JPH0554406A - Optical disk device - Google Patents

Abstract

PURPOSE:To identify plural optical disks whose disk base plate; are different in thickness and to record, reproduce or erase an information signal. CONSTITUTION:Laser beam is converged without aberration by using an objective lens 46 with regard to the disk base plate whose thickness is d2 and is converged without aberration by using the objective lens 46 and a wave front correction lens 54 with regard to the disk base plate whose thickness is d1 So, information signal is properly recorded, reproduced or erased on both disks. Further, the objective lens 46 is made to approach the surface of a disk at constant speed by a lamp generating circuit, and the time interval at which two S-shaped wave forms take place in a focus error signal is measured by a counter. So, the thickness of a disk base plate is identified with no special detector provided.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disc having a recording density comparable to that of a conventional CD (compact disc), and a C
D relates to an optical disc device capable of recording, reproducing or erasing information signals on both optical discs having different disc substrate thicknesses and high recording density.

[0002]

2. Description of the Related Art In recent years, in addition to a read-only optical disk device such as a CD player, an optical disk device capable of recording and reproducing information signals has been actively developed.

Recording and reproduction of information signals on an optical disc are usually performed by focusing a radiation beam of a semiconductor laser or the like on a recording layer of the optical disc by a lens. Here, the recording layer is a pit layer in a CD, and is a layer in a recordable optical disc that is deformed, the optical constant is changed, or a magnetic domain is formed by a focused laser beam. In order to increase the recording density of the optical disk, it is necessary to reduce the spot diameter D of this focused beam. This D is the numerical aperture NA of the lens and the wavelength λ of the laser light.
In contrast, the relationship shown in (Equation 1) is obtained.

[0004]

[Equation 1]

The expression (1) shows that the beam spot diameter D is reduced as the lens has a larger NA. That is, high density recording becomes possible by increasing NA.

However, when the NA of the lens increases,
The aberration of the focused beam due to the tilt error of the disc called tilt increases. In particular, coma becomes large. The wavefront aberration Wc of the coma and the tilt angles α and NA have the relationship shown in (Equation 2) when the thickness d of the disk substrate and the refractive index n are used.

[0007]

[Equation 2]

(Equation 2) shows that when a lens having a larger NA than the conventional one is used, the coma aberration increases even if the tilt angle is the same. However, from the equation, it can be seen that reducing the disc substrate thickness d is effective in suppressing coma. Therefore, in the optical disc for high density recording, it is preferable that the disc substrate has a smaller thickness than that of the conventional optical disc. Therefore, an optical head using an objective lens corresponding to the thin disc substrate is required.

On the other hand, even in an optical disc device compatible with high-density recording, it is preferable that the conventional optical disc having a thick substrate can be reproduced so that the abundant software resources can be utilized.

[0010]

However, an optical head designed for a thin substrate cannot be used for an optical disc having a thick substrate. The reason will be described below. Objective lenses for optical disks are designed to cancel the spherical aberration that occurs when the focused beam passes through the disk substrate. Since this aberration correction is made according to the thickness of the disk substrate, the aberration correction is not made correctly for a focused beam passing through the disk substrate having a thickness different from the designed value.
This will be described with reference to the drawings. FIG. 6 is a schematic side view for explaining how aberrations occur due to disk substrates having different thicknesses. (A) is an objective lens designed for a thin disc substrate, and is a ray tracing diagram of a state in which a beam is condensed through a disc substrate having a thickness as designed. In the figure, the broken line shows the surface of the recording layer, and all the light rays emitted from the objective lens are focused on a point O on the surface of the recording layer. (B) is an objective lens designed for the same thin disk substrate as in (a), and is a ray tracing diagram of a state in which a beam is focused through a disk substrate thicker than the designed value.
In (b), the light beam emitted from the outermost peripheral edge portion of the objective lens is focused at a point O ′ on the surface of the recording layer, but the light beam closer to the optical axis is focused closer. This is spherical aberration,
When this aberration occurs, the objective lens cannot focus the light beam to the so-called diffraction limit. Therefore, an objective lens whose aberration is corrected for a thin disk substrate cannot record, reproduce or erase an information signal on an optical disk having a thick disk substrate. Similarly, an objective lens whose aberration is corrected for a thick disc substrate cannot record, reproduce or erase information signals on an optical disc having a thin disc substrate.

