KR20120126766A - Optical pick-up apparatus - Google Patents

Abstract

PURPOSE: An optical pickup device is provided to read out information recorded in recording medium such as a CD(Compact Disk), a DVD(Digital Versatile Disk), and a BD(Blu-ray Disk) and record information in an optical disk. CONSTITUTION: An optical detecting unit(210) detects a reflection light from recording medium as an electrical signal. A collimator lens(150) converts light incident from an optical division unit. The collimator lens is incident to an object lens. The collimator lens condenses the reflection light to the optical detecting unit through the optical division unit. An aberration compensation plate(140) is located between the optical division unit and the collimator lens. The aberration compensation plate compensates the aberration of a light penetrating the light division unit.

Description

Optical pickup device {OPTICAL PICK-UP APPARATUS}

The present specification relates to an optical pickup device.

In general, an optical pickup apparatus according to the prior art reads information recorded on an optical disk such as a compact disk (CD) and a digital versatile disk (DVD) using optical light or records information on the optical disk.

An object of the present specification is to read or write information recorded on a recording medium (optical disk) such as a CD (Compact Disk) and a DVD (Digital Versatile Disk) as well as a Blu-ray Disk (BD). There is provided an optical pickup apparatus capable of recording information.

An optical pickup apparatus according to an embodiment of the present invention for achieving the above object, the first and second light source unit for generating light of different wavelengths; An optical separation unit for reflecting the light generated by the first or second light source to the recording medium and transmitting the reflected light from the recording medium; A light detector, positioned at one side of the optical separation unit, for detecting reflected light from the recording medium as an electrical signal; And a collimating lens for converting the light incident from the optical separation unit in parallel to be incident on the objective lens and condensing the reflected light from the recording medium through the optical separation unit and condensing the optical detection unit. The apparatus may further include an aberration compensation plate positioned between the collimating lenses and compensating for aberration of light passing through the light separation unit.

As an example related to the present invention, an angle between the front and rear surfaces of the aberration compensation plate may be 0.50 to 0.90 degrees.

As an example related to the present invention, an angle between a front side and a rear side of the aberration compensation plate for compensating aberration of light passing through the optical separation unit may be 0.625 degrees.

As an example related to the present invention, the aberration compensation plate may transmit light generated by the first light source unit toward the collimating lens and reflect light generated by the second light source unit toward the collimating lens.

As an example related to the present invention, the collimating lens may be moved according to the different wavelengths.

As an example related to the present invention, the collimating lens may be moved forward or backward by a motor to compensate for spherical aberration caused by thickness variation of the recording medium.

As an example related to the present invention, the compensation lens may further include a collimating lens positioned between the collimating lens and the second light source unit.

As an example related to the present invention, the compensation lens may be a concave lens positioned between the collimating lens and the second light source unit such that a composite focal length with the collimating lens is a reference focal length.

As an example related to the present invention, the apparatus further includes a mirror positioned between the collimating lens and the objective lens, wherein the mirror reflects light transmitted through the collimating lens toward the objective lens and is generated by the second light source unit. It may further include a polarizing plate for converting light into circularly polarized light.

As an example related to the present invention, the apparatus further includes a QWP (Quarter Wave Plate) positioned between the mirror and the objective lens, wherein the QWP may convert light generated by the first light source into circularly polarized light.

As an example related to the present invention, the first light source unit generates light having a wavelength corresponding to a compact disk (CD) or light having a wavelength corresponding to a digital versatile disk (DVD), and the second light source unit has a blue ray disk ( Light of a wavelength corresponding to a Blu-ray Disk) can be generated.

The optical pickup apparatus according to embodiments of the present invention includes information recorded on a recording medium (optical disk) such as a CD (Compact Disk) and a DVD (Digital Versatile Disk) as well as a Blu-ray Disk (BD). Can be read or recorded on the recording medium.

In the optical pickup device according to the embodiment of the present invention, the light of the first light source unit (for example, DVD / CD laser diode) is optically separated by placing an aberration correcting lens having a predetermined angle between the optical separation unit and the collimating lens. In addition to compensating astigmatism and coma aberration generated when passing through the unit, the astigmatism generated in the first light source unit itself may be compensated.

The optical pickup device according to the embodiment of the present invention has the same number of parts of the optical pickup device as the optical paths to the Blu-ray Disk (BD) as well as the CD (Compact Disk) and DVD (Digital Versatile Disk) are the same. It can also be reduced to reduce the size of the optical pickup device.

