KR100269121B1 - Optical pickup device - Google Patents

Abstract

PURPOSE: An optical pickup device is provided to supply two optical modules for operating recording/reproducing on a land area and a groove area of a recording medium. CONSTITUTION: A P-polarized beam emitted from a first light source(410) is converted into a parallel beam by passing through a collimating lens(420) for inputting to a first beam splitter(430). The P-polarized beam is inputted to a polarized beam splitter(320). An S-polarized beam emitted from a second light source(510) is converted into parallel by passing through a collimating lens(520) for inputting to a second beam splitter(530). The S-polarized beam is reflected on the second beam splitter for inputting to the polarized beam splitter. The beam splitter progresses the P-beam while reflecting the S-beam. Thus, an optical path is formed an object lens(310). The P-beam forms spot on a land area(110) of the disk, and the S-beam forms spot on a groove area(120).

Description

Optical pickup

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pickup apparatus, and more particularly, to an optical pickup apparatus provided with two optical modules to record and reproduce information in a land area and a groove area of a recording medium, respectively.

In general, an optical pickup device is a device that is employed in a disc player or the like to record and / or reproduce information on a recording surface of a recording medium in a non-contact manner, such that a recording medium on which predetermined information is recorded / reproduced by such an optical pickup device A schematic drawing for explaining the recording surface of the optical disc is shown in FIG.

Referring to FIG. 1, the optical disc 100 has a twin-helical structure in which a land region 110 formed in a helical shape and a groove region 120 drawn in a predetermined depth parallel to the land region are formed. The optical disc having such a double-helical structure contains data at a constant density per predetermined interval, so that this data is read at a constant linear velocity (CLV).

2 schematically shows an optical arrangement of a conventional optical disc for recording / reproducing information on such an optical disc. As shown in FIG. 2, a conventional optical pickup apparatus includes a light source 210 for generating predetermined light, an objective lens 220 for condensing incident light to form spots on a recording surface of the recording medium 100, A beam splitter 230 for transmitting and reflecting incident light at a predetermined light quantity ratio, and a photodetector 240 for reflecting light from the recording surface of the recording medium 100 and receiving incident light through the beam splitter 230.

The light source 210 is a device that generates and emits light, for example, a semiconductor laser that emits a laser beam. The objective lens 220 converges the light incident from the light source 210 to be condensed on the recording surface of the recording medium 100, for example, a land area. The beam splitter 230 is positioned on an optical path between the light source 210 and the objective lens 220 so that the light incident from the light source 210 passes straight through and the light is incident from the objective lens 220. Is reflected to the photodetector 240. The photodetector 240 receives light reflected from the recording surface of the recording medium 100 to detect an information signal and an error signal. On the other hand, the astigmatism lens 250 disposed on the optical path between the beam splitter 230 and the photodetector 240 is generally a semi-cylindrical lens, between the objective lens 220 and the recording medium 100. If the distance is On Focus, the circular beam is made to the photodetector 240, otherwise the elliptical beam is made to the recording medium 100.

The optical pickup apparatus configured as described above records / reproduces information while following a track in which one beam irradiated from a light source spirally forms on the recording surface of the recording medium 100. In this case, since information is recorded / reproduced in only one of the recording areas of the recording medium 100, for example, the land area 110 on the optical disc and the land area 110 of the groove area 120, continuous reproduction is possible and tracking is possible. This has the advantage of being easy, but it has a problem that it does not meet the increasing demand in terms of recording density.

An object of the present invention is to provide an optical pickup apparatus having two optical modules, which are capable of recording / reproducing each of land and groove regions on a recording medium.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram for explaining a twin-helical structure of a general optical disc.

2 is a view schematically showing an optical arrangement of a conventional optical pickup device.

3 is a view schematically showing an optical arrangement of the optical pickup apparatus according to the present invention.

4 is a schematic view showing an optical arrangement of an optical pickup apparatus according to another embodiment of the present invention.