In view of the above points, an object of the present invention is to provide an optical disk device capable of identifying a plurality of optical disks having different disk substrate thicknesses and recording, reproducing or erasing an information signal.

[0012]

In order to achieve this object, the optical disk device of the present invention has N (N ≧ N) having different thicknesses.
2) Disc identification that discriminates the N focusing optical systems in which aberrations have been corrected for each disc substrate and the thickness of the disc substrate of the mounted optical disc, and outputs an identification signal according to the identified result. An optical disc device comprising: a means and a control means for selecting one of the focusing optical systems according to an identification signal, wherein the focusing optical system includes an objective lens for condensing the light flux emitted from the light emitting means onto the optical disc. A light detecting means for detecting the reflected light from the optical disc, N wavefront correcting means for correcting the direction of the light flux, and N wavefront correcting means, and one of the N wavefront correcting means held. One
The optical head is provided with a moving unit that is selected according to the control signal and moves on the optical path between the light emitting unit and the optical disc.

Further, focus error detection means for detecting a distance in the optical axis direction between the focus position by the focusing optical system and the reflection surface of the optical disk, focus position control means for moving the condensing position in the optical axis direction, A first comparison that compares a focus error signal output from the focus error detection means with a predetermined first reference value, and outputs a first signal when the focus error signal is larger than the first reference value. Means for comparing the focus error signal with a predetermined second reference value to determine that the focus error signal is the second reference value.
The second signal that outputs a second signal when it is larger than the reference value of
Of the first and second signals, and the first signal and the second signal output when the focus position control unit moves the focus position toward the optical disc. Disc discriminating means including a measuring means for measuring the time interval of the signal and outputting the time interval information.

Further, there is provided position control means for moving the light emitting means onto a specific area other than the recording area of the optical disk.

[0015]

According to the present invention, according to the above construction, the control means selects the wavefront correction means which produces the least aberration according to the thickness of the disk substrate of the mounted optical disk, and the moving means selects such wavefront correction means. Is located on the optical path between the light emitting means and the optical disc, so that the light beam from the light emitting means is focused on the recording layer of the optical disc without aberration.

Further, in the disc discriminating means, the focus position control means moves the focus position of the light beam toward the optical disc. When the level of the focus error signal output by the focus error detecting means is higher than the first reference value, the first signal output by the first comparing means and when the level is higher than the second reference value. The measuring means measures the time interval with the second signal output by the second comparing means,
The thickness of the disc substrate is determined by the length of the time interval.

Further, the position control means moves the light emitting means to a specific area other than the recording area of the optical disc, and the light flux is condensed in this area while the rotation of the optical disc is stopped. I am trying to measure.

[0018]

The present invention is applicable to a plurality of disc substrate thicknesses, but in the embodiment, the disc substrate thickness is two.
The types will be described below.

FIG. 1 is a block diagram of an optical disk device according to an embodiment of the present invention, FIG. 2 is a schematic view showing a cross section of the optical disk according to the embodiment and a state of focusing by an objective lens, and FIG. 3 is an optical head according to the embodiment. 3 is a detailed configuration diagram of FIG.