The optical pickup apparatus according to the embodiment of the present invention is adapted to shift spherical aberration caused by the thickness variation of the recording medium by moving the collimating lens forward or backward according to the thickness variation of the recording medium (Blu-ray Disc, DVD, CD). You can compensate.

The optical pickup apparatus according to the exemplary embodiment of the present invention may compensate for the difference in focus positions according to different wavelengths by moving the collimating lens forward or backward.

1 is a block diagram illustrating an optical disk apparatus to which an optical pickup apparatus according to an exemplary embodiment of the present invention is applied.
2 is a diagram showing the configuration of an optical pickup device according to an embodiment of the present invention.
3 is an exemplary view showing an aberration compensation plate according to an embodiment of the present invention.
4 is an exemplary view showing a change in aberration according to the angle change of the aberration compensation plate according to the embodiment of the present invention.

Hereinafter, information recorded on a recording medium (optical disc) such as a CD (Compact Disk) and a DVD (Digital Versatile Disk) as well as a Blu-ray Disc (BD) is read or read on the recording medium. An optical pickup apparatus capable of recording information will be described with reference to FIGS.

1 is a block diagram illustrating an optical disk apparatus to which an optical pickup apparatus according to an exemplary embodiment of the present invention is applied.

As shown in Fig. 1, the optical disk apparatus to which the optical pickup apparatus according to the embodiment of the present invention is applied includes a recording and reproducing unit for recording data (information) or reproducing the recorded data on a recording medium 400 which is an optical disk ( 10); It may include a first control unit 12 for controlling the recording and playback unit 10.

The recording / reproducing section 10 receives and restores the optical pickup device 300 for recording data on the recording medium 400 or reading the recorded data, and the data read out by the optical pickup device 300. A signal processor 13 for modulating the data into a signal for recording the data on the recording medium 400, and a servo controlling the optical pickup device 300 for reading or recording a signal from the recording medium 400 ( 14), a memory 15 temporarily storing management information and data, and a second controller 16 controlling the above-described elements.

The first control unit 12 controls the above-described elements, and records a recording and reproducing command for recording or reproducing data on the recording medium 400 with reference to a user command or the like through an interface with the user. It transfers to the reproduction | regeneration part 10.

The decoder 17 may decode the data read from the recording medium 400 under the control of the first controller 12, restore the data to desired information, and provide the same to the user.

The encoder 18 converts an input signal into a signal of a specific format, for example, an MPEG 2 transport stream, under the control of the first control unit 12 to perform a function of recording data on the recording medium 400. The signal may be converted and provided to the signal processor 13.

The recording medium 400 is largely read-only-memory (ROM), recordable (R) capable of recording information only once, and repeatable recording of repeatedly writing, reading, and erasing information. It may be a Rewritable (RE) optical disc. As the recording medium 400, a compact disk (CD), a digital versatile disk (DVD), or a blu-ray disk may be used.

2 is a diagram showing the configuration of an optical pickup device according to an embodiment of the present invention.

As shown in FIG. 2, the optical pickup device 300 according to the embodiment of the present invention includes: a first light source unit 110A and a second light source unit 110B for generating light having different wavelengths; The light separation unit 190 reflects the light generated by the first light source unit 110A or the second light source unit 110B toward the recording medium 400 and transmits the light (reflected light) reflected from the recording medium 400. )Wow; A light detector (210) positioned on one side of the optical splitter (190) for detecting reflected light from the recording medium (400) as an electrical signal; The light incident from the optical separation unit 190 is converted into parallel light, the parallel light is incident on the objective lens 180, and the reflected light from the recording medium 400 passes through the optical separation unit 190. A collimating lens (150) for condensing on the light detecting unit (210); An aberration compensation plate (eg, a wedge plate) 140 positioned between the optical separation unit 190 and the collimation lens 150 to compensate for aberration of light passing through the optical separation unit 190 is further included. It can be configured to include. Here, the light generated by the first light source 110A and the second light source 110B may be transmitted through the same path by the aberration compensation plate 140.