5 is a view for explaining a tracking error correction method in the optical pickup apparatus according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100 ... optical disc 110 ... land area

120 ... groove area 310 ... objective lens

320 ... polarized beam splitter 400 ... first optical module

500 ... second optical module 410, 612 ... first light source

420, 520 ... collimating lens 430, 530 ... beam splitter

440, 540 ... cylindrical lenses 450, 550, 614, 624 ... photodetectors

510, 622 ... Second light source 613, 623 ... Hologram element

In order to achieve the above object, the optical pickup apparatus according to the present invention includes a land area formed spirally on a recording surface and a groove area adjacent to the land area and having a groove area drawn in a predetermined depth. An optical pickup apparatus for simultaneously recording / reproducing predetermined information in an area and a groove area, comprising: a first light source for generating and irradiating first polarized light and a first light beam for transmitting and reflecting incident light from the first light source at a predetermined light quantity ratio A beam splitter, a first photodetector that is reflected in the land region and receives light incident through the first beam splitter, a second light source for generating and irradiating a second polarization light, and incident light from the second light source A second beam splitter that transmits and reflects at a predetermined light quantity ratio, and light reflected by the groove area and incident through the second beam splitter is received; A second photodetector, an objective lens for converging light incident from the first and second light sources to form spots in the land and groove regions, respectively, and an optical path between the first and second light sources and the objective lens And a polarization beam splitter disposed on the light beam, which transmits light of one polarization of the incident light in a straight line and reflects the other polarization light.

Preferably, the first light source, the first beam splitter and the first photodetector are integrated to form a first optical module, and the second light source, the second beam splitter and the second photo detector are integrated to form a second optical module. To form.

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

3 shows an optical arrangement of the optical pickup apparatus according to the present invention. Referring to FIG. 3, the optical pickup apparatus according to the present invention includes a first optical module 400 for recording / reproducing predetermined information in the land area 110 of the optical disc 100, and a groove area of the optical disc 100. The second optical module 500 for recording / reproducing predetermined information on the 120 and the light incident from the first and second optical modules 400 and 500 are focused so that the land area of the optical disc 100 An objective lens 310 for forming spots in the 110 and groove regions 120, and an optical path between the first and second optical modules 400 and 500 and the objective lens 310. And a polarizing beam splitter 320 disposed on and transmitting straight polarized light of the incident light and reflecting the other polarized light.

The first optical module 400 is reflected by the first light source 410, the first beam splitter 430 for converting the propagation path of the incident light, and the land region 110 of the disc 100 to be first. It is preferable that the first photodetector 450 in which light incident through the beam splitter 430 is received is integrally provided.

The first light source 410 is a semiconductor laser that emits a first polarized light, such as P polarized light, and the first beam splitter 430 directs light incident from the first light source 410 to the disk 100. The incident light reflected from the land region 110 of the disk 100 is transmitted or reflected at a predetermined light quantity ratio so as to be directed to the first photodetector 450. The first photodetector 450 is reflected by the land region 110 of the disk to receive light through the objective lens 310, the polarizing beam splitter 320, and the first optical path changing means 430. It detects an error signal and an RF information signal, and for this purpose includes at least two partitions each independently photoelectric conversion.

On the other hand, a collimating lens 420 for converting the divergent light emitted from the first light source 410 into parallel light is located between the first light source 410 and the first beam splitter 430, the first beam splitter ( An astigmatism lens such as a cylindrical lens 440 is positioned between the 430 and the first photodetector 450. The cylindrical lens 440 causes a circular beam to form on the photodetector 450 when the distance between the objective lens 310 and the disk 100 is on focus. An elliptical beam is formed on the photodetector 450 to enable detection of the focus error signal.

The second optical module 500 is reflected by the second light source 510, the second beam splitter 530 for converting the propagation path of the incident light, and the groove area 120 of the disk 100 to be secondly reflected. It is preferable that the second photodetector 550 in which light incident through the optical path changing means 530 is received is integrated with and provided.

The second light source 510 is a semiconductor laser that emits a second polarized light, for example S polarized light, and the second beam splitter 530 directs light incident from the second light source 510 to the disk 100. The incident light reflected from the groove area 120 of the disk 100 passes or reflects the incident light at a predetermined light quantity ratio so as to be directed to the second photodetector 550. The second photodetector 550 is reflected in the groove area 120 of the disk to receive light through the objective lens 310, the polarizing beam splitter 320, and the second beam splitter 530 to receive an error signal. And at least two partition plates for detecting an RF information signal, and for this purpose, photoelectric conversion independently from each other.

