JP2010020828A - Liquid crystal optical element, optical pickup apparatus, and optical disk apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid crystal optical element, an optical pickup apparatus and an optical disk apparatus which correct aberration with high accuracy even when a plurality of laser beams are emitted from the same plane to reduce arrangement space. <P>SOLUTION: The liquid crystal optical element includes: transparent electrodes 144 and 146 irradiated with a first laser beam and a second laser beam different from the first laser beam and emitted from the same plane, and a liquid crystal molecular layer 142 to which a voltage is applied by the transparent electrodes. The transparent electrodes are positioned by a first electrode pattern 152 which corrects aberration of the first laser beam and a second electrode pattern 154 whose center position is different from the first electrode pattern, and which corrects aberration of the second laser beam. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a liquid crystal optical element, an optical pickup device, and an optical disc device.

  The optical disc apparatus reads information recorded on an optical disc (optical recording medium) such as a CD, DVD, or Blu-ray disc, and writes information on the optical disc. An optical disc apparatus includes an optical pickup device including a light emitting unit that irradiates a laser beam toward the optical disc, an optical system that focuses the laser beam on the recording surface of the optical disc, and a light receiving unit that receives the laser beam reflected from the optical disc. Have.

  In recent years, recording data on an optical disc has been required to have a higher density, and a light spot formed on the recording surface of the optical disc has been required to have a smaller diameter. However, aberrations occur due to the effects of manufacturing errors of the optical pickup device and the tilt of the optical disc when the optical disc is mounted on the optical disc device, and the diameter of the light spot is enlarged, so that accurate data recording or reproduction is possible. There was a problem that became difficult.

  Therefore, there is a case where a liquid crystal optical element capable of correcting aberration is arranged on the optical path of laser light between the light emitting unit and the optical disc. The liquid crystal optical element includes a transparent electrode and a liquid crystal molecular layer. When the transparent electrode applies a voltage to the liquid crystal molecular layer, the orientation of the liquid crystal molecules in the liquid crystal molecular layer changes, and the refractive index changes. The aberration is corrected by transmitting the laser light through the liquid crystal optical element.

  For example, Patent Documents 1 and 2 disclose techniques for correcting laser light using a liquid crystal optical element.

JP 2005-122828 A JP 2005-267790 A

  By the way, the optical disk apparatus has a light emitting unit that emits a plurality of laser beams, and can record or reproduce data corresponding to a plurality of types of optical disks such as a DVD and a Blu-ray disk. There is. In such an optical disc apparatus, the generated aberration differs depending on each of the plurality of laser beams. Therefore, the aberration cannot be corrected only by using a conventional liquid crystal optical element. Therefore, Patent Document 1 discloses a technique of a liquid crystal optical element corresponding to a plurality of laser beams.

  However, in the liquid crystal optical element of the technique described in Patent Document 1, the centers of the light spots formed by the light beams of the plurality of laser beams formed on the surface of the liquid crystal optical element need to coincide with each other. In the case of deviation, there is a problem that the aberration cannot be corrected appropriately. In order to realize the function of the liquid crystal optical element of Patent Document 1, it is necessary to accurately adjust the irradiation directions of a plurality of laser beams. Alternatively, it is necessary to strictly adjust the installation position of the liquid crystal optical element in the optical axis direction of the laser beam. Therefore, it is difficult to adjust the irradiation direction of the laser light in a light emitting part in which a plurality of laser light emitting elements are installed on the same substrate, and the liquid crystal optical element of Patent Document 1 cannot be applied. .

  Further, by applying a light emitting portion in which a plurality of light emitting elements for laser light are installed on the same substrate to the optical pickup device, the optical pickup device can be thinned. However, since the liquid crystal optical element of Patent Document 1 cannot be applied, a plurality of laser light emitting elements are dispersedly arranged on different substrates. Patent Document 2 discloses a technique for reducing the thickness of an optical pickup device by applying a liquid crystal optical element that corrects the aberration of one laser beam and arranging the liquid crystal optical element in an inclined manner.

  However, when the liquid crystal optical element is tilted, the correction amount for aberration correction changes depending on the incident angle of the laser beam.

  Therefore, the present invention has been made in view of the above problems, and an object of the present invention is to correct aberrations accurately even when the arrangement space is reduced by emitting a plurality of laser beams from the same surface. It is an object of the present invention to provide a new and improved liquid crystal optical element, an optical pickup device, and an optical disc device that can be used.

  In order to solve the above-described problem, according to one aspect of the present invention, a transparent electrode irradiated with a first laser beam emitted from the same plane and a second laser beam different from the first laser beam; A liquid crystal molecular layer to which a voltage is applied by the transparent electrode, wherein the transparent electrode has a center position different from the first electrode pattern for correcting the aberration of the first laser beam, and the second electrode pattern. A liquid crystal optical element arranged by a second electrode pattern that corrects the aberration of the laser beam is provided.

  The center of the first light spot formed in the transparent electrode surface by the first laser light coincides with the center of the first electrode pattern, and the first laser beam is formed in the transparent electrode surface by the second laser light. The center of the second light spot may coincide with the center of the second electrode pattern.