The aberration compensation plate 140 may include a plurality of wedge structures, and the aberration compensation plate 140 having the plurality of wedge structures may be disposed between the optical separation unit 190 and the collimation lens 150. And the angle of the aberration compensation plate 140 (the angle between the front and rear surfaces of the aberration compensation plate 140) at a predetermined angle (for example, 0.50 to 0.90 degrees) to form a first light source unit 110A. ) (Eg, a DVD / CD laser diode) to compensate for astigmatism and coma aberration generated when the light passes through the optical separation unit 190, as well as the first light source unit 110A (eg, The astigmatism occurring in the DVD / CD laser diode) itself can also be compensated. An angle between the front and rear surfaces of the aberration compensation plate 140 may be approximately 0.50 to 0.90 degrees.

In addition, the first light source unit not only compensates astigmatism and coma aberration generated when the light of the first light source unit 110A (for example, a DVD / CD laser diode) passes through the optical separation unit 190. To compensate for astigmatism occurring at 110A (eg, a DVD / CD laser diode) itself, the angle between the front and back of the aberration compensation plate 140 may be approximately 0.625 degrees.

Optical pickup device 300 according to an embodiment of the present invention may be composed of the following components. For example, the optical pickup device 300 according to the embodiment of the present invention may include a first light source unit (eg, a laser diode) 110A that generates light having a first wavelength (wavelengths corresponding to CD and DVD). Wow; A first grating element for dividing the generated light; An optical splitter (eg, Beam Spiltter, BS) 190 for separating the split light and the light reflected from the recording medium 400; A second light source unit (for example, a laser diode) 110B for generating light of a second wavelength (wavelength corresponding to a Blu-ray disc); A compensation lens 120 for compensating a focal length; A second grating element (130) for splitting light of the second wavelength; An aberration compensation plate (140) for transmitting the light of the first wavelength, reflecting the light of the second wavelength, and compensating for the aberration of the transmitted light; A collimator lens 150 for converting light output from the first light source 110A or the second light source 110B into parallel light on a path of the light transmitted to the recording medium 400. Wow; A mirror (160) for changing a path of the parallel light; A QWP (Quarter Wave Plate) 170 for converting the modified parallel light into circularly polarized light; An object lens (OL) 180 for condensing the circularly polarized light on the recording medium 400 in a spot shape; A sensor lens (200) for condensing the light reflected from the recording medium (400) in the form of a spot on a cell of the light detector (2100); and the light collected by the sensor lens (200) (reflected from the recording medium (400)). Light detection unit 210 for detecting the light reflected from the recording medium 400 as an electrical signal so as to reproduce the data recorded on the recording medium 400 by detecting the light). The second grating elements 220 and 130 are not essential components and may or may not be installed as necessary.

The first light source unit 110A may generate light having a wavelength corresponding to the CD and light having a wavelength corresponding to the DVD. For example, the first light source 110A generates laser light having a wavelength of approximately 780 nm corresponding to the CD and a wavelength of approximately 650 nm corresponding to the DVD.

The second light source unit 110B may generate light having a wavelength corresponding to the Blu-ray disc. For example, the second light source unit 110B may generate laser light having a wavelength of about 405 nm as a wavelength for a Blu-ray disc.

The first and second grating elements 220 and 130 are optical elements that split light into three (three beams) by constructive and destructive interference using a diffraction phenomenon of light. The first grating element 220 may further include a half wave plate 220-1 for converting the wavelength of the light generated by the first light source 110A.

The optical separation unit 190 changes the path of the light passing through the first grating element 220, transfers the light generated by the first light source unit 110A to the recording medium 400, and the recording medium ( The light reflected from the 400 is transmitted to the light detector 210.

The compensation lens 120 may be additionally positioned between the second grating element 120 and the second light source unit 110B such that the composite focal length with the collimating lens 150 is a reference focal length. The compensating lens 120 may be a concave lens for allowing the composite focal length with the collimating lens 150 to be the reference focal length.

In general, as the focal length of the collimating lens 150 is shorter, the distance from the collimating lens 150 to the light detector 210 may be reduced, thereby reducing the size of the optical pickup device. On the other hand, in consideration of light efficiency due to the light emission angle of the second light source 110B (laser diode), the collimation lens 150 having a focal length suitable for the second light source 110B (laser diode) should be used. There is a limit to the size. To solve this problem, the focal length of the collimating lens 150 is shorter than the reference focal length, and the second light source unit 110B is configured such that the combined focal length of the concave lens 120 and the collimating lens 150 becomes the reference focal length. The condensation lens 120 is positioned between the second grating element 130 and the second grating element 130.