In FIG. 1, reference numeral 1 is a first or second optical disk, and the disk substrates of both optical disks have different thicknesses. Reference numeral 2 denotes a cartridge for housing and protecting the optical disc 1, which is made of plastic or the like.
An optical head 3 outputs a light detection signal and receives a recording signal, and has a focusing optical system including an unillustrated objective lens, semiconductor laser, photodetector, beam splitter, and the like. The optical head 3 has a base that holds these optical elements and an actuator. A linear motor 4 is installed on the lower surface of the optical disc 1 and moves the optical head 3 in the radial direction of the disc parallel to the disc surface. Reference numeral 11 is a tracking error detection circuit that receives a light detection signal output from the optical head 3 and outputs a tracking error signal, and 12 is a tracking control circuit that receives the tracking error signal and outputs a drive signal to an actuator of the optical head 3. .. Reference numeral 13 is a focus error detection circuit which receives a light detection signal and outputs a focus error signal, and 14 is a focus control circuit which receives a focus error signal and outputs a drive signal to the actuator of the optical head 3. 15 is a linear motor 4 according to a control signal output from a system controller 22 described later.
It is a linear motor control circuit that outputs a drive signal to. 1
A disc discriminating circuit 6 receives a focus error signal from the focus error detecting circuit 13 and outputs an identification signal to a system controller 22 described later. Reference numeral 17 denotes a spindle control circuit that receives a light detection signal and outputs a control current to a spindle motor 18, which will be described later. Reference numeral 18 denotes a spindle motor that rotates the optical disc 1. 19
Performs signal processing such as demodulation and / or decoding from the input light detection signal and converts it into an audio signal,
Alternatively, it is a signal processing circuit that outputs an information signal for recording on the optical disc 1 to a semiconductor laser drive circuit (hereinafter referred to as an LD drive circuit) 20 described later. Reference numeral 20 is an LD drive circuit that outputs a drive current for causing the semiconductor laser of the optical head 3 to emit light. A system 22 receives an identification signal from the disc discrimination circuit 16 and outputs a control signal to the optical head 3, the focus control circuit 14, the linear motor control circuit 15, the disc discrimination circuit 16, the signal processing circuit 19 and the LD drive circuit 20. The controller.

Here, the first optical disc is a CD or an optical disc having a recording density equivalent to that of the CD, and
As shown in (a), the thickness d ₁ of the disk substrate is 1.2 m.
m. The second optical disk is an optical disk capable of higher density recording than that, and the thickness d ₂ of the disk substrate is set so as to reduce the aberration of the focused spot due to the tilt error as shown in FIG. , Is designed to be smaller than the above-mentioned d ₁ , for example d ₂ = 0.3 mm.

Further, in FIG. 3A, 1 is a first or second optical disk, 32 is a semiconductor laser which serves as a light source, 33 is a collimator lens for collimating the beam from the semiconductor laser 32, and 34 is a beam. A beam splitter for splitting, 46 is an objective lens for focusing the beam on the optical disc 1, 37 is a detection lens for focusing the reflected light split by the beam splitter 34, and 38 is a light detection signal from the collected reflected light. It is a photo detector for obtaining. 5
Reference numeral 6 denotes a lens holder that holds the objective lens 46, and 57 denotes an actuator that supports the lens holder 56, which is driven by the tracking control circuit 12 and the focus control circuit 14 described above. Further, 54 is an optical axis of the objective lens 4
6 is a wavefront correction lens attached to a slider 55 to be described later so as to be parallel to the optical axis of 6. Reference numeral 55 denotes a slider that supports the wavefront correction lens 54 and is arranged so as to cross a plane perpendicular to the light flux between the beam splitter 34 and the objective lens 46, and allows the wavefront correction lens 54 to move within this plane. .. Moreover, the moving range is a position where the wavefront correction lens 54 is completely out of the light beam (denoted by P1 in the figure) or a position where the laser beam incident on the objective lens 46 passes (in the figure). P2)
Is. FIG. 11B is a plan view of the wavefront correction lens 54 and the slider 55 as seen from the optical axis direction. In the figure,
The wavefront correction lens 54 is movable along the direction indicated by the arrow. The above components are installed on the same base member (not shown) to form the optical head 3. This base member is usually made of aluminum or the like, and is used for the linear motor 4
Is attached to.

Here, as shown in FIG. 2B, the objective lens 46 can focus a laser beam having a wavelength of 780 nm to a spot diameter of about φ1.2 μm with NA = 0.8,
Moreover, it is optically designed to correct the aberration due to the disk substrate having the thickness d ₂ . On the other hand, the wavefront correction lens 54
Is the objective lens 4 as shown in FIGS. 2 (a) and 2 (c).
6 has a NA of 0.45 and a thickness d.
It is designed to correct the aberration caused by the disk substrate of ₁ . That is, in the optical head 3, the objective lens 4
Reference numeral 6 constitutes a second focusing optical system corresponding to the second optical disc, together with the semiconductor laser 32, the collimator lens 33 and the beam splitter 34, and by adding a wavefront correction lens 54 to the second focusing optical system, It can be considered that the first focusing optical system corresponding to one optical disc is configured.

