the movement of the in-focus position are based on the interlayer distance between the current recording layer and the adjacent recording layer in the direction opposite to the direction in which the in-focus position of the light beam is moved. Therefore, the influence of the adjacent recording layer on the focus error signal can be taken into consideration, and the focus jump can be performed stably.
- a more stable focus jump can be performed by changing the drive waveform output from the focus actuator drive circuit 21 in accordance with the interlayer distance for performing the focus jump.
- This can be realized, for example, by the focus actuator drive circuit 21 appropriately correcting the output level or output time of the drive waveform in accordance with the size of the interlayer distance.
- the optimum light beam output may differ depending on the recording layer.
- a high frequency component may be superimposed when a light beam is output by a laser light source in order to improve signal characteristics obtained by reflection from the multilayer optical disk.
- the control unit sets the output of the light beam according to the recording layer with the lower optimal light beam output of the current recording layer and the destination recording layer. Therefore, it is possible to prevent the information of the recording layer from deteriorating in the multilayer optical disc in which the optimum light beam output is different for each recording layer.
- the focus jump is performed with the high frequency component superimposed. If this is performed, there is a possibility that the information of the recording layer at the movement destination is deteriorated or the information of the recording layer at the movement destination is erased by mistake.
- the control unit stops superimposing the high-frequency component on the light beam before the focus jump operation.
- information in the recording layer deteriorates in a multilayer optical disc in which a recording layer in which information is reproduced by a light beam on which a high frequency component is superimposed and a recording layer in which information is reproduced by a light beam on which no high frequency component is superimposed are mixed. Can be prevented.
- the control unit can prevent the information of the recording layer from deteriorating by setting the output of the light beam to an optimum value for the recording layer to be moved in accordance with the correction amount of the spherical aberration after the focus jump is completed.
- control unit may perform the focus jump after setting the output of the light beam according to the recording layer having the lowest output of the optimum light beam among the plurality of recording layers of the multilayer optical disc.
- the control unit performs the focus jump after setting the amplitude of the high frequency component to be superimposed on the light beam according to the recording layer having the lowest output of the optimum light beam among the plurality of recording layers of the multilayer optical disc.
- the focus jump may be performed after the superposition of the high frequency component is stopped.
- control unit may confirm that the focus jump to the desired recording layer has been made by measuring the amplitude of the tracking error signal and comparing it with a predetermined threshold after the focus jump is completed. Further, the control unit may confirm that the focus jump to the desired recording layer can be performed by reading the address of the recording layer after the movement after the focus jump is completed. Thereafter, the control unit sets an optimum light beam output for the current recording layer. Alternatively, if the current recording layer is a recording layer to be reproduced by superimposing a high frequency component on the light beam, the control unit superimposes the high frequency component on the light beam. As a result, it is possible to achieve both the reliability of the multilayer optical disc and the fast and stable access operation.
- the optical disc device, the focus control method, and the integrated circuit according to the present invention can realize a stable and high-speed focus jump operation even in a multilayer optical disc having a plurality of recording layers, and can realize a large capacity and a high recording density.
- the present invention is useful as an optical disc apparatus, a focus control method, and an integrated circuit for reading information recorded on an optical disc or recording information on the optical disc.
