JP2004039025A - Optical disk for adjusting optical pickup, and device and method to adjust optical pickup - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To simplify the adjustment of a pair of optical pickups which are used to reproduce a double-sided reproduction DVD and to quickly conduct the adjustment. <P>SOLUTION: An optical disk is provided with a first signal recording layer 5 of a first disk substrate 2 side onto which the light beam from one of the optical pickups is made incident and a second signal recording layer 7 of a second disk substrate 4 side onto which the light beam from the other optical pickup is made incident. Recording tracks are provided on the layers 5 and 7 in a spiral and a reverse spiral, respectively. The recording direction of the data of the layer 5 is started from either one of the inner periphery or the outer periphery whereas the recording direction of the layer 7 is reversed with respect to the recording direction of the layer 5. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical disk for adjusting an optical pickup used for adjusting an optical pickup capable of recording and reproducing an optical disk having a signal recording layer on both surfaces, an optical pickup adjusting device, and an optical pickup adjusting method using the adjusting device. About.
[0002]
[Prior art]
As an optical recording medium, there is a DVD (Digital Versatile Disk) having a higher recording density than a CD (Compact Disk). DVDs include a double-sided reproduction type which has a plurality of recording layers on which data is recorded and which reproduces data by irradiating a laser beam from each side of the disk, for example. Such a DVD has a structure in which two substrates having a recording surface are bonded together via an adhesive.
[0003]
An apparatus for recording / reproducing a DVD of the double-sided reproduction type as described above includes a pair of optical pickups corresponding to each side, and a laser beam from the optical pickup corresponding to each of one side and the other side of the DVD. To reproduce each side of the DVD.
[0004]
The pair of optical pickups are respectively a light source for emitting a light beam of 635-650 nm for DVD, an objective lens for condensing the light beam emitted from the light source, and a return light reflected on the corresponding signal recording surface of DVD. It is provided with a photodetector for detecting a beam, an objective lens driving section for driving and displacing the objective lens in the focusing direction and the tracking direction, and the like.
[0005]
The objective lens driving section includes a lens holder that holds the objective lens, a holder support member that supports the lens holder by an elastic support member so as to be displaceable in a focusing direction and a tracking direction, and a lens holder that holds the objective lens in the focusing direction. A focusing drive unit for driving displacement and a tracking drive unit for driving and displacing the lens holder holding the objective lens in the tracking direction are provided.
[0006]
The focusing drive unit includes a focusing coil and a focusing magnet, and focuses the lens holder held on the elastic support member by the action of the current flowing through the focusing coil and the magnetic field generated by the focusing magnet in the optical axis direction of the objective lens. Drive displacement in the direction. The tracking drive unit includes a tracking coil and a tracking magnet, and moves the lens holder supported by the elastic support member by the action of the current flowing through the tracking coil and the magnetic field generated by the tracking magnet at right angles to the optical axis of the objective lens. Drive displacement.
[0007]
In the optical pickup having the above-described configuration, when reproducing one surface of a DVD, a light beam emitted from a light source in one optical pickup is focused on a signal recording surface of one surface of the DVD. The objective lens is driven and displaced by the focusing drive unit, and the objective lens is driven and displaced in the tracking direction by the tracking drive unit to scan the light beam and read out the information signal recorded on one surface of the DVD. Do.
[0008]
Further, such an optical pickup has a focusing drive so that when reproducing the other surface of the DVD, the light beam emitted from the light source in the other optical pickup is focused on the signal recording surface of the other surface of the DVD. The unit drives and displaces the objective lens, and the tracking drive unit drives and displaces the objective lens in the tracking direction, thereby scanning the light beam and reading out the information signal recorded on the other surface of the DVD.
[0009]
The optical pickup configured as described above is further attached to a base unit to be assembled into a recording and / or reproducing device. The base unit has a base mounted on a casing of the recording and / or reproducing apparatus, and a slide member on which the optical pickup is mounted and a slide member on which the optical pickup is mounted are fed to the base in a radial direction of the optical disk. A feed mechanism for operating and a disk rotation drive mechanism for rotating the optical disk are provided.
[0010]
By the way, in the optical pickup assembled in the assembling process, the relative position between the objective lens and the light source and the inclination of the optical axis of the objective lens are adjusted. This adjustment is performed, for example, after each optical pickup is assembled to the base unit, and does not depend on the assembling accuracy of the optical pickup to the base unit, as compared to the adjustment performed before assembling the optical pickup to the base unit. In addition, the relative position between the objective lens and the light source and the inclination of the optical axis of the objective lens can be adjusted.
[0011]
This adjustment is performed for the corresponding recording surface of the DVD for each optical pickup. Specifically, first, an adjustment optical disk for DVD is mounted on a disk rotation drive mechanism, and the adjustment optical disk for DVD is rotated in a predetermined direction, and the optical characteristic of one optical pickup becomes an optimum value. Thus, the relative position between the objective lens and the light source is adjusted. Then, TOC (Table Of Contents) information of the adjustment optical disk is read, a predetermined portion of the adjustment optical disk is accessed, and the tilt of the objective lens is adjusted using the adjustment optical disk.
[0012]
Then, the rotation of the adjustment optical disc for DVD is stopped, the adjustment optical disc is rotated in a direction opposite to the predetermined direction, and the objective lens and the light source are set so that the optical characteristics of the other optical pickup have an optimum value. Adjust the relative position of. Then, the TOC information of the adjustment optical disk is read, a predetermined portion of the adjustment optical disk is accessed, and the tilt of the objective lens is adjusted using the adjustment optical disk.
[0013]
Here, on the adjustment optical disk, data that is 8-16 modulated in the same physical format as the DVD is spirally recorded on both sides.
[0014]
[Problems to be solved by the invention]
As described above, in the adjustment of a pair of optical pickups used for recording and reproduction of an optical disk such as a DVD of a double-sided reproduction type, when adjusting the optical characteristics when reproducing the optical disk, the adjustment optical disk is mounted on the disk rotation drive mechanism. To rotate in a predetermined direction, adjust the optical characteristics of one optical pickup when reproducing one surface of the optical disk, temporarily stop the rotation of the adjusting optical disk, and then reversely rotate the other surface of the optical disk. It is necessary to adjust the optical characteristics of the other optical pickup when reproducing the data. Such an adjustment requires an operation of stopping the rotation of the adjustment optical disk and rotating the adjustment optical disk in the reverse direction, so that it has been difficult to improve the efficiency of the adjustment operation of the pair of optical pickups.
[0015]
The present invention has been made in view of the above-described problems, and an object of the present invention is to simplify and quickly adjust a pair of optical pickups that can perform recording and reproduction on a double-sided reproduction type optical disc. To provide an optical disc for adjusting an optical pickup.
[0016]
Another object of the present invention is to provide an optical disc for adjusting an optical pickup, which can simplify the configuration of the adjusting device.