On the other hand, as in the first optical module 400, the collimating lens 520 for converting the divergent light emitted from the second light source 510 into parallel light is the second light source 510 and the second beam splitter 530 ), And an astigmatism lens, such as a cylindrical lens 540, is positioned between the second beam splitter 530 and the second photodetector 550.

The polarizing beam splitter 320 is commonly located on the optical path between the first optical module 400 and the objective lens 310 and the optical path between the second optical module 500 and the objective lens 310. According to the polarization direction of the incident light, the traveling path of at least one of the polarizations emitted from the first optical module 400 and the second optical module 500 is converted. Accordingly, the polarizations in different directions emitted from the first optical module 400 and the second optical module 500 proceed toward the disk 100. In the optical arrangement as shown in FIG. 3, the process of determining the propagation path of light by the polarization beam splitter 320 is as follows. According to the polarization beam splitter 320 which transmits P-polarized light and reflects S-polarized light, the P-polarized light emitted from the first optical module 400 travels straight from the polarized beam splitter 320 so that the land area of the disk ( A spot is formed in the 110 and the S-polarized light emitted from the second optical module 500 is reflected by the polarization beam splitter 320 to form a spot in the groove area 120 of the disk.

The objective lens 310 focuses the P-polarized light emitted from the first optical module 400 and the S-polarized light emitted from the second optical module 500, so that the P-polarized light is spotted in the land region 110 of the disc. S polarized light causes spots to be formed in the groove region 120 of the disk.

Hereinafter, the operation of the optical pickup apparatus according to the present invention will be described with reference to the accompanying drawings.

P-polarized light emitted from the first light source 410 is converted into parallel light while passing through the collimating lens 420 and is incident on the first beam splitter 430. P-polarized light that passes straight through the first beam splitter 430 is incident on the polarization beam splitter 320. Meanwhile, the S-polarized light emitted from the second light source 510 is also converted into parallel light while passing through the collimating lens 520 and is incident on the second beam splitter 530. S-polarized light reflected by the second beam splitter 530 is incident to the polarization beam splitter 320. In the polarization beam splitter 320 which receives the P-polarized light and the S-polarized light, the P-polarized light is straight and the S-polarized light is reflected to form an optical path toward the objective lens 310. On the optical path thus formed, the P-polarized light forms a spot in the land region 110 of the disc via the objective lens 310, and the S-polarized light is formed in the groove region 120 of the disc via the objective lens 310. Form a spot.

On the other hand, the P-polarized light reflected from the land region 110 is passed through the objective lens 310, the polarizing beam splitter 320, the first beam splitter 430, and the cylindrical lens 440. 450, and the S-polarized light reflected by the groove region 120 is formed through the objective lens 310, the polarizing beam splitter 320, the second beam splitter 530, and the cylindrical lens 540. 2 is formed on the photodetector 550. Then, the first and second photodetectors 450 and 550 receive P polarized light and S polarized light, respectively, and convert the P polarized light and the S polarized light into an electric signal, which is then applied to the land area 110 and the groove area 120 of the disc. The recorded information can be detected, and the focus error and track error signal of the objective lens 310 can be detected.

On the other hand, Figure 4 schematically shows an optical pickup device according to another embodiment of the present invention. As shown, the first optical module 400 and the second optical module 500 of FIG. 3 are light sources 611, 621, hologram elements 613, 623, and photodetectors 614, 624, respectively. And housings 615 and 625 are integrally formed. That is, the first optical module 400 includes a first substrate 611, a first light source 611 positioned on the first substrate 611 to generate and emit first polarized light, and an incident direction of incident light. The hologram element 613 which is to be transmitted in a straight line and diffraction, and the first photodetector 614 which is reflected in the land area of the disk 100 and receives the light incident through the hologram element 613 are integrally provided. have. In addition, the second optical module 500 includes a second substrate 621, a second light source 621 positioned on the second substrate 621 to generate and emit second polarized light, and an incident light incident direction. The hologram element 623 which is to be transmitted in a straight line and diffraction, and the second photodetector 624 which is reflected in the groove area of the disk 100 and receives light incident through the hologram element 623 are integrally provided. have.