The operation of the optical disk device of this embodiment having the above-described structure will be described below.

First, the case where the cartridge 2 containing the second optical disk is mounted in the optical disk device of this embodiment will be described. When the cartridge 2 is mounted, the system controller 22 outputs a control signal to the LD drive circuit 20, the focus control circuit 14, and the disc discriminating circuit 16, and the content of the cartridge 2 is either the first optical disc or the second optical disc. Identify if there is. Details of this operation and the configuration of the disc discrimination circuit 16 will be described later. When the system controller 22 determines from the discriminating signal from the disc discriminating circuit 16 that the mounted optical disc is the second optical disc, it outputs a control signal to the slider 55. When the control signal is input, the slider 55 moves the wavefront correction lens 54 to the position P1. Semiconductor laser 3
The light emitted by 2 is collimated by the collimator lens 33, reflected by the beam splitter 34, and condensed on the optical disc 1 by the objective lens 46. The light reflected by the optical disc 1 is collimated again by the objective lens 46, passes through the first beam splitter 34, and is condensed on the photodetector 38 by the detection lens 37. The photodetector 38 outputs a light detection signal from the condensed disk reflected light to the signal processing circuit 19, the spindle control circuit 17, the focus error detection circuit 13, and the tracking error detection circuit 11. The actuator 57 uses the drive current from the tracking control circuit 12 and the focus control circuit 14 to drive the lens holder 5
6 is finely displaced in the tracking direction and the focusing direction to properly focus the laser beam on the information track on the optical disc 1.

The tracking error detection circuit 11 generates a tracking error signal from the input light detection signal and outputs it to the tracking control circuit 12. A known method such as a three-beam method or a push-pull method can be applied to detect the tracking error amount. The tracking control circuit 12 generates a tracking actuator drive signal according to the tracking error signal and controls the actuator 57 of the optical head 3 so that the tracking error becomes zero. Similarly, the focus error detection circuit 13 also generates a focus error signal by a known focus error detection method such as the astigmatic difference method and outputs it to the focus control circuit 14 and the disc discrimination circuit 16. The focus control circuit 14 generates a focus actuator drive signal according to the focus error signal and controls the actuator 57 of the optical head 3 so that the focusing error becomes zero. The linear motor control circuit 15 outputs a drive current to the linear motor 4 in response to a control signal from the system controller 22 to move the optical head 3 in the inner peripheral direction or the outer peripheral direction of the optical disc 1. The spindle control circuit 17 extracts a clock component from the light detection signal and controls the spindle motor 18 to rotate the optical disc 1 at a constant linear velocity (referred to as CLV) or a constant angular velocity (referred to as CAV).
The signal processing circuit 19 generates an information signal from the photodetection signal during reproduction, performs signal processing such as demodulation and decoding, and outputs the signal as an audio or video signal to the outside. On the other hand, at the time of recording, audio or video signals input from the outside are subjected to signal processing such as encoding and modulation, and LD is used as a recording signal.
Output to the drive circuit 20. The LD drive circuit 20 modulates the intensity of the laser beam by modulating the drive current input to the semiconductor laser 32 of the optical head 3 with the recording signal, and records the information signal on the second optical disc 1. In this way, the optical head 3 records, reproduces, or erases information signals on the second optical disc 1 until the cartridge 2 is removed.

On the other hand, when the loaded optical disc 1 is the first optical disc, the system controller 22 outputs a control signal to the slider 55 so as to move the wavefront correction lens 54 to the position P1. Therefore, the semiconductor laser 3
The laser beam emitted by 2 passes through the wavefront correction lens 54 and the objective lens 46 and is focused on the information track of the optical disc 1 without any aberration, and the information signal is appropriately recorded, reproduced or erased. The operation of other components is
This is the same as the case of the second optical disc described above.