[0017]
[Means for Solving the Problems]
The optical disc for adjusting the optical pickup according to the present invention has two surfaces serving as signal recording surfaces, recording tracks are provided spirally on one signal recording surface, and the other signal recording surface has Is characterized in that recording tracks are spirally provided in the direction opposite to one signal recording surface, and each signal recording surface is irradiated with laser light from each surface side.
[0018]
In the optical disc for adjusting the optical pickup configured as described above, the pair of optical pickups can be adjusted without stopping the rotation of the optical disc for adjusting the optical pickup.
[0019]
In the optical pickup adjusting device according to the present invention, both surfaces are signal recording surfaces, recording tracks are spirally provided on one signal recording surface, and recording tracks are provided on one signal recording surface with one signal recording surface. An adjustment optical disk which is provided in a spiral shape in a direction opposite to the recording surface, and which is irradiated with laser light from each surface side to each signal recording surface; a rotation driving means for rotating the adjustment optical disk; The light is emitted, the laser light is focused on the corresponding signal recording surface of the adjustment optical disk by the condenser lens, the return light reflected by the adjustment optical disk is received by the light receiving section, and a signal corresponding to the received light intensity is received. Sending means for sending a pair of opposing optical pickups for output in the radial direction of the adjusting optical disc, and a light receiving section for receiving and receiving return light from the adjusting optical disc. Based on the signal output according to the intensity, characterized in that it comprises adjustment means for adjusting the optical characteristics of the optical pickup, respectively.
[0020]
The optical pickup adjusting device configured as described above can adjust a pair of optical pickups without stopping the rotation of the optical disc for adjusting the optical pickup.
[0021]
Furthermore, in the method for adjusting an optical pickup according to the present invention, both surfaces are signal recording surfaces, recording tracks are spirally provided on one signal recording surface, and recording tracks are provided on one signal recording surface with one signal recording surface. A step of rotating an adjustment optical disc, which is provided in a spiral shape in a direction opposite to the recording surface and is irradiated with laser light from each side with respect to each signal recording face, and a step of rotating each of the signal recording faces of the adjustment optical disc; A pair of corresponding opposing optical pickups emits laser light from a light source and focuses the laser light on each corresponding signal recording surface of the adjustment optical disc by a condenser lens; and returns from the adjustment optical disc. Based on a signal that receives light by the light receiving section of each optical pickup and outputs the light according to the intensity of the received light, each optical pickup is sent to a desired recording track. And having a flop, and adjusting each of the optical characteristics of the optical pickup on the basis of the signal.
[0022]
The method for adjusting the optical pickup constituted by the steps described above can adjust the pair of optical pickups without stopping the rotation of the optical disc for adjustment of the optical pickup.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an optical disk for adjusting an optical pickup to which the present invention is applied, an adjustment device for an optical pickup using the adjustment optical disk, and a method for adjusting an optical pickup using the adjustment device will be described with reference to the drawings.
[0024]
First, as shown in FIG. 1, an adjustment optical disk 1 for an optical pickup is an adjustment optical disk used for adjusting a pair of optical pickups capable of reproducing a double-sided reproduction type DVD and has a thickness of 0.6 mm. A first disk substrate 2 having light transmittance and a second disk substrate 3 having light transmittance and having a thickness of 0.6 mm are also bonded to each other with an adhesive.
[0025]
The first disk substrate 2 is provided with a first signal recording layer 5 on the bonding surface side. The first signal recording layer 5 is used for adjusting one of the optical pickups, and is provided at a position 0.6 mm from the first signal reading surface 2a side. In the first signal recording layer 5, 8-16 modulated data has a track pitch of 0.74 μm and a pit length of 0.4 to 4 so that the DVD and laser light reflection conditions substantially match. It is recorded in a pit pattern of 1.87 μm. Here, the recording track T1 provided on the first signal recording layer 5 is formed in a spiral shape as viewed from the first signal reading surface 2a side, as shown in FIG. Note that a reflection film, a protection film, and the like are formed on the first signal recording layer 5.
[0026]
The second disk substrate 3 is provided with a second signal recording layer 7 on the bonding surface side. The second signal recording layer 7 is used for adjusting the other optical pickup, and is provided at a position 0.6 mm from the second signal reading surface 3a side. In the second signal recording layer 7, the data modulated by 8-16 is converted to data having a track pitch of 0.74 [mu] m and a pit length of 0.4 to 1.87 [mu] m so that the reflection condition substantially matches that of the DVD. It is recorded in a pit pattern. Here, as shown in FIG. 3, the recording track T2 provided on the second signal recording layer 7 has a direction opposite to the spiral direction of the recording track T1 when viewed from the second signal reading surface 3a side. In the form of a spiral (hereinafter referred to as an inverted spiral). Note that a reflective film, a protective film, and the like are formed on the second signal recording layer 7.
[0027]
As shown in FIG. 2, the direction of data spirally recorded on the first signal recording layer 5 on the first disk substrate 2 is from the inner peripheral side to the outer peripheral side. As shown in FIG. 3, on the second disk substrate 3, the direction of the data recorded in the reverse spiral form on the second signal recording layer 7 is from the outer peripheral side to the inner peripheral side. In other words, the adjustment optical disk 1 rotates in a predetermined direction for reproducing the first signal recording layer 5 on the first disk substrate 2, so that the second signal recording layer 7 on the second disk substrate 3 is rotated. The rotation direction is reversed with respect to a predetermined direction, but since the direction of the data is recorded in the reverse direction, the data recorded on the second signal recording layer 7 by the other optical pickup without stopping the rotation. Becomes readable.
[0028]
Here, the DVD uses the 8-16 modulation method. However, since the adjustment optical disk 1 is an adjustment optical disk for a pair of optical pickups, there is no need to basically demodulate data. The first signal recording layer 5 and / or the second signal recording layer 7 may record data modulated by 8-14 modulation like a CD. That is, in the adjustment optical disk 1, by using a modulation method with a small number of bits after modulation, that is, 8-14 modulation as the modulation method, processing such as demodulation processing can be reduced.
[0029]
The first signal recording layer 5 and the second signal recording layer 7 record data to which a Reed-Solomon Product Code (RS-PC: Reed Solomon Product Code) used in DVD is added as an error correction code. It is supposed to. Also, a cross interleaved Reed-Solomon Code (CIRC) may be added as an error correction code.
[0030]
By the way, as shown in FIG. 4, the adjustment optical disc 1 has an adjustment data recorded in the first signal recording layer 8 and the second signal recording layer 7 of the adjustment data recorded in the first signal recording layer 5. The data is provided so as to overlap with the second recording area 9. That is, in the adjustment optical disk 1, the first recording area 8 and the second recording area 9 can have the same tracking control of each objective lens in the pair of optical pickups. That is, when one optical pickup is on-track, the other optical pickup can also be on-track.
[0031]
As described above, the adjustment optical disc 1 is provided so that the first recording area 8 and the second recording area 9 are overlapped with each other, so that the other optical pickup performs the same tracking control as the one optical pickup. Accordingly, the other optical pickup can be turned on-track, and the adjustment of the pair of optical pickups can be performed efficiently.
