KR960006099B1 - Optical pick-up apparatus with paravola reflector - Google Patents

Abstract

a laser source which generates the laser beam; an optical diffraction means which reflects the laser beam and divides the laser beam into the three parts; a parabola reflector which collects the reflected beam from the optical diffraction means into the information recoding medium and collects the reflected beam from the information recoding medium into the laser source through the optical diffraction means.

Description

Optical pickup with parabolic reflector

1 and 2 illustrate the structure of a conventional optical pickup apparatus.

3 is a schematic perspective view illustrating a configuration of an optical pickup apparatus having a parabolic reflector according to the present invention.

4 is a cross-sectional view for explaining the operation of the optical pickup device having a parabolic reflector according to the present invention.

* Explanation of symbols for main parts of the drawings

10: laser light source 11: collimated lens

12: beam splitter 14: objective lens

17: light emitting diode 20: light source

22: collimated lens 30: information recording medium (disk)

40: parabola reflector 50: hologram laser diode

60: mirror diffraction grating 70: movable coil

80: fixed arm

The present invention relates to an optical pickup apparatus having a parabola reflector, and more particularly, a laser beam radiated from a hologram laser diode is connected by a mirror diffraction grating and a parabola reflector to condense on the surface of an information recording medium. An optical pickup apparatus having a parabolic reflector adapted to receive a laser beam reflected from a surface of the information recording medium to read information recorded on the information recording medium.

In general, a disc reproducing system that uses an optical property to read information recorded on the surface of an information recording medium such as a laser disc or a compact disc by means of a lazy beam, investigates the laser beam on the surface of the information recording medium, and examines the information. An optical pickup apparatus adapted to receive reflected light reflected from the surface of the recording medium to read information.

Such an optical pickup apparatus is classified into a 1 beam method using a single laser beam and a 3 beam method using a single laser beam by dividing into three, and the configuration is a laser diode as shown in FIG. A light source 10 configured to generate a laser beam and a collimated lens 11 converting the laser beam radiated from the light source 10 into parallel light, and parallel light by the collimated lens 11 Laser beam incident on the surface of the disk D, precisely on the reflective surface R of the disk D, is converted into a beam splitter 12 and a quarter wave plate 13, respectively. The objective lens 14 is provided, and the reflected light reflected from the reflective surface R of the disk D is converted into parallel light through the objective lens 14, and the polarized surface at the quarter wave tube 13 is Is changed by 90 ° and then the incident and reflected light of the laser beam The reflected light is separated from the beam splitter 12 that separates the light from the beam splitter 12. The optical pickup apparatus includes a focused lens 5 focusing the reflected light and the reflected light focused by the focused lens 15. A quadrature light-receiving diode 17 which receives light through (Knife edge, 16) is provided.

As is well known, the beam splitter 12 is configured by obliquely arranging two rectangular prisms, and polarizes on the inclined surface of the prism in any one direction so as to ensure straightness for incident light while reflecting 90 ° in the direction of reflected light. The film is applied. Further, the quarter-wave plate 13 has a function of converting linearly polarized light into circularly polarized light or converting circularly polarized light into linearly polarized light by using birefringence.

In the case of the three-beam method, the front or rear of the collimating lens 11, that is, between the light source 11 and the collimating lens 11 or between the collimating lens 11 and the beam split 12 A diffraction grating 18 for dividing the laser beam into three is provided.

According to the optical pickup device having such a configuration, the laser beam emitted from the light source 10 is converted into parallel light in the coolimate lens 11 (in the case of the three beam method, divided by the diffraction grating 18 in three beams), and then the incident light. A beam spot of approximately 1 μm on the reflective surface R of the disk D in the objective lens l4 through the beam split 12 and the quarter wave tube 13 separating the reflected light. To form. The laser beam irradiated onto the disk D has a different amount of reflected light depending on the presence or absence of the pit P on which information is recorded, and the reflected light is converted into parallel light in the objective lens 14 and then the quarter wave plate 13 ), The polarization plane is changed by 90 °, and then the direction is changed in the beam splitter 12 to be focused by the focusing lens 15. The focused reflected light is received by the four-segment light-receiving diode 17 through the cylindrical lens or knife edge 16, and the position accuracy of the pickup device with respect to the disk D in accordance with the condensed state of the light-receiving diode. Is determined and information is reproduced based on the amount of reflected light determined by the pitch P of the disk D. FIG.

