KR20030075753A - Compatible optical pickup - Google Patents

Abstract

PURPOSE: A compatible optical pickup is provided to compensate a coma aberration by a transparent plate member, and to make thickness of a plate type beam splitter and the plate member thinner to receive optical spots suitable for optical detectors, thereby exactly reproducing a signal of an optical disk. CONSTITUTION: A light source(11) emits the first and the second lights(11a,11b) having different wavelength suitable for the first and the second optical disks(10a,10b) having different thickness. A plate type beam splitter(14) converts ongoing paths of the emitted first and the second lights. An objective lens(16) focuses the first and the second lights, and forms optical spots on recordable surfaces of the optical disks. One pair of optical detectors(17,18) receive the first and the second lights sequentially passing through the objective lens and the plate type beam splitter by being reflected from the optical disks, and detect information signals and error signals. A plate member(19) slopes in opposite direction to the plate type beam splitter, and compensates a coma aberration generated when the first and the second lights are transmitted from the plate type beam splitter.

Description

Compatible optical pickup

The present invention relates to a compatible optical pickup, and more particularly to a compatible optical pickup having a two-wavelength laser diode as a light source and a plate-type beam splitter as an optical path conversion device.

Referring to FIG. 1, a conventional compatible optical pickup includes a laser diode 2 emitting first and second lights 2a and 2b having different wavelengths, and a second light emitted from the laser diode 2. A plate-shaped beam splitter 4 for converting the traveling paths of the first and second lights 2a and 2b and the parallel light emitted from the laser diode 2 and collimated by the collimating lens 5 are focused. An objective lens 6 for forming an optical spot on the recording surface of the optical disc 1, and first and second light reflected by the optical disc 1 and via the objective lens 6 and the plate-shaped beam splitter 4; A pair of photodetectors 7 and 8 are provided to receive (2a) and 2b to detect information signals and error signals. In addition, the conventional compatible optical pickup has a grating 3 for branching the second light 2b emitted from the laser diode 2 so as to detect the tracking error signal by the 3-beam method during CD recording / reproducing.

The laser diode 2 is a two wavelength one-chip type, the first light 2a having a wavelength (650 nm) suitable for recording / reproducing DVD, and a wavelength (780 nm) suitable for recording / reproducing CD. The second light 2b is emitted. At this time, the first and the second light (2a) (2b) is emitted in a state spaced apart from each other by a predetermined interval in the structure of the laser diode 2, the optical axis does not coincide with each other.

The first and second light beams 2a and 2b emitted from the laser diode 2 are reflected by the plate-shaped beam splitter 4, and are collimated by the collimating lens 5 to form the objective lens 6 Is incident on the recording surface of the optical disc 1 on the objective lens 6. The first light 2a is focused on the recording surface of the thin DVD 1a, and the second light 2b is focused on the recording surface of the thick CD 1b.

When the plate type beam splitter 4 is used as the optical path changing device as in the conventional compatible optical pickup as described above, the first and second light reflected by the optical disc 1 and transmitted through the plate type beam splitter 4 ( Since astigmatism occurs in 2a) and (2b), it is possible to detect a focus error signal by the astigmatism method.

However, in the conventional compatible optical pickup, the thickness d 'of the plate-shaped beam splitter 4 is thickened and collimated in order to make the size of the light spot received by the photodetectors 7 and 8 to a desired size. Since the numerical aperture (NA) of the lens 5 is increased, optical aberration, in particular coma aberration, is large. When the thickness of the plate-shaped beam splitter 4 is increased, the size of the light spot received by the photodetectors 7 and 8 can be increased, but there is a problem in that coma aberration is largely generated as described above.

In a conventional optical pickup having a plate-type beam splitter as an optical path changing device, a concave lens (not shown) is inclined in front of the photodetector to be inclined opposite to the plate-type beam splitter, thereby correcting coma aberration and the size of the light spot received by the photodetector. Adjust it. However, when the concave lens is applied to an optical system structure in which the optical axes of the first and second lights 2a and 2b proceed with the optical axes spaced apart from each other, as in the conventional compatible optical pickup shown in FIG. According to the position of the lens, the distance between the first and second lights 2a and 2b incident on the pair of four-segment photodetectors 7 and 8 having a constant spacing varies, so that the conventional It is difficult to apply such a concave lens to correct coma aberration in compatible optical pickups.

That is, when the optical axes of the first and second lights 2a and 2b having different wavelengths are shifted from each other as in the conventional compatible optical pickup, the coma aberration correction and the photodetectors 7 and 8 are received. It is not possible to apply concave lenses for light spot size adjustment.

The present invention has been conceived in view of the above-mentioned point, and it is possible to improve the coma aberration and to adjust the size of the light spot received by the photodetector, even though the structure uses two lights having different wavelengths at which the optical axes are different from each other. The purpose is to provide a compatible optical pickup.

1 is a view schematically showing an example of a conventional compatible optical pickup having a plate-type beam splitter as an optical path changing device;

2 is a schematic illustration of a compatible optical pickup according to an embodiment of the present invention having a plate-shaped beamsplitter as an optical path changing device.

