KR980011173A - Optical pick-up device - Google Patents

Abstract

The present invention relates to an optical pickup apparatus, and more particularly, to an optical pickup apparatus which includes a laser diode for emitting a laser beam, a diffraction grating provided on the upper side of the laser diode for separating the laser beam into light for tracking error detection, A beam splitter integrally formed on the upper side of the diffraction grating for transmitting and reflecting a part of the laser beam separated from the diffraction grating, an objective lens positioned on the upper side of the beam splitter and spaced apart from the center by a predetermined distance, A reflection type holographic grating integrally formed on one side of the beam splitter and adapted to reflect light information incident on the beam splitter through an objective lens, and a reflection type holographic grating integrally formed on the other side of the beam splitter, A beam transmitted through the coated lens surface, and a lens surface that is not coated with the beam. Data recorded on a digital audio disk and a digital video disk having different recording densities can be selectively read by using a point where a numerical aperture of the lens and a light amount difference are generated between the passed beams and a beam size converged on the disk is different And the diffraction grating, the beam splitter, the reflection type holographic grating, and the photodiode are integrated to reduce the product size and the error occurrence rate.

Description

Optical pick-up device

The present invention relates to an optical pickup apparatus and, more particularly, to an optical pickup apparatus using a semi-transparent coating on a central portion of an objective lens to generate a numerical aperture and a light quantity difference of a lens, To an optical pickup apparatus capable of selectively reading information recorded on a digital video disk and a digital audio disk.

As shown in FIG. 1, the OPTICAL PICK-UP apparatus generally includes a laser diode 70 for generating a laser beam, a laser diode 70 disposed on one side of the laser diode 70, A diffraction grating 71 for dividing the diffraction grating 71 into a light for tracking error detection and a beam splitter 71 having a predetermined slope at one side of the diffraction grating 71 and separating incident light into reflected light and transmitted light having a constant ratio of reflectance and transmittance An objective lens 72 disposed on the beam splitter 72 for focusing the light separated by the beam splitter 72 on the disc 73 and having a diffraction limit performance of a predetermined wavelength or less, And a photodiode 75 provided below the beam splitter 72 and converting the optical information read from the disk 73 through an objective lens 74 into a current.

In the operation of the conventional optical pickup device thus constructed, a laser beam having a predetermined oscillation wavelength is emitted from the laser diode 70 first. The laser beam emitted from the laser diode 70 passes through the diffraction grating 71 and is separated into three beams (three beams: zero-order light, ± first-order light) for detecting a tracking error.

The laser beam separated into three beams while passing through the diffraction grating 71 proceeds to a beam splitter 72 having a constant ratio of reflectance and transmittance. The laser beam proceeding to the beam splitter 72 is separated into a predetermined ratio of reflected light and transmitted light, and the reflected laser beam is condensed by the objective lens 74 for condensing the beam with a diffraction limit performance of a predetermined wavelength or less, And a diameter of about 1.6 mu m.

Here, the laser beam focused by the objective lens 74 is irradiated onto the recording layer of the disk 73 in the airy form of about 1.6 mu m, and the laser beam irradiated on the recording layer is almost The laser beam is diffracted by the pit and reflected out of the field of view of the objective lens 74 at the position of the pit. Therefore, since only a part of the incident laser beam is reflected and returned, a difference occurs in the amount of light detected by the photodiode 75. [

The modulated light information is transmitted to the photodiode 75 through the objective lens 74 and the beam splitter 72 and is reflected by the photodiode 75 75 converts the optical information into a current and outputs it. The current output from the photodiode 75 is demodulated into an RF signal, a focus signal, and a tracking signal by a control circuit (not shown). Thus, the information recorded on the disc 73 is reproduced.

However, in the conventional optical pickup device, since the optical parts of the beam splitter, the diffraction grating, and the photodiode are independently fabricated and assembled to constitute the optical pickup device, the error rate during operation is high due to the mechanical error generated during the assembly, Considering the position and accuracy of assembly between the respective optical parts, the size and installation of the individual parts are limited. Therefore, it is difficult to miniaturize the optical parts. Especially, since the beam size is fixed to one, There is a problem that the disc can not be reproduced by one optical pickup device.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an objective lens which is semi-transparent coated on the center of an objective lens, It is possible to selectively read the information recorded on the digital video disk and the digital audio disk having different recording densities by using the difference in the number of beams and the amount of light and thus the beam size converged on the disk, It is an object of the present invention to provide an optical pickup apparatus that integrates a grating, a beam splitter, a photodiode, and a reflection type holographic grating to miniaturize a product, and reduce a mechanical error occurrence rate that can be generated by an assembling process.