Accordingly, by placing the concave lens 120 between the second light source 110B and the second grating element 130, the size of the optical pickup device may be reduced without reducing the light efficiency.

The aberration compensation plate 140 transmits the light of the first wavelength, reflects the light of the second wavelength, and compensates for the sagittal coma and astigmatism aberrations of the transmitted light. Has a preset angle. For example, the aberration compensation plate 140 may be positioned between the optical separation unit 190 and the collimation lens 150, and may be disposed between the front (front) and rear (rear) surfaces of the aberration compensation plate 140. When the light of the first light source 110A (for example, DVD / CD laser diode) passes through the optical separation unit 190 by forming the angle at a predetermined angle (for example, approximately 0.50 to 0.90 degrees). In addition to compensating astigmatism and coma aberration generated, astigmatism generated in the first light source 110A (eg, a DVD / CD laser diode) itself may be compensated.

3 illustrates an aberration compensation plate 140 according to an embodiment of the present invention.

)(예를 들면, 대략 0.50~0.90도)를 갖는 수차 보상 플레이트(140)를 상기 광 분리부(190)와 상기 시준 렌즈(150) 사이에 위치시킴으로써 제1 광원부(110A)(예를 들면, DVD/CD 레이저 다이오드)의 광이 상기 광 분리부(190)를 투과할 때 발생하는 비점수차, 코마 수차를 보상할 뿐만 아니라 상기 제1 광원부(110A)(예를 들면, DVD/CD 레이저 다이오드) 자체에서 발생하는 비점 수차도 보상할 수 있다. 즉, 상기 수차 보상 플레이트(140)의 앞면과 뒷면 사이의 각도를 변경함으로써 상기 비점 수차 및 코마 수차를 상기 비점 수차 및 코마 수차에 적응적으로 반비례하는 수차로 보상할 수 있다.As shown in Fig. 3, the predetermined angle (

(A, for example, approximately 0.50 to 0.90 degrees) by placing the aberration compensation plate 140 between the optical separation unit 190 and the collimation lens 150 to provide the first light source unit 110A (eg, In addition to compensating astigmatism and coma aberration generated when the light of the DVD / CD laser diode passes through the optical separation unit 190, the first light source unit 110A (for example, the DVD / CD laser diode) It can also compensate for astigmatism occurring in itself. That is, by changing the angle between the front and rear of the aberration compensation plate 140, the astigmatism and coma aberration can be compensated by the aberration adaptively inversely proportional to the astigmatism and coma aberration.

4 is an exemplary view showing a change in aberration according to the angle change of the aberration compensation plate according to the embodiment of the present invention.

As shown in FIG. 4, it can be seen that the astigmatism 4-1 and the coma aberration 4-2 change according to the angle change of the aberration compensation plate 140. Thus, the light of the first light source 110A (eg, DVD / CD laser diode) is transmitted through the aberration compensation plate 140 having the predetermined angle (eg, approximately 0.625 degree). In addition to compensating astigmatism and coma aberration generated when passing through 190, the astigmatism generated in the first light source 110A (eg, a DVD / CD laser diode) itself may be compensated.

The collimating lens 150 converts the light generated by the first light source unit 110A or the second light source unit 110B into parallel light. For example, the data recording efficiency of the recording medium 400 is improved by converting the scattered light generated by the first light source 110A or the second light source 110B into parallel light through the collimating lens 150. You can.

The collimating lens 150 is forward or rearward by a motor (for example, a stepping motor) (not shown) to compensate for spherical aberration caused by the thickness variation of the recording medium (Blu-ray Disc, DVD, CD). Can be moved to. That is, the motor compensates for the spherical aberration by moving the position of the collimating lens 150 according to the type of the recording medium (Blu-ray Disc, DVD, CD) based on the control signal of the second controller 16. .

 In addition, the second control unit 16 adjusts the position of the collimation lens 150 to the wavelength of each of the wavelengths in order to correct the difference in the chromatic aberration generated in the light receiving system according to the wavelength difference of the light corresponding to the Blu-ray Disc, DVD, CD. By moving in accordance with the above, light corresponding to the Blu-ray Disc, DVD and CD is condensed at the same position in the optical axis direction of the light detector 210.