<Description of Symbols for Main Parts of Drawings>

11 ... light source 11a, 11b ... first and second light

14 ... plate-type beam splitter 16 ... objective lens

19 ... plate members 17,18 ... photodetectors

In accordance with an aspect of the present invention, a compatible optical pickup includes: a light source emitting first and second light having different wavelengths suitable for first and second optical discs having different thicknesses; A plate-shaped beam splitter for converting a propagation path of the first and second light emitted from the light source; An objective lens for converging first and second light emitted from the light source and forming an optical spot on a recording surface of the optical disc; A pair of photodetectors reflected from the optical disk and receiving first and second light sequentially passing through the objective lens and the plate-shaped beam splitter to detect an information signal and an error signal; And a plate member disposed to be inclined opposite to the plate-shaped beam splitter and correcting coma aberration generated while the first and second lights penetrate the plate-shaped beam splitter.

Here, it is preferable that the first optical disc is a DVD-based optical disc, and the second optical disc is a CD-based optical disc.

Preferably, the light source is a two wavelength one-chip laser diode.

The plate-shaped beam splitter and the plate member have the same thickness and may be inclined at the same inclination of the opposite reference.

In addition, the plate-shaped beam splitter and the plate member may have different thicknesses, and may be inclined at different inclinations of opposite signs.

Hereinafter, preferred embodiments of the compatible optical pickup according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 2, a compatible optical pickup according to an exemplary embodiment of the present invention includes a light source 11, a plate-shaped beam splitter 14 for converting a propagation path of incident light, and an incident light to focus an optical disk. An objective lens 16 for forming light spots on the recording surface of the optical disc 10, photodetectors 17 and 18 for receiving information reflected from the optical disc 10 to detect information signals and error signals; And a transparent plate member 19 for correcting coma aberration generated in the first and second lights 11a and 11b by the plate-shaped beam splitter 14.

The light source 11 emits the first and second lights 11a and 11b having different wavelengths suitable for the first and second optical disks 10a and 10b having different thicknesses, spaced apart from each other at predetermined intervals. . The light source 11 may include a two-wavelength one-chip laser diode. In the compatible optical pickup according to the present invention, the optical axes of the first and second lights 11a and 11b do not coincide with each other.

The first optical disc 10 may be a DVD optical disc, and the second optical disc 10 may be a CD optical disc. In this case, the first light 11a is light having a wavelength of 650 nm (or 635 nm), and the second light 11b is light having a wavelength of 780 nm.

The plate beam splitter 14 converts the traveling paths of the first and second light beams 11a and 11b emitted from the light source 11. The light source 11 and the plate-shaped beam splitter 14 are reflected by the optical disk 10 and transmitted through the plate-shaped beam splitter 14 so that astigmatism is generated to detect a focus error signal by the astigmatism method. The first and second lights 11a and 11b emitted from the light source 11 are preferably disposed to be reflected by the plate-shaped beam splitter 14 and directed toward the objective lens 16.

Of course, the compatible optical pickup according to the present invention includes a plate member 19, and since the astigmatism is also generated by the plate member 19, the light source 11 and the plate-shaped beam splitter 14, The first and second lights 11a and 11b emitted from the light source 11 may be arranged to pass through the plate-shaped beam splitter 14 and face the objective lens 16.

The photodetectors 17 and 18 reflect the first and second lights 11a and 11b which are reflected by the optical disk 10 and sequentially transmitted through the objective lens 16 and the plate-shaped beam splitter 14. And first and second photodetectors 17 and 18, respectively, for receiving and detecting the information signal and the error signal.

Each of the first and second photodetectors 17 and 18 has a quadrant light receiving area. As shown in FIG. 2, when the compatible optical pickup according to the present invention includes the grating 13 to detect the tracking error signal by the 3-beam method when recording / reproducing the second optical disk 10, The second photodetector 18 divides the light into the quadrature light receiving region such that the second light 11b emitted from the light source 11 receives ± 1st light from among the light branched by the grating 13 into 0th order and ± 1st order. It is preferable to further provide two light receiving areas (not shown) on both sides.

The grating 13 may also be used to detect the tracking error signal by the 3-beam method even when recording / reproducing the first optical disc 10a. That is, the first light 11a emitted from the light source 11 is branched into the 0th order and the ± 1th order by the grating 13 similarly to the first light 11a. Therefore, the first photodetector 17 further includes two light receiving regions (not shown) on both sides of the quad split light receiving region so that the first photodetector 17 receives the ± 1 order light for the first light 11a branched from the grating 13, respectively. In this case, the three-beam method can be used for recording / reproducing the first optical disc 10. At this time, the interval between the four-split light receiving region of the first photodetector 17 and the two light receiving regions on both sides is different in the grating 13 which is different from the wavelength difference between the first light 11a and the second light 11b. Is determined in consideration of the diffraction angle difference.

Here, a technique for detecting a tracking error signal by a three-beam method, a photodetector structure for the same, and the like are well known in the art, and thus a detailed description thereof is omitted.