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Abstract
Description
図1は、本発明の実施の形態1における光ディスク装置の構成を示すブロック図である。
次に、本発明の実施の形態2における光ディスク装置について説明する。
次に、本発明の実施の形態3における光ディスク装置について説明する。
次に、本発明の実施の形態4における光ディスク装置について説明する。
Claims (17)
- 複数の記録層を有する光ディスクに対して光ビームを照射することにより、前記光ディスクに記録されている情報を読み出す又は前記光ディスクに情報を記録する光ディスク装置において、
前記記録層上の光スポットにおいて発生する球面収差を補正する球面収差補正部と、
所定の記録層に前記光ビームを合焦させるフォーカス制御部と、
前記光ビームの合焦点位置を現在の記録層から他の記録層に移動させるフォーカスジャンプ部と、
前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向とは反対方向に隣接する記録層との間の層間距離に基づいて、前記球面収差補正部による球面収差の補正と、前記フォーカスジャンプ部による合焦点位置の移動とを制御するフォーカスジャンプ制御部とを備えることを特徴とする光ディスク装置。 - 前記フォーカスジャンプ制御部は、前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向とは反対方向に隣接する記録層との間の層間距離に基づいて、前記球面収差補正部による球面収差の補正と、前記フォーカスジャンプ部による合焦点位置の移動とのうちのいずれを先に行うかを判断することを特徴とする請求項1記載の光ディスク装置。
- 前記フォーカスジャンプ制御部は、前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向とは反対方向に隣接する記録層との間の層間距離と所定の閾値とを比較し、前記層間距離が前記閾値より大きい場合、球面収差の補正を行った後、合焦点位置の移動を行い、前記層間距離が前記閾値以下である場合、合焦点位置の移動を行った後、球面収差の補正を行うことを特徴とする請求項2記載の光ディスク装置。
- 前記フォーカスジャンプ制御部は、前記現在の記録層と、前記現在の記録層から前後所定の距離の範囲内に存在する記録層との間の層間距離に基づいて、前記球面収差補正部による球面収差の補正と、前記フォーカスジャンプ部による合焦点位置の移動とを制御することを特徴とする請求項1~3のいずれかに記載の光ディスク装置。
- 前記フォーカスジャンプ制御部は、前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向に隣接する記録層との間の層間距離と、前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向とは反対方向に隣接する記録層との間の層間距離とに基づいて、前記球面収差を補正するための球面収差補正量を算出し、
前記球面収差補正部は、算出された前記球面収差補正量に応じて前記球面収差を補正することを特徴とする請求項1記載の光ディスク装置。 - 前記フォーカスジャンプ制御部は、球面収差を補正する位置を表す球面収差補正位置を下記の(1)式に基づいて算出し、算出した前記球面収差補正位置において前記球面収差を補正するための球面収差補正量を算出することを特徴とする請求項5記載の光ディスク装置。
SAtgt2=SAtgt+(ΔSA1/ΔSA2)×K・・・(1)
ただし、SAtgt2は、前記球面収差補正位置を表し、SAtgtは、前記光ディスクの表面から、前記光ビームの合焦点位置を移動させる方向に隣接する記録層までの距離を表し、ΔSA1は、前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向に隣接する記録層との間の層間距離を表し、ΔSA2は、前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向とは反対方向に隣接する記録層との間の層間距離を表し、Kは、補正係数を表す。 - 前記フォーカスジャンプ制御部は、算出された前記球面収差補正量に応じて前記球面収差を補正するように前記球面収差補正部に指示し、前記光ビームの合焦点位置を現在の記録層から他の記録層に移動するように前記フォーカスジャンプ部に指示し、移動後の前記他の記録層における球面収差を補正するように前記球面収差補正部に指示することを特徴とする請求項5又は6記載の光ディスク装置。
- 前記フォーカスジャンプ制御部は、前記光ビームが合焦している現在の記録層からm層離れた他の記録層へ合焦点位置を移動させる際に、隣接する記録層へ合焦点位置を移動させる動作をm回繰り返すように、前記球面収差補正部による球面収差の補正と、前記フォーカスジャンプ部による合焦点位置の移動とを制御することを特徴とする請求項1に記載の光ディスク装置。