[0032]
Further, the first recording area 8 and the second recording area 9 provided on the adjustment optical disk 1 may be provided so as not to overlap each other as shown in FIG.
[0033]
As described above, in the adjustment optical disc 1, the recording tracks T1 and T2 provided on the first signal recording layer 5 and the second signal recording layer 7, respectively, are provided in a spiral shape and an inverted spiral shape, respectively. Since the adjustment data is recorded on the signal recording layer 7 in the opposite direction to the first signal recording layer 5, that is, from the outer periphery to the inner periphery, the rotation of the adjustment optical disc 1 is continuously stopped without stopping the rotation of the adjustment optical disk 1. Thus, the pair of optical pickups can be adjusted.
[0034]
Next, the configuration of a pair of optical pickups that are adjusted using the above-described adjustment optical disc 1 will be described with reference to FIGS. This optical pickup can perform recording and / or reproduction of a DVD, for example.
[0035]
As shown in FIG. 6, the first optical pickup 11a is provided so as to face the first signal recording layer 5 of the above-described adjustment optical disc 1, and is recorded on a recording track of the first signal recording layer 5. Data to be played back. Further, the second optical pickup 11b is provided so as to face the second signal recording layer 7 of the above-mentioned adjustment optical disc 1, and reproduces data recorded on a recording track of the second signal recording layer 7. It has become.
[0036]
The first optical pickup 11a is mounted on a base 22a on which various control devices are mounted, and the second optical pickup 11b is mounted on a base 22b on which various control devices are mounted. The base 22a and the base 22b are connected and fixed via a base support member 22c.
[0037]
As shown in FIG. 7, the first optical pickup 11a includes a light source 12a such as a semiconductor laser that emits a light beam having a wavelength of 635 to 650 nm for DVD, and an optical disc for adjusting the light beam emitted from the light source 12a. An objective lens 13a for converging light on the first signal recording layer 5, a photodetector 14a for receiving a return light beam reflected by the first signal recording layer 5 of the adjustment optical disc 1, and a light source A beam splitter 15a that guides the light beam emitted from 12a to the objective lens 13a and guides a return light beam reflected by the adjustment optical disk 1 to the photodetector 14a, and drives the objective lens 13a in the focusing direction and the tracking direction. And an objective lens driving unit 16a that is displaced.
[0038]
As shown in FIG. 7, the second optical pickup 11b includes a light source 12b such as a semiconductor laser that emits a light beam having a wavelength of 635 to 650 nm for DVD and a light source 12b for adjusting the light beam emitted from the light source 12b. An objective lens 13b for condensing light on the second signal recording layer 7 of the optical disc 1; a photodetector 14b for receiving a return light beam reflected on the second signal recording layer 7 of the adjusting optical disc 1; A beam splitter 15b for guiding the light beam emitted from the light source 12b to the objective lens 13b and a return light beam reflected by the adjustment optical disk 1 to the photodetector 14b, and the objective lens 13b in the focusing direction and the tracking direction. And an objective lens driving section 16b that is driven and displaced.
[0039]
The objective lenses 13a and 13b are, for example, holograms formed integrally with the lenses. , And the second signal recording layer 7 is focused. The objective lenses 13a and 13b are held by lens holders 17a and 17b, respectively, and the lens holders 17a and 17b are respectively attached to the holder support members 18a and 18b via elastic support members. The lens holders 17a and 17b holding the objective lenses 13a and 13b are supported by the elastic support member, so that the focusing direction, which is the optical axis direction of the objective lenses 13a and 13b, is orthogonal to the optical axis direction of the objective lenses 13a and 13b. In such a state that it can be displaced in the tracking direction, it is supported by the holder supporting members 18a and 18b.
[0040]
The objective lens driving units 16a and 16b include a focusing driving unit that drives and displaces the objective lenses 13a and 13b in the focusing direction and a tracking driving unit that drives and displaces the objective lenses 13a and 13b in the tracking direction. The drive unit includes a coil attached to the lens holders 17a and 17b and a magnet attached to the holder support members 18a and 18b. Each drive unit drives and displaces the objective lenses 13a and 13b held in the lens holders 17a and 17b in the focusing direction and the tracking direction by the action of the current flowing through the coil and the magnetic field generated by the magnet. Thus, the light beams emitted from the light sources 12a and 12b are scanned by the objective lens driving units 16a and 16b and the like, and focused on the first signal recording layer 5 and the second signal recording layer 7 of the adjustment optical disc 1, respectively. Then, by detecting the return light beams reflected by the first signal recording layer 5 and the second signal recording layer 7 by the photodetectors 14a and 14b, respectively, the information signal can be read reliably. Become like
[0041]
The first optical pickup 11a configured as described above is further attached to a first base unit 21a to be mounted on a recording and / or reproducing device, as shown in FIG. The first base unit 21a has a base 22a assembled to a housing of a recording and / or reproducing apparatus. The base 22a has a slide member 23a to which the first optical pickup 11a is assembled, and a first optical unit. A feed mechanism 24a that feeds the slide member 23a to which the pickup 11a is assembled in a radial direction of the optical disk, and a disk rotation drive mechanism 25 that drives the optical disk to rotate are provided.
[0042]
Further, the second optical pickup 11b configured as described above is further attached to a second base unit 21b to be mounted on a recording and / or reproducing device, as shown in FIG. The second base unit 21b has a base 22b assembled to a casing of the recording and / or reproducing apparatus. The base 22b has a slide member 23b to which the second optical pickup 11b is assembled, and a first light. A feed mechanism 24b for feeding the slide member 23b with the pickup 11a mounted thereto in the radial direction of the optical disk is provided.
[0043]
The first and second optical pickups 11a and 11b are attached to the slide members 23a and 24b, respectively, and are respectively provided in openings 28a and 28b provided along the radial direction of the optical disk of the bases 22a and 22b. Will be arranged. For the slide members 23a and 23b, for example, positioning pins on the slide members 23a and 23b are engaged with positioning holes provided in the holder support members 18a and 18b, and the first optical pickup 11a and the second optical pickup 11a are bonded by an adhesive. The holder supporting members 18a and 18b constituting the optical pickup 11b are fixed in a state where they are positioned with high precision.
[0044]
The feed mechanisms 24a and 24b include, for example, drive motors 26a and 26b attached to the bases 22a and 22b, respectively, and feed screws 27a and 27b connected to the drive motors 26a and 26b via a plurality of gear trains. The feed screws 27a and 27b are rotatably attached to the bases 22a and 22b along the moving direction of the first optical pickup 11a and the second optical pickup 11b, that is, along the radial direction of the optical disk. The engagement protrusions of the slide members 23a and 23b to which the first optical pickup 11a and the second optical pickup 11b are attached are engaged with screw grooves provided on the peripheral surfaces of the feed screws 27a and 27b. . As a result, the slide members 23a and 23b to which the first optical pickup 11a and the second optical pickup 11b are attached are rotated by the drive motors 26a and 26b, respectively, so that the diameter of the optical disc is increased. Move in the direction.