Next, details of the disc discriminating circuit 16 will be described with reference to the drawings. FIG. 4 is a block diagram of a portion for identifying the thickness of the disc in this embodiment. In the figure, 60 is a phase compensation filter that receives the output b of the focus error detection circuit 13 and outputs a phase-compensated error signal to a driver 61, which will be described later, and 61 is from the phase compensation filter 60 or a ramp generation circuit 63 that will be described later. A driver that receives a signal and outputs a drive current to the actuator 57, and 62 is a gate that is installed between the phase compensation filter 60 and the driver 61, and is controlled by the control signal from the controller 22. Reference numeral 63 is a ramp generation circuit that outputs a ramp signal a to the driver 61. The above are the components of the focus control circuit 14. Further, 70 is a focus error signal b from the focus error detection circuit 13,
A reset pulse from the system controller 22 is input, and a first level comparator 71 which outputs a start pulse c to a counter 72 described later, 71 receives a focus error signal b, and outputs a stop pulse d to a counter 72 described later. A second level comparator 72 is a counter which receives a start pulse c and a stop pulse d and outputs a count value to an identification circuit 73 described later,
A discriminating circuit 73 receives the count value and outputs an discriminating signal to the controller 22. The discriminating circuit 73 constitutes the disc discriminating circuit 16.

FIG. 5 is a waveform diagram showing signal waveforms at respective points a to d shown in FIG. 4 when discriminating the substrate thickness of the optical disk. (A) is the output voltage of the ramp generation circuit 63. (B) is a focus error signal, a dotted line comparison voltage V ₁ of the first level comparator 70, and shows a comparison voltage V ₂ of the second level comparator 71. In this signal, the left S-shaped waveform is generated by the reflection of the laser beam on the substrate surface of the optical disc 1, and the right S-shaped waveform is the laser beam transmitted through the substrate.
It is caused by reflection on the recording layer, which is a regular reflection position. In general, the former S-shaped waveform is several times smaller than the latter S-shaped waveform. (C) is an output waveform of the first level comparator 70, and (d) is an output waveform of the second level comparator 71.

The operation of the optical disc apparatus of this embodiment in the process of identifying the thickness of the disc substrate of the optical disc 1 by the focus control circuit 14 and the disc discriminating circuit 16 will be described below with reference to FIG.

First, when the optical disc 1 is loaded, the gate 62 is controlled by a control signal from the system controller 22.
Is opened (OFF), and the lamp generation circuit 63
Outputs a ramp waveform signal to the driver 61, as shown in FIG. The driver 61 drives the actuator 57 of the optical head 3 in accordance with the ramp waveform signal,
The objective lens 46 is brought close to the optical disc 1 at a constant speed v.

When the objective lens 46 approaches the disk surface,
First, as shown in FIG. 5B, an S-shaped waveform appears in the focus error signal due to reflection from the disk surface. The comparison voltage V ₁ is set lower than the maximum value of this S-shaped waveform, and V ₂ is set high. Thus, Figure 5 at the time of exceeding the V ₁
As shown in (c), the output of the first level comparator 70 changes. This is input to the counter 72 as a start pulse. Further, once the start pulse is output, the output signal is held until the reset pulse is input.

Further, when the objective lens 46 approaches the optical disc 1, the regular S-shaped waveform appears in the focus error signal due to the reflection from the regular reflection position. Since V ₂ is set lower than the level of this S-shaped waveform,
When the level of the focus error signal exceeds V ₂ , the output of the second level comparator 71 changes. This is input to the counter 72 as a stop pulse. First
Since the level comparator 70 of 1 is still held, its output signal does not change. The counter 72 measures the time from the start pulse to the stop pulse and outputs the count value to the identification circuit 73. Since the objective lens 46 was approaching the optical disc 1 at a constant speed, the time difference between the two S-shaped waveforms is proportional to the difference in reflection position, that is, the thickness of the disc substrate. The identification circuit 73 receives the input count value,
Compare with a preset reference value. If it is smaller than the count reference value, it is determined that the optical disc has a thin substrate, and if it is larger, it is determined that the optical disc is a thick optical disc, and an identification signal is output to the controller 22. The size of the counting reference value is appropriately (d ₁ −d ₂ ) / v in terms of time amount, using d ₁ and d ₂ shown in FIG. 2, for example.