- 前記フォーカスジャンプ制御部は、
前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向とは反対方向に隣接する記録層との間の層間距離に基づいて、前記球面収差を補正するための球面収差補正量を算出する球面収差補正量算出部と、
前記他の記録層において前記球面収差が最適になるように前記球面収差の補正を開始し、前記球面収差が前記他の記録層に最適になるまでの間、前記球面収差補正量算出部によって算出された球面収差補正量に達した場合、隣接する記録層へ合焦点位置を移動させるように前記フォーカスジャンプ部に指示する指示部とを含むことを特徴とする請求項1記載の光ディスク装置。 - 前記球面収差補正量算出部は、前記現在の記録層から2層以上離れた他の記録層へ合焦点位置を移動させる場合、前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向に隣接する記録層との間の層間距離と、前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向とは反対方向に隣接する記録層との間の層間距離とに基づいて、隣接する記録層へ合焦点位置を移動させる際の各球面収差補正量を算出することを特徴とする請求項9記載の光ディスク装置。
- 前記光ディスクの各記録層の層間距離を取得する層間距離取得部をさらに備え、
前記層間距離取得部は、前記光ディスクの規格値に基づいて前記層間距離を取得することを特徴とする請求項1~10のいずれかに記載の光ディスク装置。 - 前記光ディスクの各記録層の層間距離を取得する層間距離取得部をさらに備え、
前記層間距離取得部は、前記光ディスクの種類に対応する規格値に基づいて前記層間距離を取得することを特徴とする請求項1~10のいずれかに記載の光ディスク装置。 - 前記光ディスクの各記録層の層間距離を取得する層間距離取得部と、
前記光ビームを前記記録層に集光する対物レンズと、
前記光ビームを所定の記録層に合焦するために、前記対物レンズを光軸方向に駆動する駆動部と、
前記光ビームの合焦点位置と前記光ディスクの記録層との相対的な距離をフォーカスエラー信号として生成するフォーカスエラー信号生成部とをさらに備え、
前記層間距離取得部は、前記駆動部によって前記対物レンズを所定の速度で光軸方向に駆動させながら、前記フォーカスエラー信号生成部によって生成される前記フォーカスエラー信号を検出し、前記フォーカスエラー信号の検出タイミングに基づいて前記層間距離を取得することを特徴とする請求項1~10のいずれかに記載の光ディスク装置。 - 前記光ディスクの各記録層の層間距離を取得する層間距離取得部と、
前記光ビームの合焦点位置と前記光ディスク上に形成されたトラックとの相対的な距離をトラッキングエラー信号として生成するトラッキングエラー信号生成部とをさらに備え、
前記層間距離取得部は、前記光ディスクの各記録層において生成される前記トラッキングエラー信号の振幅が最大となる位置の前記球面収差の補正量に基づいて前記層間距離を取得することを特徴とする請求項1~10のいずれかに記載の光ディスク装置。 - 前記光ディスクの各記録層の層間距離を取得する層間距離取得部と、
前記光ディスクの各記録層に記録されている情報を再生して再生信号品質指標を生成する再生信号品質指標生成部とをさらに備え、
前記層間距離取得部は、前記光ディスクの各記録層の記録済み領域を再生することによって生成される前記再生信号品質指標が最良となる前記球面収差の補正量に基づいて前記層間距離を取得することを特徴とする請求項1~10のいずれかに記載の光ディスク装置。 - 複数の記録層を有する光ディスクに照射される光ビームの合焦点位置を現在の記録層から他の記録層に移動させるためのフォーカス制御方法であって、
前記光ディスクの所定の記録層に光ビームを合焦させるフォーカス制御ステップと、
前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向とは反対方向に隣接する記録層との間の層間距離に基づいて、前記記録層上の光スポットにおいて発生する球面収差の補正と、前記光ビームの合焦点位置の移動とを制御するフォーカスジャンプ制御ステップとを含むことを特徴とするフォーカス制御方法。 - 複数の記録層を有する光ディスクに照射される光ビームの合焦点位置を現在の記録層から他の記録層に移動させるための集積回路であって、
前記光ディスクの所定の記録層に光ビームを合焦させるフォーカス制御回路と、
前記現在の記録層と、前記光ビームの合焦点位置を移動させる方向とは反対方向に隣接する記録層との間の層間距離に基づいて、前記記録層上の光スポットにおいて発生する球面収差の補正と、前記光ビームの合焦点位置の移動とを制御するフォーカスジャンプ制御回路とを備えることを特徴とする集積回路。
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