According to an aspect of the present invention, there is provided a laser diode including a laser diode for emitting a laser beam, a diffraction grating provided on the upper side of the laser diode for separating the laser beam into light for tracking error detection, A beam splitter integrally formed on the upper side of the beam splitter and transmitting a part of the laser beam separated from the diffraction grating and partially reflecting the laser beam, an objective lens positioned on the upper side of the beam splitter, A reflection type holographic grating integrally formed on one side of the beam splitter and adapted to reflect light information incident on a beam splitter through an objective lens; and a reflection type holographic grating integrally formed on the other side of the beam splitter, And a photodiode for detecting information as an electric current.

FIG. 1 is a configuration diagram of a conventional optical pickup device. FIG.

FIG. 2 is a configuration diagram of the present invention; FIG.

DESCRIPTION OF THE REFERENCE NUMERALS

1: laser diode 2: diffraction grating

3: beam splitter 4: objective lens

5: Reflective surface 6: Reflective holographic grating

7: Photodiode 8: Semi-transparent portion

9: Combat Widows 10: Disc

BRIEF DESCRIPTION OF THE DRAWINGS Fig.

As shown in FIG. 2, the structure of the present invention includes a laser diode 1 for emitting a laser beam, a laser diode 1 disposed above the laser diode 1 at a predetermined interval and separating the laser beam into light for tracking error detection A beam splitter 3 integrally formed on the upper side of the diffraction grating 2 for transmitting a part of the laser beam separated from the diffraction grating and partially reflecting the laser beam, And an objective lens 4 integrally formed on one side of the beam splitter 3 and being provided integrally with the beam splitter 3 through an objective lens 4. The beam splitter 3 is formed integrally with the beam splitter 3, A reflection type hologram grating 6 which is incident on the reflection splitter 3 and reflects the light information reflected by the reflection surface 5 of the beam splitter 3 and a reflective hologram grating 6 which is integrally formed in the center of the other side of the beam splitter 3, (6) is detected Is composed of a photodiode (7).

The surface of the objective lens 4 has a semitransmissive portion 8 coated with a film having a circular central portion and a transmittance and a reflectance of 50:50 respectively and a portion not coated on the outer peripheral surface of the semitransmissive portion 8 And a comb-feeding wid portion 9 for transmitting the entire incident beam.

Next, the operation of the present invention will be described.

First, when the laser beam is emitted from the laser diode 1, the laser beam emitted from the laser diode 1 passes through the diffraction grating 2 to form a three-beam (three-beam) Primary light).

The laser beam split into three beams while passing through the diffraction grating 2 proceeds to the beam splitter 3 having a constant ratio of reflectance and transmittance. The laser beam traveling to the beam splitter 3 is separated into a predetermined ratio of reflected light and transmitted light, and the laser beam transmitted through the beam splitter 3 travels to the objective lens 4.

The laser beam irradiated on the objective lens 4 passes through the transflective portion 8 and the combat wid portion 9 and the numerical aperture of the lens is changed by the difference in transmittance between the transflective portion 8 and the combat wid portion 9, (8), and NA2 in the battle section (9).

Therefore, the laser beam passing through the transflective portion 8 and the combat wid portion 9 of the objective lens 4 forms two different kinds of beam paths due to the difference in numerical aperture and the difference in light amount caused by the difference in transmittance , And selectively reads the information recorded on the digital audio disk (DAD) and the digital video disk (DVD) according to the beam path difference.

That is, the laser beam transmitted through the beam splitter 3 passes through the transflective portion 8 of the objective lens 4 and is focused at an angle of? 1 to form a beam focus on the disk 10. The laser beam passing through the comb-shaped portion 9 of the objective lens 4 is focused at an angle of? 2 to form a beam focus on the disk 10.

Here, the beams focused at the angles of [theta] 1 and [theta] 2 form a beam focus at the same point but have different beam sizes.

The relationship between the angle of the focused laser beam, the numerical aperture, and the beam size is as follows.

NA1 =? Sin? 1, NA2 =? Sin? 2 (1)

(? is refractive index, refractive index in air? = 1)

NA1 = Sin? 1, NA2 = Sin? 2 (2)

D = K ?? ? / NA (3)

(D is a beam size, and K is a constant)

The beam size is changed as the numerical aperture (NA) of the lens is changed by the light amount difference and the beam path difference of the laser beam generated by the transflective coating coated on the objective lens 4 as in the above equation.