[0045]
As shown in FIG. 6, the disk rotation drive mechanism 25 includes a drive motor 29 disposed on the back side of the base 22a on which the first optical pickup 11a is mounted, and a drive shaft mounted on the drive motor 29. And a disk table 30. The disk table 30 centers the adjustment optical disk 1 by engaging with the center hole of the adjustment optical disk 1 and integrally rotates the adjustment optical disk 1. The drive motor 29 rotates the adjustment optical disc 1 during reproduction of the adjustment optical disc 1 so that the linear velocity becomes, for example, 3.49 m / sec specified by the DVD standard.
[0046]
As shown in FIG. 6, the base 22a of the first base unit 21a to which the first optical pickup 11a is attached and the base 22b of the second base unit 21b to which the second optical pickup 11b is attached are as follows. , Are fixed via a base holding member 22c.
[0047]
By the way, as shown in FIG. 6, the adjusting device 41 for adjusting the first optical pickup 11a and the second optical pickup 11b assembled to the first base unit 21a and the second base unit 21b supports the base. The first base unit 21a in which the first optical pickup 11a is assembled to the member 22c and the second base unit 21b in which the second optical pickup 11b is assembled are held while being positioned. As shown in FIG. 7, the adjusting device 41 holds the holder supporting members 18a and 18b of the first optical pickup 11a and the second optical pickup 11b, and adjusts the positions of the objective lenses 13a and 13b. The adjusting mechanisms 42a and 42b, the base holding mechanisms 43a and 43b that hold the bases 22a and 22b, the slide member holding mechanisms 44a and 44b that hold the slide members 23a and 23b, and the light sources 12a and 12b that hold the light sources 12a and 12b. Light source adjusting mechanisms 45a and 45b for adjusting the position of 12b, light detector adjusting mechanisms 46a and 46b for holding the light detectors 14a and 14b and adjusting the positions of the light detectors 14a and 14b, and light sources 12a and 12b. A detection mechanism (not shown) for detecting the optical characteristics of the emitted light beam.
[0048]
The base support member 22c that holds the first base unit 21a and the second base unit 21b has a plurality of standing shafts for positioning the bases 22a and 22b, and these positioning shafts are provided on the bases 22a and 22b. By engaging the positioning holes, the bases 22a and 22b are held in a positioned state.
[0049]
The objective lens adjusting mechanisms 42a and 42b have a pair of holding arms for holding the holder supporting members 18a and 18b, and when adjusting, hold the holder supporting members 18a and 18b with the pair of holding arms. The pair of holding arms holding the holder support members 18a and 18b hold the holder support members 18a and 18b in a radial direction (X direction) parallel to the radial direction of the adjustment optical disk 1 and the adjustment optical disk 1 respectively. Are moved in parallel in the tangential direction (Y direction) orthogonal to the radial direction. The pair of holding arms hold the holder supporting members 18a and 18b, and radially skew the objective lenses 13a and 13b in the radial direction with respect to the optical axis and move the objective lenses 13a and 13b with respect to the optical axis. Adjust the tangential skew to tilt in the tangential direction. The pair of holding arms move the objective lenses 13a and 13b in the optical axis direction in order to adjust the optical path length between the light sources 12a and 12b and the adjustment optical disk 1. Thus, the holder supporting members 18a and 18b are moved by the pair of holding arms in a plane direction parallel to the adjustment optical disk 1, the optical axis direction of the objective lenses 13a and 13b orthogonal to the plane, and furthermore, the inclination of the objective lenses 13a and 13b. Is adjusted with high accuracy. At this time, the holder support members 18a and 18b are slightly floated with respect to the slide members 23a and 23b, and the adhesive is filled in a gap formed between the slide members 23a and 23b and the holder support members 18a and 18b. By being filled, it is fixed in a state where it is positioned with high precision with respect to the slide members 23a and 23b.
[0050]
The base holding mechanisms 43a and 43b have a pair of holding arms for holding feed screws 27a and 27b constituting feed mechanisms 24a and 24b provided on the bases 22a and 22b. When the first optical pickup 11a and the second optical pickup 11b are adjusted, the pair of holding arms hold both ends of the feed screws 27a and 27b so that the feed screws 27a and 27b do not bend and deform. The adjustment positions of the optical pickup 11a and the second optical pickup 11b do not shift.
[0051]
The slide member holding mechanisms 44a and 44b have a plurality of positioning pins for preventing the slide members 23a and 23b from moving along the feed screws 27a and 27b, and include a first optical pickup 11a and a second optical pickup. When the pickup 11b is adjusted, these positioning pins engage with positioning holes provided in the slide members 23a and 23b, thereby positioning the slide members 23a and 23b at a predetermined position in the radial direction of the adjustment optical disc 1 with high accuracy. Hold it in the state.
[0052]
The light source adjusting mechanisms 45a and 45b have light source holding arms for holding the light sources 12a and 12b disposed in the first optical pickup 11a and the second optical pickup 11b. The light source holding arm holds the light sources 12a and 12b in a positioned state when adjusting the first optical pickup 11a and the second optical pickup 11b, and the center of the light sources 12a and 12b is on the optical axis of the objective lenses 13a and 13b. Move to match the fixed point of. The light source holding arm rotates the light sources 12a and 12b about the light emitting points of the light sources 12a and 12b. Further, the light source holding arm moves in the optical axis direction of the objective lenses 13a and 13b in order to adjust the optical path length between the light sources 12a and 12b and the optical disc 1 for adjustment.
[0053]
Each of the photodetector adjustment mechanisms 46a and 46b has a photodetector holding arm that holds the photodetectors 14a and 14b provided in the first optical pickup 11a. The photodetector holding arm holds the photodetectors 14a and 14b in a positioned state when adjusting the first optical pickup 11a and the second optical pickup 11b, and the center of the photodetectors 14a and 14b is the objective lens 13a. , 13b so as to coincide with the fixed point on the optical axis. The light detector holding arm rotates the light detectors 14a and 14b. Further, the photodetector holding arm moves the photodetectors 14a and 14b in the optical axis direction to adjust the optical path length.
[0054]
The detection mechanism has a CCD (Charge-Coupled Devices) camera (not shown) for detecting light beams emitted from the objective lenses 13a and 13b, and a coma aberration determination unit (not shown) for detecting coma. The CCD camera is positioned on the optical axis of the objective lenses 13a and 13b by a moving mechanism, detects a light beam, and outputs a detection result to a coma aberration determination unit. Then, the coma aberration determination unit detects the minimum value of the coma aberration.