The plate member 19 is disposed inclined opposite to the plate-shaped beam splitter 14 so as to correct coma aberration generated in the first and second lights 11a and 11b by the plate-type beam splitter 14. . At this time, the thickness and inclination of the plate member 19 generate coma aberrations of the same size in the direction opposite to the coma aberration generated by the plate-shaped beam splitter 14 in the first and second lights 11a and 11b. In this way, the coma aberration generated by the plate-shaped beam splitter 14 can be canceled.

The plate member 19 may have the same optical material and structure as the plate-shaped beam splitter 14, and its thickness may be the same as or different from the plate-type beam splitter 14 as necessary.

In the case where the plate member 19 and the plate-shaped beam splitter 14 have the same thickness, the plate member 19 and the plate-shaped beam splitter 14 are arranged at the same inclination of opposite signs symmetrically with respect to the axis crossing the optical axis. do. For example, when the plate member 19 and the plate-shaped beam splitter 14 are of the same thickness and the plate-shaped beam splitter 14 is inclined +45 degrees with respect to the axis crossing the optical axis, the plate member 19 is removed. When placed at an angle of -45 degrees with respect to the axis, the coma aberration generated by the plate-shaped beam splitter 14 is canceled by the plate member 19.

In addition, when the thicknesses of the plate member 19 and the plate-shaped beam splitter 14 are different from each other, the plate member 19 and the plate-shaped beam splitter 14 have opposite signs with respect to the axis in consideration of the thickness difference. They should be placed at different slopes.

On the other hand, the size of the light spot received by the photodetectors 17 and 18 is proportional to the overall thickness of the plate member 19 and the plate-shaped beam splitter 14 as described above. Reducing the overall thickness of the plate member 19 and the plate-shaped beam splitter 14 reduces the size of the light spots received by the photodetectors 17 and 18 and reduces the overall size of the plate member 19 and the plate-shaped beam splitter 14. As the thickness increases, the size of the light spot received by the photodetectors 17 and 18 increases.

Since the compatible optical pickup according to the present invention has a structure including the plate member 19 and the plate-shaped beam splitter 14, that is, substantially two plate-shaped beam splitters, the thickness of each plate-shaped beam splitter is conventionally compatible. Even when thinner than the plate-shaped beam splitter in the optical pickup, the desired light spot size can be obtained, and the coma aberration generated by the plate-shaped beam splitter 14 is erased by the plate member 19, so that the optical disc 10 ) Can be reproduced more accurately.

On the other hand, the compatible optical pickup according to the present invention further comprises a collimating lens 15 for converting the divergent light emitted from the light source 11 into parallel light on the optical path between the light source 11 and the objective lens 16. can do. When the collimating lens 15 is provided as described above, the objective lens 16 is designed for parallel incident light.

As described above, the compatible optical pickup according to the present invention employs an astigmatism method using a plate-shaped beam splitter for detecting a focus error signal, and uses two lights having different wavelengths at which optical axes are shifted from each other.

At this time, the plate-shaped beam splitter is disposed to be inclined, so that not only astigmatism but also coma aberration, the compatible optical pickup according to the present invention has a transparent plate member disposed to be inclined opposite to the plate-type beam splitter, The aberration problem and the light spot size problem can be solved simultaneously.

That is, according to the compatible optical pickup according to the present invention, coma aberration generated by the plate-type beam splitter can be erased in the plate member.

In addition, according to the compatible optical pickup according to the present invention, the thickness of each of the plate-type beam splitter and the plate member can be made thinner than the conventional thick plate-type beam splitter while allowing light spots of a suitable size to be received by the photodetector.

Therefore, according to the compatible optical pickup according to the present invention, it is possible to receive an optical coma aberration correction and a light spot of a suitable size to the photodetector, so that it is possible to reproduce the signal of the optical disk more accurately.

Claims (5)

A light source for emitting first and second light having different wavelengths suitable for the first and second optical discs having different thicknesses; A plate-shaped beam splitter for converting a propagation path of the first and second light emitted from the light source; An objective lens for converging first and second light emitted from the light source and forming an optical spot on a recording surface of the optical disc; A pair of photodetectors reflected from the optical disk and receiving first and second light sequentially passing through the objective lens and the plate-shaped beam splitter to detect an information signal and an error signal; And a plate member disposed to be inclined opposite to the plate-shaped beam splitter and correcting coma aberration generated while the first and second lights penetrate the plate-shaped beam splitter. The compatible optical pickup of claim 1, wherein the first optical disk is a DVD-based optical disk, and the second optical disk is a CD-based optical disk. 2. The compatible optical pickup of claim 1, wherein the light source is a two wavelength one-chip laser diode. The compatible optical pickup according to any one of claims 1 to 3, wherein the plate-shaped beam splitter and the plate member have the same thickness and are inclined at the same inclination with opposite signs. 4. The compatible optical pickup according to any one of claims 1 to 3, wherein the plate-shaped beam splitter and the plate member have different thicknesses and are inclined at different inclinations of opposite signs.