The mirror 160 reflects light transmitted through the collimating lens 150 to change a path of light transmitted through the collimating lens 150. That is, the mirror 160 injects the light transmitted through the collimating lens 150 into the recording medium 400. Here, the mirror 160 may be provided as a phase delay mirror that delays the phase of the incident light, which is configured to generate a phase difference of 90 degrees or 270 degrees with respect to the vertical and horizontal polarization when the light is incident at a specific angle. Can be.

The phase delay mirror may delay the phase of incident light by forming a polarization layer for delaying the phase of light on the surface of the mirror that changes the path of the light. For example, by converting light into circularly polarized light using the phase delay mirror, the recording characteristics and the noise characteristics of the recording medium 400 are relatively improved. The mirror 160 may include a polarizer for converting light generated by the first light source 110A or the second light source 110B into circularly polarized light.

The light whose path is changed by the mirror 160 is condensed on the recording medium 400 by the objective lens 180. That is, the objective lens 180 condenses the light incident by the mirror 160 on the recording medium 400 in the form of a spot. Light irradiated to the recording medium 400 by the objective lens 180 may form a pit on the recording medium 400 to record data or may be reflected by the formed pit.

The objective lens 180 may be provided in a bobbin (not shown) constituting an actuator (not shown) of the optical pickup device, and the objective lens 180 may be configured to track, The incident light may be irradiated onto the recording medium 400 as it is moved for the focusing operation.

A QWP (Quarter Wave Plate) 170 may be further provided between the mirror 160 and the objective lens 180 to convert the changed parallel light into circular polarized light. For example, the QWP (Quarter Wave Plate) 170 is generated by the first light source unit 110A in order to increase the efficiency of the reflected light (reflected light of the recording medium 400) incident on the light detector 210. Light and / or light generated by the second light source unit 110B is converted into circularly polarized light.

On the other hand, the light (reflected light) reflected from the recording medium 400 is moved to the reverse path of the path that the light is transmitted from the first light source unit 110A or the second light source unit 110B to the recording medium 400, the light separation unit Is passed to 190.

The optical separation unit 190 transmits the light (reflected light) reflected from the recording medium 400 to the optical detection unit 210. That is, the light reflected by the Blu-ray Disc, the light reflected by the DVD, and the light reflected by the CD pass through the same path and are concentrated on the light detector 210.

The sensor lens 200 may be additionally installed between the light separation unit 190 and the light detection unit 210. The sensor lens 200 causes the light (reflected light) reflected from the recording medium 400 to be focused on the light detector 210 in the form of a spot.

The light detector 210 may be configured of a plurality of photodiodes to convert light reflected from the recording medium 400 into an electrical signal. The light detector 210 may configure a plurality of cells to detect light collected by the sensor lens 200.

Since the grating element, the light detector, and the light separator are also disclosed in Patent Application No. 10-2005-0128473 filed in Korea by the applicant of the present application, a detailed description thereof will be omitted.

Hereinafter, the operation of the optical pickup apparatus will be described based on the light of the wavelength corresponding to the CD or the light of the wavelength corresponding to the DVD.

First, the first light source 110A generates light having a wavelength corresponding to CD or light having a wavelength corresponding to DVD.

The first grating element 220 divides the light generated by the first light source unit 110A, and applies the divided light to the light separation unit 190. The first grating element 220 may further include a half wave plate 220-1 for converting the wavelength of the light generated by the first light source 110A.

The optical separation unit 190 applies the light passing through the first grating element 220 to the aberration compensation plate 140.

The aberration compensation plate 140 transmits light generated by the first light source unit 110A, and astigmatism generated when the light generated by the first light source unit 110A passes through the light separation unit 190. In addition, coma aberration is compensated for, and astigmatism generated in the first light source 110A (for example, a DVD / CD laser diode) itself is compensated for.

The collimating lens 150 converts the light transmitted through the aberration compensation plate 140 into parallel light. The collimating lens 150 is a motor (eg, stepping motor) (not shown) to compensate for spherical aberration caused by thickness variation of a recording medium (eg, Blu-ray Disc, DVD, CD). It can be moved forward or backward by That is, the motor moves the position of the collimating lens 150 according to the type of recording medium (Blu-ray Disc, DVD, CD) based on the control signal of the second control unit 16 (recording medium 400). Compensation by spherical aberration adaptively inversely proportional to the change in thickness) of the recording medium 400.