The operation of the optical pickup device having such a configuration is as described above, and in the present embodiment, the beam splitters 430 and 530 are used as the optical path changing means in the first optical module 400 and the second optical module 500. Instead, the hologram elements 613 and 623 are employed, respectively.

Meanwhile, when a track error signal is detected in the process of recording / reproducing predetermined information in the land area 110 and the groove area 120 on the disc 100 by the optical pickup apparatus according to the present invention, the first optical module is detected. At least one optical module 400 and the second optical module 500 may be moved in both directions so that tracking is performed. That is, as shown in FIG. 5, a tracking error has occurred in a spot formed in the land region 110 of the disk by the first optical module 400 by l, and the groove of the disk is caused by the second optical module 500. Consider a case where the spot formed in the region 120 has no tracking error (in FIG. 5, the solid line is the light incident by the first optical module 400 and the dotted line is the second optical module 500). Is incident light). In this case, when tracking correction by an actuator (not shown) of the objective lens 310 is performed, the spot formed by the first optical module 400 may be corrected, but at the same time, the second optical module 500 may be corrected. The tracking error is generated by the spot formed by). Therefore, in this case, if only the first optical module 400 is moved so that the error l is corrected with respect to the polarization beam splitter 320, the first optical module 400 can maintain the tracking in the second optical module 500 while simultaneously maintaining the tracking in the second optical module 500. Tracking errors in module 400 may be corrected. Even in the case of focus error, only the collimating lens 420 of the first optical module 400 may be moved and corrected while maintaining the focusing of the second optical module 500.

As described above, the optical pickup apparatus according to the present invention employs two optical modules to simultaneously record / reproduce the land area and the groove area of the disc, thereby doubling the recording density and transfer speed of the disc. Can be.

Claims (8)

Light for simultaneously recording / reproducing predetermined information in the land area and groove area of a twin-shaped recording medium having a land area spirally formed on a recording surface and a groove area adjacent to the land area and drawn in a predetermined depth. In the pickup device, A first light source for generating and irradiating a first polarized light; A first beam splitter configured to transmit and reflect incident light from the first light source at a predetermined light quantity ratio; A first photodetector reflecting light from the land region and receiving light incident through the first beam splitter; A second light source for generating and irradiating a second polarized light; A second beam splitter configured to transmit and reflect incident light from the second light source at a predetermined light quantity ratio; A second photodetector reflecting light from the groove area and receiving light incident through the second beam splitter; An objective lens for converging light incident from the first and second light sources to form spots in the land and groove regions, respectively; And An optical pickup device disposed on an optical path between the first and second light sources and the objective lens, the polarizing beam splitter transmitting light of one polarization of the incident light and reflecting another polarization light; . The method of claim 1, And a cylindrical lens disposed on an optical path between the first beam splitter and the first photodetector to detect a focus error signal by an astigmatism method. The method according to claim 1 or 2, And a cylindrical lens disposed on an optical path between the second beam splitter and the second photodetector, so that a focus error signal can be detected by an astigmatism method. The method of claim 1, And the first light source, the first beam splitter, and the first photodetector are integrated to form a first optical module. The method of claim 4, wherein the first optical module, A first substrate, a first light source positioned on the first substrate, a hologram element configured to transmit and diffract linearly and diffraction in accordance with the incident direction of the incident light, and positioned on the first substrate and reflected in the land region, And a first photodetector to receive light incident via the hologram element integrally. The method of claim 1, And the second light source, the second beam split, and the second photo detector are integrated to form a second optical module. The method of claim 6, wherein the second optical module, A second substrate, a second light source located on the second substrate, a hologram element configured to transmit and diffract straight and diffraction in accordance with the incident direction of the incident light, and positioned on the second substrate and reflected in the groove area to And a second photodetector integrally receiving the light incident through the hologram element. The method according to any one of claims 4 to 7, At least one of the first and second optical modules is arranged to be movable relative to the polarizing beam splitter so as to independently move each spot formed in the land area and the groove area. .

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