[0055]
As shown in FIG. 10, the adjustment device 41 includes a signal detection unit 51 that detects each reproduction signal output from the photodetectors 14 a and 14 b of each optical pickup, and a signal detection unit 51 that detects the reproduction signal. A display unit 52 for displaying the read signal, a drive control unit 53 for controlling the drive motor 29 constituting the disk rotation drive mechanism 25, and feed mechanisms 24a and 24b for the first optical pickup 11a and the second optical pickup 11b. It comprises drive control units 54a and 54b for controlling the constituent drive motors 26a and 26b, output control units 55a and 55b for controlling the light beam outputs of the light sources 12a and 12b, and a controller 56 for controlling the overall operation. I have. The controller 56 controls the drive control units 53, 54a, 54b, the output control units 55a, 55b, and the objective lens adjustment mechanisms 42a, 42b based on the determination result from the coma aberration determination unit and the input from the signal detection unit 51. And the light source adjustment mechanisms 45a and 45b, the photodetector adjustment mechanisms 46a and 46b, and the like.
[0056]
Furthermore, the adjusting device 41 includes a demodulation unit 57 that demodulates the signal detected by the signal detection unit 51, and an error correction processing unit 58 that performs an error correction process on the demodulated data. The adjustment optical disk 1 shown in FIGS. 1, 4 and 5 is used for the adjustment device 41. The adjustment optical disk 1 includes a first signal recording layer 5 and a second signal recording layer 7. In the 8-16 modulation method, adjustment data to which RS-PC is added as an error correction code is recorded. That is, the first signal recording layer 5 and the second signal recording layer 7 record data modulated by the same modulation method and subjected to the same method of error correction coding. Therefore, the demodulation unit 57 performs demodulation processing on the 8-16 modulated data read from the first signal recording layer 5 and the second signal recording layer 7, and the error correction processing unit 58 performs demodulation. Error correction processing is performed based on the RS-PC of the received data. Then, for example, the error correction processing unit 58 outputs the error rate to an inspection device or the like for inspecting the error rate.
[0057]
The relative positions of the light sources 12a and 12b and the objective lenses 13a and 13b of the first optical pickup 11a and the second optical pickup 11b using the adjusting device 41 and the adjusting optical disk 1 configured as described above, and the objective. A method for adjusting the positions and inclinations of the lenses 13a and 13b with respect to the optical axis will be described.
[0058]
First, the first base unit 21a and the second base unit 21b are installed on the base support member 22c, respectively. At this time, the first base unit 21a and the second base unit 21b are accurately positioned on the base support member 22c by the positioning shafts being engaged with the positioning holes provided in the bases 22a and 22b. Held in state. The slide member holding mechanisms 44a and 44b move the slide members 23a and 23b to predetermined positions in the radial direction of the optical disc 1 for adjustment by engaging the positioning pins with the positioning holes provided in the slide members 23a and 23b. Hold with high precision positioning. Further, the base holding mechanisms 43a and 43b hold the feed screws 27a and 27b with a pair of holding arms so as not to rotate, so that the first optical pickup 11a and the second optical pickup 11b do not deviate from the adjustment positions. ing. In the adjusting device 41, the first optical pickup 11a and the second optical pickup 11b are mounted on slide members 23a and 23b movably mounted on bases 22a and 22b via feed screws 27a and 27b. Placed and combined.
[0059]
The holder support members 18a and 18b of the first optical pickup 11a and the second optical pickup 11b mounted on the slide members 23a and 23b are held by a pair of holding arms of the objective lens adjustment mechanisms 42 and 42b. Thereby, the positions of the objective lenses 13a and 13b are three-dimensionally positioned with respect to the slide members 23a and 23b. The light sources 12a and 12b are held by light source holding arms constituting light source adjusting mechanisms 45a and 45b, and the light detectors 14a and 14b are attached to light detector holding arms constituting light receiving unit holding mechanisms 46a and 46b. Will be retained.
[0060]
Then, the adjusting device 41 first adjusts the position of the light source 12a of the first optical pickup 11a and the objective lens 13a. That is, as shown in FIG. 11, in step S1, the controller 56 controls the output control unit 55a so that the light source 12a emits a light beam having a wavelength for DVD of 635 to 650 nm. As a result, a light beam having a wavelength of 635-650 nm for DVD is emitted from the light source 12a. At this time, the adjusting optical disk 1 is not mounted on the disk table 30 constituting the disk rotation driving mechanism 25.
[0061]
In step S2, the controller 56 performs adjustment of the objective lens 13a with respect to the light source 12a, that is, adjustment of adjusting the position of the objective lens 13a to the designed optical axis. Specifically, the objective lens adjusting mechanism 42a holding the holder supporting member 18a drives and controls the holding arm holding the holder supporting member 18a under the control of the controller 56, thereby moving the objective lens 13a in the radial direction (X Direction) and the tangential direction (Y direction), and the light source adjusting mechanism 45a holding the light source 12a moves so that the center of the light source 12a coincides with a fixed point on the optical axis of the objective lens 13a. . Thus, the adjusting device 41 moves the positions of the light source 12a and the objective lens 13a, and adjusts the position of the objective lens 13a to the designed optical axis.
[0062]
In step S3, the controller 56 performs processing for minimizing coma. That is, the objective lens adjusting mechanism 42a controls the radial skew of the objective lens 13a and the tangential skew of the objective lens 13a by controlling the driving of the holding arm holding the holder supporting member 18a based on the control of the controller 56. The coma is minimized by adjusting the inclination of the objective lens 13a with respect to the optical axis. That is, a detection mechanism (not shown) detects a light beam condensed by the objective lens 13a by a CCD camera or the like, determines coma by a coma aberration determination section, and controls the objective lens adjustment mechanism 42a based on the determination. Is controlled so that is minimized. When detecting the minimum value of the coma aberration, the controller 56 drives the objective lens adjusting mechanism 42a so as to maintain the position of the objective lens 13a in which the coma aberration is minimized.
[0063]
Thus, the first optical pickup 11a is adjusted so that the position of the objective lens 13a coincides with the designed optical axis, and the tilt of the objective lens 13a is adjusted so that coma aberration is minimized. The relative position between the objective lens 12a and the objective lens 13a is adjusted.
[0064]
Next, the adjusting device 41 adjusts the position between the light source 12b of the second optical pickup 11b and the objective lens 13b. That is, in step S4, the controller 56 controls the output control unit 55b such that the light source 12b emits a light beam having a wavelength for DVD of 635 to 650 nm. As a result, a light beam having a wavelength of 635-650 nm for DVD is emitted from the light source 12b. At this time, the adjusting optical disk 1 is not mounted on the disk table 30 constituting the disk rotation driving mechanism 25.
[0065]
In step S5, the controller 56 adjusts the objective lens 13b with respect to the light source 12b, that is, adjusts the position of the objective lens 13b to match the designed optical axis. Specifically, the objective lens adjusting mechanism 42b holding the holder support member 18b drives and controls the holding arm holding the holder support member 18b based on the control of the controller 56 to move the objective lens 13b in the radial direction (X Direction) and the tangential direction (Y direction), and the light source adjustment mechanism 45b holding the light source 12b moves so that the center of the light source 12b coincides with a fixed point on the optical axis of the objective lens 13b. . Thus, the adjustment device 41 moves the positions of the light source 12b and the objective lens 13b, and adjusts the position of the objective lens 13b to the designed optical axis.