By the way, in the conventional optical pickup apparatus having the above-described configuration, the incident light of the laser beam emitted from the light source 10 composed of the laser diode and the reflected light reflected from the reflecting surface R of the disk D are received and the disk D The laser beam passes through a plurality of incidometers and reflectometers between the photodiodes 17, which obtain an electrical signal relating to the information recorded in < RTI ID = 0.0 > 1, < / RTI > and for that reason the optical pickup device has a relatively complicated structure. Moreover, in the case of the quarter-wave plate 13 which converts the reflected light by 90 ° to the incident light, antireflection coating is performed on the surface thereof, so that strict limitations are imposed on the thickness and cutting angle appropriate for the wavelength of the laser beam used. The situation is not easy to manufacture.

In view of this, studies on the simplification of the optical pickup device have been conducted, and the optical pickup device of the type shown in FIG. 2 has been proposed. According to the optical pickup device, the laser pickup is composed of a laser diode. The collimating lens 22 which converts the light source 20 which generate | occur | produces, and the laser beam radiated | emitted by this light source 20 and injected through a rectangular prism into parallel light, This collimating lens 22 converts into parallel light An objective lens 23 for condensing the laser beam on the disk D, and a focusing coil for positioning the objective lens 23 so that the objective lens 23 is focused at the target position of the disk D accurately. Reflected light reflected from the 24 and the plurality of sandstones 25 and the disk D is converted into parallel light by the objective lens 23, and is reflected from the reflecting surface of the rectangular prism 21 through the chromate lens 22. Reflected light transversely It consists equipped with a light-receiving diode (26) for receiving.

According to this optical pick-up apparatus, the collimated lens 22 is designed to be used in close proximity to the objective lens 23 so as to use only the portion having the good characteristics of the laser beam emitted from the light source 20, as shown in FIG. Compared to the optical pickup device, the use of a beam splitter or a quarter wave plate is excluded. Therefore, although the optical pickup device shown in FIG. 2 has a relatively simple configuration, the position adjustment of the collimator lens 22 and the objective lens 23 and the objective lens 23 for converting the laser beam into parallel light is achieved. (I.e., a plurality of magnets 25 for focusing).

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described prior art, in which a mirror diffraction grating of a laser beam emitted from a hologram laser diode without the configuration of a collimated lens or an objective lens for converting the laser beam emitted from a light source into parallel light is provided. It is an object of the present invention to provide an optical pickup apparatus having a parabolic reflector having a simple configuration in which three beams are divided so that the parabolic reflector is directly focused on the surface of the information recording medium.

According to the present invention for achieving the above object, the information recorded on the surface of the information recording medium by irradiating the laser beam on the surface of the information recording medium and receiving the reflected light of the laser beam reflected from the surface of the information recording medium. An optical pickup apparatus for reading a light, comprising: a holographic laser light source for generating a laser beam, and optical diffraction means for dividing and reflecting the laser beam emitted from the holographic laser light source into three beams; The laser beam reflected by dividing into tens of thousands is reflected on the surface of the information recording medium, and the reflected light reflected from the surface of the information recording medium is focused on the light receiving element disposed around the laser light source through the optical diffraction means. Provided is an optical pickup apparatus having a parabola reflector configured with a parabola reflector.

According to a preferred embodiment of the present invention, the optical diffraction means comprises a mirror provided on the frame of the parabola reflector, and the parabola reflector has a hemispherical shape in which the laser beam has a circumferential ratio where the laser beam is focused at a predetermined position of the information recording medium. It is formed by a biasing means is provided by the biasing means that the displacement is possible.

According to the optical pickup device having a parabola reflector according to the present invention configured as described above, the laser beam radiated from the laser diode of the hologram laser light source is reflected by the mirror diffraction beam to the parabola reflector, and the laser beam incident on the parabola reflector is The information recording medium is irradiated onto the surface of the information recording medium from the hemispherical surface of the parabola reflector, and the reflected light reflected from the surface of the information recording medium is received by the parabolic reflector and the mirror diffraction grating by the light receiving element of the hologram laser light source. The information recorded on the surface of the can be read.

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

FIG. 3 is a schematic perspective view illustrating the configuration of an optical pickup apparatus having a parabola reflector according to the present invention, and FIG. 4 is a cross-sectional view illustrating the operation of the optical pickup apparatus having a parabola reflector according to the present invention shown in FIG. 30 denotes a disc as an information recording medium on which audio information or video information is recorded, 40 denotes a parabola reflector for reflecting a laser beam in an optical pickup apparatus equipped with a parabola reflector according to the present invention, and 50 denotes that parabola reflector. A hologram laser light source comprising a light emitting element provided at a central portion of the 40 to generate a laser beam, and a laser beam generated from the light emitting element is integrated with a light receiving element for receiving the reflected light reflected from the surface of the disk 30. Represents a laser diode. 60 divides the laser beam from the hologram laser diode 30 so that the divided laser beam is reflected by the parabolic reflector 40 at an angle to be collected at a predetermined position of the disk 30 while the disk For setting the path of the laser beam such that the reflected light reflected from the surface of the disk 30 through the parabola reflector 40 is incident on the light receiving element of the hologram laser diode 50. A mirror diffraction grating is shown, and 70 denotes a movable coil for positioning, ie, focusing and tracking, of the hologram laser diode 50 installed at the center of the parabola reflector 40.