If the disc 10 to be reproduced is a digital audio disc, the beam spot of the laser beam, which is transmitted through the transflective portion 8 of the objective lens 4 and converged at the angle of? 1, It is larger than the beam spot of the laser beam focused at the angle of? 2 through the comb-tooth portion 9, and a beam spot of 1.6 mu m is formed on the disk 10. Accordingly, data recorded on a digital audio disk DAD having a low recording density is read.

Once the laser beam is transmitted through the transflective portion 8 of the objective lens 4 and focused on the disk 10 by the angle of? 1 and the beam spot of 1.6 m, The focused laser beam is diffracted by the pit and out of the field of view of the objective lens 4, so that only a part of the incident laser beam is returned and the amount of light of the laser beam detected by the photodiode 7 is different.

At this time, the optical information reflected on the recording layer of the disk 10 and incident on the transflective portion 8 proceeds to the beam splitter 3. The light information reflected by the reflective film 5 of the beam splitter 3 at a constant rate is transmitted to the reflective hologram grating 6 and reflected by the reflective hologram grating 6. The optical information reflected by the reflection type holographic grating 6 is detected by the photodiode 7.

On the other hand, when the disk 10 to be reproduced is a digital video disk with a high recording density, the beam spot of the laser beam, which is transmitted through the comb-shaped portion 9 of the objective lens 4 and converged at the angle of 2, The laser beam transmitted through the transflective portion 8 becomes smaller than the focused laser beam, and a beam spot of 0.8 μm is formed on the disk 10. When the laser beam transmitted through the comb-shaped portion 9 of the objective lens 4 is converged on the disk 10 by the angle of? 2 and the beam spot of 0.8 m, it is almost reflected as it is in the place where there is no recorded pit, The converged laser beam is diffracted by the pit and out of the visual field of the objective lens 4, so that only a part of the incident laser beam is returned and a difference is generated in the light amount of the laser beam detected by the photodiode 7.

At this time, the optical information reflected on the disk 10 and incident on the comb-over portion 9 proceeds to the beam splitter 3. The light information reflected by the reflection surface 5 of the beam splitter 3 at a constant ratio is reflected by the reflection type hologram grating 6 and detected by the photodiode 7.

At the same time, the laser beam passing through the transflective portion 8 of the objective lens 4 and focused on the disk 10 at the angle of? 1 has a large diameter of the beam spot, The amount of light reaching the objective lens 4 is negligible.

The optical information reflected by the digital audio disk and the digital video disk through the beam path as described above and detected by the photodiode 7 is converted into a current which is an RF signal, a focus signal, and a tracking signal, The tracking signal is input to the servo control section to perform focus and tracking servo control. The RF signal is demodulated into an original signal in the digital signal processing section to reproduce the information recorded on the disk.

Here, the focus error signal is detected by the Foucault method and the tracking error signal is detected by the three beam method.

As described above, according to the present invention, a semi-transmissive coating is applied to a central portion of an objective lens, and a numerical aperture and a light amount difference of a lens are generated between a beam transmitted through a coated lens surface and a beam passing through an uncoated lens surface Accordingly, it is possible to selectively read data recorded on a digital audio disk and a digital video disk having different recording densities by using a beam size converged on the disk, and it is possible to selectively read data recorded on a digital video disk and a diffraction grating, a beam splitter, a photodiode, Type hologram grating are integrated to reduce the product size and the error occurrence rate.

Claims (1)

A diffraction grating 2 disposed at a predetermined distance above the laser diode 1 for separating the laser beam into light for tracking error detection and a laser diode 1 for emitting a laser beam, A beam splitter 3 integrally formed on the upper side of the beam splitter 3 and transmitting a part of the laser beam separated from the diffraction grating 2 and reflecting a part of the laser beam; An objective lens 4 composed of a semi-transmissive portion 8 coated with a circular semi-transparent film and a comb-shaped transparent portion 9 for totally transmitting a beam incident on a portion not coated on the outer peripheral surface of the semi-transparent portion 8 A reflection type holographic grating 6 integrally formed on one side of the beam splitter 3 for reflecting optical information incident on the beam splitter 3 through the objective lens 4, And is integrally formed at the center of the other side, The optical pickup device according to claim consisting of the photodiode (7) for detecting the reflected light information from the RAM grid (6). ※ Note: It is disclosed by the contents of the first application.