[0066]
In step S6, the controller 56 performs processing for minimizing coma. That is, the objective lens adjusting mechanism 42b controls the radial skew of the objective lens 13b and the tangential skew of the objective lens 13b by controlling the driving of the holding arm holding the holder supporting member 18b based on the control of the controller 56. The coma is minimized by adjusting the inclination of the objective lens 13b with respect to the optical axis. That is, a detection mechanism (not shown) detects a light beam condensed by the objective lens 13b by a CCD camera or the like, determines coma by a coma aberration determination unit, and controls the objective lens adjustment mechanism 42b based on the determination. Is controlled so that is minimized. Then, when detecting the minimum value of the coma aberration, the controller 56 drives the objective lens adjusting mechanism 42b so as to maintain the position of the objective lens 13b in which the coma aberration is minimized.
[0067]
Thus, the second optical pickup 11b is adjusted so that the position of the objective lens 13b coincides with the designed optical axis, and the inclination of the objective lens 13b is adjusted so that coma aberration is minimized. Adjustment of the relative position between 12b and the objective lens 13b is performed.
[0068]
In step S7, the adjustment optical disk 1 is mounted on the disk table 30 constituting the disk rotation drive mechanism 25 provided on the base 22a provided on the base support member 22c, and drive control is performed based on the control of the controller 56. The unit 53 drives the drive motor 29 so that the linear velocity when the adjustment optical disk 1 rotates in a predetermined direction becomes, for example, 3.49 m / sec specified by the DVD standard. Here, as shown in FIGS. 1, 4 and 5, the adjustment optical disk 1 mounted on the disk table 30 includes a first signal recording layer 5 for adjusting the first optical pickup 11a and a second signal recording layer 5 for adjusting the first optical pickup 11a. A second signal recording layer 7 for adjusting the second optical pickup 11b is provided, and spiral recording tracks and inverted spiral recording tracks are respectively provided on the signal recording layers 5 and 7. Then, in the adjustment optical disc 1 shown in FIG. 4, the first recording area 8 provided in the first signal recording layer 5 and the second recording area 9 provided in the second signal recording area 7 The adjustment optical disc 1 shown in FIG. 5 is provided so as to overlap with the first recording area 8 provided in the first signal recording layer 5 and the second recording area provided in the second signal recording area 7. 9 are provided so as not to overlap. The adjustment data recorded on the first signal recording layer 5 and the second signal recording layer 7 is recorded as 8-16 modulated data.
[0069]
Next, in step S8, the adjustment of the first optical pickup 11a will be described. First, when the adjustment optical disk 1 shown in FIG. 1, FIG. 4 or FIG. The optical pickup 11a is fed to the position of the first recording area 8 of the first signal recording layer 5. That is, the controller 56 drives the drive motor 26 by the drive control unit 54, and moves the first optical pickup 11a to a readable position of the first recording area 8.
[0070]
The controller 56 controls the output control unit 55a so that the light source 12a emits a light beam having a wavelength of 635 to 650 nm. As a result, a light beam having a wavelength of 635 to 650 nm for DVD is emitted from the light source 12a, and the photodetector 14a generates a return light beam reflected by the first signal recording layer 5 of the adjustment optical disk 1. To detect.
[0071]
In step S9, the adjusting device 41 performs a coarse adjustment for adjusting the position of the photodetector 14a to the designed optical axis position. At this time, the controller 56 controls the objective lens driving unit 16a so that the focusing control and the tracking control are turned off. In this state, the light detector adjustment mechanism 46a holding the light detector 14a moves the light detector holding arm holding the light detector 14a under the control of the controller 56, and Rough adjustment is performed to match the position of 14a with the position of the designed optical axis.
[0072]
In step S10, the adjustment device 41 performs a coarse adjustment for optimizing the optical path length from the light source 12a, that is, the light emitting point of the light beam to the adjustment optical disk 1. At this time, the controller 56 turns on the focusing control and turns off the tracking control so that the objective lens driving unit 16a focuses on the first signal recording layer 5. The focusing control is performed by, for example, an astigmatism method. The controller 56 controls the objective lens adjustment mechanism 42a holding the objective lens 13a, the light source adjustment mechanism 45a holding the light source 12a, and the light detector adjustment mechanism 46a holding the light detector 14a. By performing control, coarse adjustment for optimizing the optical path length from the light emitting point of the light beam to the adjustment optical disk 1 is performed.
[0073]
In step S11, the adjustment device 41 performs fine adjustment for adjusting the position of the photodetector 14a to the position of the designed optical axis. At this time, the controller 56 turns on both the focusing control and the tracking control so that the objective lens driving unit 16a can scan the spiral recording track with the light beam focused on the first signal recording layer 5. Control. Note that tracking control is performed by, for example, a push-pull method, a differential phase detection (DPD) method, or the like. In this state, the light detector adjustment mechanism 46a holding the light detector 14a moves the light detector holding arm holding the light detector 14a under the control of the controller 56, and Fine adjustment is performed to adjust the position of 14a to the position of the optical axis in design.
[0074]
In step S12, the adjusting device 41 performs fine adjustment for optimizing the optical path length from the light source 12a, that is, the light emitting point of the light beam to the optical disc 1 for adjustment. At this time, the controller 56 turns on both the focusing control and the tracking control so that the objective lens driving unit 16a can scan the spiral recording track with the light beam focused on the first signal recording layer 5. Control. The controller 56 controls the objective lens adjustment mechanism 42a holding the objective lens 13a, the light source adjustment mechanism 45a holding the light source 12a, and the light detector adjustment mechanism 46a holding the light detector 14a. By performing control, fine adjustment for optimizing the optical path length from the light emitting point of the light beam to the adjustment optical disk 1 is performed.
[0075]
Next, the adjusting device 41 performs skew adjustment. Here, the skew adjustment is performed so as to satisfy the tilt tolerance of the DVD.
[0076]
Then, in step S13, the controller 56 drives the objective lens adjustment mechanism 42b such that the jitter value generated by the signal detection unit 51 is minimized.
[0077]
In step S14, the adjustment device 41 checks the optical characteristics of the first optical pickup 11a during DVD reproduction. For example, the adjustment device 41 outputs the RF signal generated by the signal detection unit 51 based on the output from the photodetector 14a that detects the return light beam reflected by the first signal recording layer 5 so that the RF signal has an optimum value. The controller 55a is controlled to check the adjustment of the output level of the light source 12a.
[0078]
After that, the adjustment device 41 that has completed the optical adjustment of the first optical pickup 11a performs, for example, an error rate inspection of the first optical pickup 11a.
[0079]
Next, the adjusting device 41 adjusts the second optical pickup 11b that reproduces the second signal recording layer 7. Here, the adjustment optical disk 1 shown in FIG. 4, that is, the first recording area 8 of the first signal recording layer 5 and the second recording area 9 of the second signal recording layer 7 overlap on the disk table 30. When the loaded optical disk is loaded, in step S15, the controller 56 switches to stop emitting the light from the light source 12a of the first optical pickup 11a and emit the light beam from the light source 12b of the second optical pickup 11b. I do. That is, the output control unit 55b controls the light source 12b to emit a light beam of 635 to 650 nm for DVD. Then, the photodetector 14b receives the return light beam reflected by the second signal recording layer 7 of the adjustment optical disk 1. When the adjustment optical disk 1 is mounted on the disk table 30, the second optical pickup 11b mounted on the slide member 23b is not fed.