The mirror 160 reflects the light transmitted through the collimating lens 150 to allow the light transmitted through the collimating lens 150 to enter the QWP (Quarter Wave Plate) 170.

The QWP (Quarter Wave Plate) 170 converts the parallel light reflected by the mirror 160 into circularly polarized light and injects the circularly polarized light into the objective lens 180.

The objective lens 180 condenses the circularly polarized light on the recording medium 400 in the form of a spot.

On the other hand, the light (reflected light) reflected from the recording medium (for example, CD or DVD) 400 is the objective lens 180, the QWP (Quarter Wave Plate) 170, the mirror 160, the The collimating lens 150 and the aberration compensating plate 140 are transmitted to the optical separation unit 190.

The optical separation unit 190 transmits the light (reflected light) reflected from the recording medium 400 to the optical detection unit 210. That is, the light reflected by the Blu-ray Disc, the light reflected by the DVD, and the light reflected by the CD pass through the same path and are concentrated on the light detector 210.

The sensor lens 200 may be installed between the light separation unit 190 and the light detection unit 210. The sensor lens 200 causes the light (reflected light) reflected from the recording medium 400 to be focused on the light detector 210 in the form of a spot.

The light detector 210 detects the light reflected from the recording medium 400 as an electrical signal.

Hereinafter, the operation of the optical pickup device will be described based on the light of the wavelength corresponding to the Blu-ray Disc.

First, the second light source unit 110B generates light having a wavelength corresponding to a Blu-ray disc, and applies the generated light to the compensation lens 120.

The compensation lens 120 is additionally positioned between the second grating element 120 and the second light source unit 110B such that the composite focal length with the collimating lens 150 is a reference focal length. The compensating lens 120 may be a concave lens for allowing the composite focal length with the collimating lens 150 to be the reference focal length.

The second grating element 130 divides (eg, three beams) light generated by the second light source unit 110B, and applies the divided light to the aberration compensation plate 140.

The aberration compensation plate 140 reflects the light applied by the second grating element 130 toward the collimating lens 150.

The collimating lens 150 converts the light generated by the second light source unit 110B into parallel light. For example, data recording efficiency in the recording medium 400 may be improved by converting the scattered light generated by the second light source unit 110B into parallel light through the collimating lens 150.

The collimating lens 150 is forwarded by the motor (for example, a stepping motor) (not shown) to compensate for spherical aberration caused by the thickness variation of the recording medium (Blu-ray Disc, DVD, CD). Or may be moved backwards. That is, the motor compensates for the spherical aberration by moving the position of the collimating lens 150 according to the type of the recording medium (Blu-ray Disc, DVD, CD) based on the control signal of the second controller 16. .

 In addition, the second control unit 16 moves the position of the collimation lens 150 according to each wavelength in order to correct the difference in the chromatic aberration according to the wavelength difference of the light corresponding to the Blu-ray Disc, DVD, CD. , The light corresponding to the Blu-ray Disc, DVD, and CD is condensed at the same position in the optical axis direction of the light detector 210.

The mirror 160 changes the path of the light transmitted through the collimating lens 150 by reflecting the light transmitted through the collimating lens 150. That is, the mirror 160 enters the light passing through the collimating lens 150 into the objective lens 180 through the QWP (Quarter Wave Plate) 170. Here, the mirror 160 may be provided as the phase delay mirror, which may cause the phase difference to occur at 90 degrees or 270 degrees with respect to the vertical and horizontal polarization when light is incident at a specific angle. For example, by converting the light generated by the second light source unit 110B into circularly polarized light through the phase delay mirror, the recording characteristics and the noise characteristics of the recording medium 400 are relatively improved.

The objective lens 180 condenses the light whose path is changed by the mirror 160 on the recording medium 400.

On the other hand, the light (reflected light) reflected from the recording medium (for example, Blu-ray disc) 400 is the objective lens 180, the QWP (Quarter Wave Plate) 170, the mirror 160, the The collimating lens 150 and the aberration compensating plate 140 are transmitted to the optical separation unit 190.

The optical separation unit 190 transmits the light (reflected light) reflected from the recording medium 400 to the optical detection unit 210. That is, the light reflected by the Blu-ray Disc, the light reflected by the DVD, and the light reflected by the CD pass through the same path and are concentrated on the light detector 210.