Upon receiving the identification signal, the system controller 22 outputs a control signal to the ramp generation circuit 63 to stop the generation of the ramp signal. Also, a reset pulse is output to return the first level comparator 70 to the initial state. In this way, the thickness of the disc substrate of the optical disc 1 is identified.

More preferably, when the optical disc 1 is a recordable disc, the information recording area such as an inner peripheral portion of the disc or an area specially provided for identifying the plate thickness in a state where the rotation of the disc is stopped. It is better to identify the plate thickness in other areas. As a result, it is possible to prevent the recording film from being destroyed by irradiating the same location on the disc with the laser beam for a long time and erasing the recorded information in order to identify the plate thickness. The operation of the optical disk device of the present embodiment when discriminating the plate thickness at the inner peripheral portion of the disk will be described below.

When the optical disc 1 is loaded, the system controller 22 outputs a control signal to the linear motor control circuit 15 so that the optical head 3 is attached to the linear motor 4 by the optical disc 1.
Move to the inner circumference of. When the movement of the optical head 3 is completed, the LD drive circuit 20 causes the semiconductor laser 32 of the optical head 3 to emit light with a constant intensity according to a control signal from the system controller 22. The laser beam from the semiconductor laser 32 is focused on the non-recording area on the inner circumference of the disc, and the disc discrimination circuit 14 measures the plate thickness by the reflected light from the disc as described above. When the plate thickness determination is completed, the system controller 22 causes the spindle motor 18 to rotate the optical disk 1 and outputs a control signal to the focus control circuit 14 and the tracking control circuit 12 to start the focus and tracking control. When both controls are stable, the optical head 3 is moved to a predetermined start position to start recording, reproducing or erasing.

As described above, according to this embodiment, the thickness d ₂
By focusing the laser beam on the disk substrate of _{No. 2} by the objective lens 46 without aberration, and by focusing the laser beam on the disk substrate of thickness d _{1 by} the objective lens 46 and the wavefront correction lens 54 without aberration. , Information signals can be recorded, reproduced or erased well on either disc.

The output of the lamp generation circuit 63 brings the objective lens 46 closer to the disk surface at a constant speed, and the counter 72 measures the time interval at which two S-shaped waveforms appearing in the focus error signal are generated. The thickness of the disc substrate can be discriminated without the provision of a detector.

Further, in the case of a recordable optical disc, the disc thickness is discriminated by the control of the system controller 22 in a region outside the recording region, such as the inner peripheral portion of the disc, so that it has been recorded by irradiation with a laser beam for a long time. No information is destroyed.

The optical head 50 of this embodiment has a thickness d
_Although the objective lens 46 corresponding to the _second disc substrate is provided, and the disc substrate having the thickness d ₁ is further configured to add the aberration correction by the wavefront correction lens 54, the reverse configuration may be adopted. .. That is, the objective lens 46 is set to the first
In place of the lens having the aberration correction and NA corresponding to the optical disc of 1), on the other hand, the above-mentioned effect can be obtained even in the configuration including the wavefront correction lens designed to perform the aberration correction and the NA corresponding to the disc substrate having the thickness d _2. can get. In addition, two wavefront correction lenses are provided, and each of the first and second objective lenses is provided.
Alternatively, the optical system may be configured to have aberration correction and NA corresponding to the second optical disc.

Further, in the present embodiment, the wavefront correction lens 54 is used as the wavefront correction means for the optical disc having the plate thickness corresponding to the objective lens 46, but a wavefront conversion element such as a liquid crystal hologram is used as the objective lens. It may be arranged on the optical path and the wavefront of the focused light on the optical disc may be switched by the wavefront conversion element according to the plate thickness. In this case, an electric control signal allows the wavefront to pass through unchanged,
Since the wavefront can be converted so as to correct the aberration and change the NA, the mechanical moving means such as the slider 55 is unnecessary, and the optical head 3 can be made smaller and lighter.