[0080]
Further, the adjustment optical disk 1 shown in FIG. 5, that is, the first recording area 8 of the first signal recording layer 5 and the second recording area 9 of the second signal recording layer 7 do not overlap on the disk table 30. When the provided optical disc is mounted, the slide member 23b incorporating the second optical pickup 11b is fed in the radial direction of the adjustment optical disc 1 to a position where the first recording area 8 can be read. . Thereafter, the controller 56 switches to stop emitting light from the light source 12a of the first optical pickup 11a and emit light beam from the light source 12b of the second optical pickup 11b. That is, the output control unit 55b controls the light source 12b to emit a light beam of 635 to 650 nm for DVD. Then, the photodetector 14b receives the return light beam reflected by the second signal recording layer 7 of the adjustment optical disk 1.
[0081]
In step S16, the adjustment device 41 performs a coarse adjustment for adjusting the position of the photodetector 14b to the position of the designed optical axis. At this time, the controller 56 controls the objective lens driving unit 16b so that the focusing control and the tracking control are turned off. In this state, the photodetector adjustment mechanism 46b holding the photodetector 14b moves the photodetector holding arm holding the photodetector 14b under the control of the controller 56, and Rough adjustment is performed to adjust the position of 14b to the position of the optical axis in design.
[0082]
In step S17, the adjustment device 41 performs a rough adjustment for optimizing the optical path length from the light source 12b, that is, the light emitting point of the light beam to the adjustment optical disk 1. At this time, the controller 56 turns on the focusing control and turns off the tracking control to focus the objective lens driving unit 16b on the second signal recording layer 7. The focusing control is performed by, for example, an astigmatism method. The controller 56 controls the objective lens adjusting mechanism 42b holding the objective lens 13b, the light source adjusting mechanism 45b holding the light source 12b, and the light detector adjusting mechanism 46b holding the light detector 14b. By performing control, coarse adjustment for optimizing the optical path length from the light emitting point of the light beam to the adjustment optical disk 1 is performed.
[0083]
In step S18, the adjustment device 41 performs fine adjustment to adjust the position of the photodetector 14b to the position of the designed optical axis. At this time, the controller 56 turns on both the focusing control and the tracking control so that the objective lens driving unit 16b can scan the reverse spiral recording track with the light beam focused on the second signal recording layer 7. Control. The tracking control is performed by, for example, a push-pull method or a DPD method. In this state, the photodetector adjustment mechanism 46b holding the photodetector 14b moves the photodetector holding arm holding the photodetector 14b under the control of the controller 56, and Fine adjustment is performed to adjust the position of 14b to the position of the optical axis in design.
[0084]
In step S19, the adjustment device 41 performs fine adjustment to adjust the position of the photodetector 14b to the position of the designed optical axis. At this time, the controller 56 turns on both the focusing control and the tracking control so that the objective lens driving unit 16b can scan the reverse spiral recording track with the light beam focused on the second signal recording layer 7. Control. The controller 56 controls the objective lens adjusting mechanism 42b holding the objective lens 13b, the light source adjusting mechanism 45b holding the light source 12b, and the light detector adjusting mechanism 46b holding the light detector 14b. By performing control, fine adjustment for optimizing the optical path length from the light emitting point of the light beam to the adjustment optical disk 1 is performed.
[0085]
Next, the adjusting device 41 performs skew adjustment. Here, the skew adjustment is performed so as to satisfy the tilt tolerance of the DVD.
[0086]
The controller 56 controls the slider holding mechanism 44b to feed the slide member 23b incorporating the second optical pickup 11b in the radial direction of the adjustment optical disk 1 to a position where the second recording area 9 can be read. I do.
[0087]
Then, in step S20, the controller 56 drives the objective lens adjustment mechanism 42b such that the jitter value generated by the signal detection unit 51 is minimized.
[0088]
In step S21, the adjustment device 41 checks the optical characteristics of the second optical pickup 11b during DVD reproduction. For example, the adjustment device 41 outputs the RF signal generated by the signal detection unit 51 based on the output from the photodetector 14b that has detected the return light beam reflected by the second signal recording layer 7 so that the RF signal has an optimum value. The controller 55b is controlled to check the adjustment of the output level of the light source 12b.
[0089]
After that, the adjustment device 41 that has completed the optical adjustment of the second optical pickup 11b performs, for example, an error rate inspection of the second optical pickup 11b.
[0090]
Thus, the first optical pickup 11a and the second optical pickup 11b for which the adjustment of the optical characteristics has been completed are fixed to the slide members 23a and 23b with an adhesive, respectively, and mounted on the recording and / or reproducing apparatus for the optical disk.
[0091]
As described above, the first optical pickup 11a and the second optical pickup 11b are adjusted in such a manner that data is recorded in the signal recording layers 5 and 7 in a spiral shape and a reverse spiral shape, respectively, and in opposite directions. By using the optical disc 1, the adjustment can be performed smoothly without stopping the rotation of the adjusting optical disc as in the related art.
[0092]
Further, the adjusting optical disc 1 shown in FIG. 4, that is, the adjusting optical disc 1 in which the first recording area 8 of the first signal recording layer 5 and the second recording area 9 of the second signal recording layer 7 overlap. Is mounted, when switching between the adjustment of the first optical pickup 11a and the adjustment of the second optical pickup 11b, the first optical pickup 11a and the second optical pickup 11b are synchronously controlled in tracking. Accordingly, the second optical pickup 11b can be switched smoothly because it is already on-track.
[0093]
In the above description, the first optical pickup 11a is adjusted, and then the second optical pickup 11b is adjusted without stopping the rotation of the adjustment optical disc 1. However, the first optical pickup 11a and the second optical pickup 11b are adjusted. The two optical pickups 11b may be adjusted simultaneously. At this time, data must be recorded on the recording track of the second signal recording layer 7 from the inner peripheral side to the outer peripheral side of the adjustment optical disk 1.
[0094]
In this case, it is necessary to process each output from the light detection units 14a and 14b individually so that the controller 56 can simultaneously control the first optical pickup 11a and the second optical pickup 11b. There is. In this case, a signal detection unit and the like are provided corresponding to the first optical pickup 11a and the second optical pickup 11b.
[0095]
As described above, when the first optical pickup 11a and the second optical pickup 11b can be adjusted at the same time, the adjustment time can be further shortened. Adjustment of the pickup can be performed.
[0096]
Note that the adjustment of the first optical pickup 11a in steps S8 to S14 and the adjustment of the second optical pickup 11b in steps S15 to S19 are not limited to the example illustrated in FIG. The order of adjustment between the first optical pickup 11a and the second optical pickup 11b may be switched.