The sensor lens 200 may be additionally installed between the light separation unit 190 and the light detection unit 210. The sensor lens 200 condenses the light (reflected light) reflected from the recording medium 400 to the light detector 210 in the form of a spot.

The light detector 210 detects the light reflected from the recording medium 400 as an electrical signal.

As described above, the optical pickup apparatus according to the embodiment of the present invention is not only a compact disk (CD) and a digital versatile disk (DVD), but also a recording medium (optical disk) such as a Blu-ray disk (BD). Information can be read or recorded on the recording medium.

In the optical pickup device according to the embodiment of the present invention, by placing the aberration correcting lens having a predetermined angle between the optical separation unit and the collimation lens, the light of the first light source unit 110A (for example, DVD / CD laser diode) It not only compensates for astigmatism and coma aberration generated when passing through the optical separation unit 190, but also compensates for astigmatism generated in the first light source unit 110A (for example, a DVD / CD laser diode) itself. can do.

The optical pickup device according to the embodiment of the present invention has the same number of parts of the optical pickup device as the optical paths to the Blu-ray Disk (BD) as well as the CD (Compact Disk) and DVD (Digital Versatile Disk) are the same. It can also be reduced to reduce the size of the optical pickup device.

An optical pickup apparatus according to an embodiment of the present invention, by moving the collimating lens 150 to the front or rear in accordance with the thickness variation of the recording medium (Blu-ray Disc, DVD, CD), the recording medium (Blu-ray Disc, DVD) , CD) can compensate for spherical aberration caused by thickness variation of CD).

In the optical pickup device according to the embodiment of the present invention, by moving the collimating lens 150 to the front or rear, the difference in the focus position according to the different wavelengths (wavelength of light generated by the first light source unit and the second light source unit) You can also compensate.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

110A: first light source unit 110B: second light source unit
120: compensation lens 130: second grating element
140: aberration compensation plate 150: collimation lens
160: mirror 170: wave plate (QWP)
180: objective lens 190: optical separation unit
200: sensor lens 210: light detector

Claims (11)

First and second light source units generating light having different wavelengths;
An optical separation unit for reflecting the light generated by the first or second light source to the recording medium and transmitting the reflected light from the recording medium;
A light detector, positioned at one side of the optical separation unit, for detecting reflected light from the recording medium as an electrical signal;
And a collimating lens for converting the light incident from the optical separation unit in parallel to enter the objective lens, and condensing the reflected light from the recording medium through the optical separation unit and condensing the optical detection unit,
And an aberration compensation plate positioned between the optical separation unit and the collimating lens and compensating for aberration of light passing through the optical separation unit. The optical pickup apparatus of claim 1, wherein an angle between the front surface and the rear surface of the aberration compensation plate is 0.50 to 0.90 degrees. The optical pickup apparatus of claim 1, wherein an angle between a front side and a rear side of the aberration compensation plate for compensating aberration of light passing through the optical separation unit is 0.625 degrees. The aberration compensation plate of claim 1, wherein
Transmits the light generated by the first light source to the collimating lens,
And the light generated by the second light source is reflected toward the collimating lens. The method of claim 1, wherein the collimating lens,
Optical pickup device, characterized in that moved according to the different wavelengths. The method of claim 1, wherein the collimating lens,
An optical pickup apparatus characterized by being moved forward or backward by a motor to compensate for spherical aberration caused by the thickness variation of the recording medium. The optical pickup apparatus of claim 1, further comprising a compensating lens positioned between the collimating lens and the second light source unit. The method of claim 7, wherein the compensation lens,
And a concave lens positioned between the collimating lens and the second light source unit such that a combined focal length with the collimating lens becomes a reference focal length. The method of claim 1,
And a mirror positioned between the collimating lens and the objective lens, wherein the mirror reflects the light passing through the collimating lens toward the objective lens and converts the light generated by the second light source into circularly polarized light. Optical pickup device further comprises. The optical pickup of claim 9, further comprising a QWP (Quarter Wave Plate) positioned between the mirror and the objective lens, wherein the QWP converts light generated by the first light source into circularly polarized light. Device. The method of claim 1, wherein the first light source unit generates light having a wavelength corresponding to a compact disk (CD) or a light having a wavelength corresponding to a digital versatile disk (DVD), and the second light source unit has a Blu-ray disc (Blu−). optical pickup device for generating light having a wavelength corresponding to a ray disk).

Images