The parabolic reflector 40 is formed in a hemispherical shape having a circumferential ratio that is set so that the laser beam diffracted from the mirror diffraction grating 60 is accurately concentrated at a predetermined position of the disc 30, and the mirror diffraction grating 60 is The laser beam generated from the hologram laser diode 50 is reflected by the parabola reflector 40 so as to focus the light accurately at a predetermined position of the disk 30, or the reflected light from the surface of the disk 30 is reflected by the parabola reflector ( The diffraction angle is set so as to be reflected by 40 and accurately received by the light receiving element of the hologram laser diode 50. In addition, the mirror diffraction grating 60 is a central portion of the parabola reflector 40 through the fixing arm 80 extending from the upper peripheral portion of the paraola reflector 40 as shown in FIG. It is located on the hologram laser diode 50.

Further, around the parabola reflector 40, a movable coil 70 is provided for the positional displacement of the hologram laser diode 50 from the hologram laser diode 50 under control from a controller (not shown). The laser beam acts to adjust the angle of the light collected on the surface of the disk 30 in the parabola reflector 40. In other words, the entire structure in which the parabolic reflector 40 is formed acts as an actuator.

According to the optical pickup device having a parabola reflector according to the present invention configured as described above, a laser beam generated from the hologram laser diode 50 is installed on a central portion of the parabola reflector 40 by a fixed arm 80. It is diffracted by a grating 60 at a constant diffraction angle and is incident on the parabolic reflector 40 and then focused on the surface of the disk 30 corresponding to the circumference of the parabola reflector 40.

The amount of reflected light reflected from the surface of the disk 30 is determined by the pit work for information recording formed on the surface of the disk 30, and the reflected light reflected from the disk 30 is reflected by the parabolic reflector 40. The diffraction effect of the mirror diffraction grating 60 is provided to the light receiving element of the hologram laser diode 50 to read information recorded on the disc 30.

When the focusing and tracking of the laser beam on the disc 30 is required during the reading of the information, the parabolic reflector 40 is controlled by the operation of the movable coil 70 under the control of a control device (not shown). Displacement of the formed structure is performed to allow for desired focusing and tracking.

As described above, according to the optical pickup device having a parabola reflector according to the present invention, the laser beam emitted from the hologram laser diode is divided into three beams at the mirror diffraction grating so that the parabola reflector can focus on the surface of the information recording medium directly. By eliminating the need for collimated lenses or objective lenses for converting the laser beam into parallel light, the optical structure of the optical pickup device is remarkably simplified.

Claims (4)

The light which irradiates the laser beam on the surface of the information recording medium 30, receives the reflected light of the laser beam reflected from the surface of the information recording medium 30, and reads the information recorded on the surface of the information recording medium 30. A pickup apparatus, comprising: a laser light source (50) for generating a laser beam: optical diffraction means (60) for dividing and reflecting a laser beam emitted from the hologram laser light source (50) into three beams; The laser light source 50 is mounted at the center, and the laser beam reflected by splitting and reflecting by the optical diffraction means 60 is condensed on the surface of the information recording medium 30, and then on the surface of the information recording medium 30. And a parabola reflector (40) for focusing the reflected light reflected by the optical diffraction means (60) to the laser light source (50). The method of claim 1, wherein the optical diffraction means (60) is characterized in that the mirror is provided in the central portion of the parabola reflector 40 through a fixing arm 80 extending from the upper peripheral portion of the parabola reflector 40 Light up device with parabolic reflector. The optical pickup having a parabola reflector according to claim 1, wherein the parabolic reflector 40 is formed in a hemispherical shape which is displaced by a biasing means 70 provided at a periphery thereof to change the reflection angle of the laser beam. Device. The laser beam source of claim 1, wherein the laser light source 50 comprises a hologram laser diode in which a light emitting element for generating the laser beam and a light receiving element for receiving the reflected light from the disk 30 are integrally formed. Optical pickup device having a parabola reflector, characterized in that focusing meet tracking according to the displacement of 40).