[0097]
Further, when the first optical pickup 11a and the second optical pickup 11b are constituted by laser couplers, since the components other than the objective lenses 13a and 13b are integrated, the coma aberration in steps S1 to S6 is increased. After the adjustment of (1), the adjustment performed in at least steps S8 to S12 and steps S15 to S19 may be omitted. That is, when the first optical pickup 11a and the second optical pickup 11b are constituted by laser couplers, it is only necessary to adjust the positions of the objective lenses 13a and 13b.
[0098]
【The invention's effect】
According to the present invention, both sides are signal recording surfaces, recording tracks are spirally provided on one signal recording surface, and recording tracks are spirally formed on the other signal recording surface in a direction opposite to that of one signal recording surface. And a laser beam is applied to each signal recording layer from each side, so that a set of light beams is continuously output without stopping the rotation of the adjusting optical disk as in the conventional case. The adjustment of the pickup can be performed, and the adjustment process of a set of optical pickups can be sped up.
[Brief description of the drawings]
FIG. 1 is a perspective view of an optical disc for adjusting an optical pickup to which the present invention is applied.
FIG. 2 is a diagram illustrating a first signal recording layer viewed from a first disk substrate side.
FIG. 3 is a diagram illustrating a second signal recording layer viewed from a second disk substrate side.
FIG. 4 is a cross-sectional view of an adjustment optical disk provided so that a first recording area of a first signal recording layer and a second recording area of a second signal recording layer overlap.
FIG. 5 is a cross-sectional view of an adjustment optical disk provided so that a first recording area of a first signal recording layer and a second recording area of a second signal recording layer do not overlap.
FIG. 6 is a diagram illustrating a configuration of an optical pickup adjustment device.
FIG. 7 is a diagram illustrating a configuration of a first optical pickup and a second optical pickup.
FIG. 8 is a diagram illustrating a configuration of a first base unit.
FIG. 9 is a diagram illustrating a configuration of a second base unit.
FIG. 10 is a diagram illustrating signal processing and control of each mechanism in the adjustment device of the optical pickup.
FIG. 11 is a flowchart illustrating a method for adjusting an optical pickup.
[Explanation of symbols]
Reference Signs List 1 adjustment optical disk, 2 first disk substrate, 3 second disk substrate, 4 adhesive, 5 first signal recording layer, 7 second signal recording layer, 8 first recording area, 9 second Recording area, 11a First optical pickup, 11b Second optical pickup, 12a, 12b Light source, 13a, 13b Objective lens, 14a, 14b Photodetector, 15a, 15b Beam splitter, 16a, 16b Objective lens drive unit, 17a , 17b lens holder, 18a, 18b holder support member, 21a first base unit, 21b second base unit, 22a, 22b base, 23a, 23b slide member, 24a, 24b feed mechanism, 25 disk rotation drive mechanism, 26 Drive motor, 27a, 27b feed screw, 28 opening, 29 drive motor, 30 disk table, 41 Adjustment device, 42a, 42b Objective lens adjustment mechanism, 43a, 43b Base holding mechanism, 44a, 44b Slide member holding mechanism, 45a, 45b Light source adjustment mechanism, 46a, 46b Photodetector adjustment mechanism, 51 Signal detection section, 52 Display section , 53 drive control unit, 54a, 54b drive control unit, 55a, 55b output control unit, 56 controller, 57 demodulation unit, 58 error correction processing unit

Claims (8)

Both sides are signal recording surfaces, recording tracks are provided spirally on one signal recording surface, and recording tracks are provided spirally in the opposite direction to the one signal recording surface on the other signal recording surface. An optical disc for adjusting an optical pickup in which each signal recording surface is irradiated with laser light from each surface side. On the recording track provided on the one signal recording surface, data is sequentially recorded from one side of the inner or outer circumference to the other side, while the recording track provided on the other signal recording surface is provided. 2. The optical disc for adjusting an optical pickup according to claim 1, wherein data is sequentially recorded from said other side to said one side. Both sides are signal recording surfaces, recording tracks are provided spirally on one signal recording surface, and recording tracks are provided spirally in the opposite direction to the one signal recording surface on the other signal recording surface. An optical disc for adjustment in which each signal recording surface is irradiated with laser light from each surface side,
Rotation driving means for driving the adjustment optical disc to rotate,
A laser beam is emitted from a light source, the laser beam is condensed on a corresponding signal recording surface of the optical disc for adjustment by a condenser lens, and a return light reflected by the optical disc for adjustment is received by a light receiving portion to receive light intensity. Sending means for sending a pair of optical pickups facing each other that respectively output signals according to the radial direction of the adjusting optical disc,
An adjustment device for an optical pickup, comprising: an adjustment unit that adjusts optical characteristics of the optical pickup based on a signal that the light receiving unit receives a return light from the adjustment optical disk and outputs the light according to a received light intensity. The optical disc for adjustment is provided on the other signal recording surface while data is sequentially recorded on the recording track provided on the one signal recording surface from one side of the inner or outer circumference to the other side. 4. The optical pickup adjusting apparatus according to claim 3, wherein data is sequentially recorded on the recording track from the other side to the one side. Each of the optical pickups simultaneously focuses laser light emitted from the light source on the corresponding signal recording surface of the adjustment optical disc by the condenser lens, and returns light from the adjustment optical disc by the light receiving unit. When receiving light,
5. The optical pickup adjusting device according to claim 4, wherein said adjusting means simultaneously adjusts the optical characteristics of each of said optical pickup units based on a signal output by said light receiving unit of each of said optical pickups in accordance with a received light intensity. Both sides are signal recording surfaces, recording tracks are provided spirally on one signal recording surface, and recording tracks are provided spirally in the opposite direction to the one signal recording surface on the other signal recording surface. Rotating an adjustment optical disc that is irradiated with laser light from each surface side for each signal recording surface; and
A pair of optical pickups facing each other corresponding to each signal recording surface of the adjustment optical disk emit laser light from a light source, and apply a laser beam to each corresponding signal recording surface of the adjustment optical disk by a condenser lens. Focusing light;
Based on a signal that receives the return light from the adjusting optical disc by a light receiving unit of each of the optical pickups and outputs the light according to the intensity of received light, the operation of sending each of the optical pickups to a desired recording track;
Adjusting the optical characteristics of each of the optical pickups based on the signal. The optical disc for adjustment is provided on the other signal recording surface while data is sequentially recorded on the recording track provided on the one signal recording surface from one side of the inner or outer circumference to the other side. 7. The method according to claim 6, wherein data is sequentially recorded from the other side to the one side on the recorded recording track. In the step of condensing the laser light, the laser light emitted from the light source of each of the optical pickups is simultaneously condensed on each signal recording surface of the corresponding optical disc for adjustment by a condensing lens,
The step of adjusting the optical characteristics includes simultaneously adjusting the optical characteristics of each of the optical pickups based on the signals output by the light receiving units and returned according to the received light intensity, respectively, from the adjustment optical disk. Item 8. The method for adjusting an optical pickup according to Item 7.

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