Further, in the present embodiment, the description has been made assuming that the disk substrate has two types of thickness, but the present invention can be applied to the case of three types or more. In this case, the number of wavefront correction lenses may be increased according to the number of plate thickness types. Further, the discriminating means of the optical disc may be configured so that the number of counting reference values is increased according to the number of kinds of plate thickness and a plurality of counting values can be discriminated.

[0043]

As described above, according to the present invention,
Since the objective lens and the wavefront correcting means corresponding to the substrate thickness of each of the N disks are provided, an optical disk device capable of recording or reproducing on any optical disk can be realized, and its practical effect is large.

Further, when the focus position control means brings the objective lens close to the disk surface, the measuring means measures the time interval at which two S-shaped waveforms are generated in the focus error signal, so that the thickness of the disk substrate is increased. Can be identified without providing a special detector.

Further, by setting the position where the luminous flux from the light emitting means is condensed to measure the time interval information to a specific area other than the recording area on the optical disk, the luminous flux on which the recorded information is condensed. It won't be destroyed by.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an optical disc device according to an embodiment of the present invention.

FIG. 2 is a schematic diagram showing a cross section of an optical disk and a state of light collection by an objective lens in the same example.

FIG. 3 is a block diagram showing a detailed configuration of an optical head in the embodiment.

FIG. 4 is a block diagram showing an internal configuration of a portion for identifying the thickness of the disc in the embodiment.

5 is a waveform diagram showing signal waveforms used for explaining the operation of FIG.

FIG. 6 is a schematic side view for explaining a situation in which aberrations are generated by conventional disk substrates having different thicknesses.

[Explanation of symbols]

 1 Optical Disc 3 Optical Head 13 Focus Error Detection Circuit 14 Focus Control Circuit 16 Disc Discrimination Circuit 22 System Controller 32 Semiconductor Laser 38 Photo Detector 46 Objective Lens 54 Wavefront Correction Lens 55 Slider 57 Actuator 63 Lamp Generation Circuit 64 Adder 70 First Level Comparator 71 Second Level Comparator 72 Counter 73 Discrimination Circuit

Claims (3)

[Claims] 1. N-focusing optical systems in which aberrations are respectively corrected with respect to N (N ≧ 2) disc substrates having different thicknesses, and the thicknesses of the substrates of the optical discs mounted are identified and identified. An optical disc apparatus comprising: a disc identification unit that outputs an identification signal according to the result; and a control unit that selects one of the focusing optical systems according to the identification signal. Emitting light, an objective lens for condensing the light flux emitted from the light emitting means onto the optical disc, a photodetector for detecting reflected light from the optical disc, and N wavefront corrections for correcting the directions of the light fluxes. And means for holding the N wavefront correcting means and moving one of the held N wavefront correcting means on the optical path between the light emitting means and the optical disk. Light consisting of an optical head Disk device. 2. A focus error detecting means for detecting a distance in the optical axis direction between a focus position where a light beam from the light emitting means is focused and a reflecting surface of the optical disk, and a focus position control for moving the condensing position in the optical axis direction. Means for comparing the focus error signal output from the focus error detection means with a predetermined first reference value, and outputs the first signal when the focus error signal is larger than the first reference value. A first comparing means comparing the focus error signal with a predetermined second reference value, and outputting a second signal when the focus error signal is larger than the second reference value. Two comparing means, and the first and second signals are input, and the first and second signals are output when the focus position control means moves the focus position toward the optical disc. Signal and said second measuring means for outputting the time interval information by measuring the time interval of the signal, the optical disk apparatus according to claim 1, further comprising a disk discrimination means comprising. 3. A position control means for moving the light emitting means onto a specific area other than the recording area of the optical disc, wherein the light flux from the light emitting means is focused on the area while the rotation of the optical disc is stopped. The optical disk device according to claim 2, wherein the time interval information is measured by