  When the wavelength of the first laser beam is longer than that of the second laser beam, the second electrode pattern has a circular shape, and the first electrode pattern may be positioned inside the circular shape of the second electrode pattern. Good.

  The second electrode pattern may be formed in the transparent electrode surface by a second laser beam.

  Moreover, in order to solve the said subject, according to another viewpoint of this invention, The light emission part which light-emits 1st laser beam and 2nd laser beam different from 1st laser beam from the same surface, A voltage is applied by the objective lens for condensing the first laser beam and the second laser beam on the surface of the recording medium, the transparent electrode irradiated with the first laser beam and the second laser beam, and the transparent electrode. The transparent electrode has a center position different from that of the first electrode pattern for correcting the aberration of the first laser beam and the first electrode pattern. There is provided an optical pickup device arranged by a second electrode pattern for correcting aberration of laser light.

  The light emitting unit may emit one or more other laser beams in addition to the first laser beam and the second laser beam from the same plane.

  Moreover, in order to solve the said subject, according to another viewpoint of this invention, The light emission part which light-emits 1st laser beam and 2nd laser beam different from 1st laser beam from the same surface, A voltage is applied by the objective lens for condensing the first laser beam and the second laser beam on the surface of the recording medium, the transparent electrode irradiated with the first laser beam and the second laser beam, and the transparent electrode. The transparent electrode has a center position different from that of the first electrode pattern for correcting the aberration of the first laser beam and the first electrode pattern. There is provided an optical disk device arranged by a second electrode pattern for correcting aberration of laser light.

  According to the present invention, even when the arrangement space is reduced by emitting a plurality of laser beams from the same surface, aberration correction can be performed with high accuracy.

  Exemplary embodiments of the present invention will be described below in detail with reference to the accompanying drawings. In addition, in this specification and drawing, about the component which has the substantially same function structure, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol.

  First, an optical disc device 100 according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing a configuration of an optical disc apparatus 100 according to the present embodiment.

  As shown in FIG. 1, the optical disc apparatus 100 includes an optical pickup 102, a spindle motor 104 that rotationally drives an optical disc (optical recording medium) 10, a feed motor 106, a drive control unit 108, a signal processing unit 110, The signal modulation / demodulation unit 112, the system controller 114, and the operation unit 116 are included.

  The optical pickup 102 is an example of an optical pickup device, and irradiates the optical disc 10 with laser light or receives light reflected by the optical disc 10. As will be described later with reference to FIG. 2 and the like, the optical pickup 102 includes an objective lens 132, a biaxial actuator (not shown) that drives the objective lens 132, a light emitting unit 122 (for example, a laser diode), and a light receiving element (for example, a photo). A diode 138).

The spindle motor 104 receives a drive signal from the drive control unit 108. The spindle motor 104 rotationally drives a disk table (not shown) on which the optical disk 10 is placed at a predetermined speed. As a result, the optical disk 10 rotates around the center of the optical disk 10.
The feed motor 106 receives a drive signal from the drive control unit 108. The feed motor 106 moves the optical pickup 102 in the radial direction (radial direction) of the optical disc 10 via the feed mechanism. When the optical pickup 102 is moved to a predetermined position, recording and reproduction of predetermined data can be performed.

The drive control unit 108 receives a tracking error signal and a focus error signal from the system controller 114 and generates a drive signal related to driving of the biaxial actuator of the optical pickup 102. The drive control unit 108 sends the generated drive signal to the biaxial actuator of the optical pickup 102.
Further, the drive control unit 108 receives a control signal from the system controller 114 and generates drive signals related to driving of the light emitting unit 122 of the optical pickup 102, the spindle motor 104, and the feed motor 106. The drive control unit 108 sends the generated drive signal to the light emitting unit 122, the spindle motor 104, and the feed motor 106.

  The signal processing unit 110 receives an output signal based on the reflected light of the laser light from the optical pickup 102. The signal processing unit 110 performs signal processing such as converting the received signal from an analog signal to a digital signal and amplifying the signal. The signal processing unit 110 sends a signal generated by signal processing to the signal modulation / demodulation unit 112 and the drive control unit 108.

  The signal modulation / demodulation unit 112 receives a signal from the signal processing unit 110 and performs signal demodulation processing during data reproduction. Further, the signal modulation / demodulation unit 112 performs signal modulation processing based on a signal received from the outside during data recording, and sends the processed signal to the signal processing unit 110.

The system controller 114 performs input / output of signals with the operation unit 116. Further, the output signal output from the signal modulation / demodulation unit 112 is input to the system controller 114. The system controller 114 generates a tracking error signal and a focus error signal based on the output signal output from the signal modulation / demodulation unit 112. The system controller 114 sends the generated tracking error signal and focus error signal to the drive control unit 108.
Further, the system controller 114 generates a control signal for controlling the light emitting unit 122, the spindle motor 104, and the feed motor 106 based on the output signal output from the signal modulation / demodulation unit 112. The system controller 114 sends the generated control signal to the drive control unit 108.

  Hereinafter, the operation of the optical disc apparatus 100 having the above configuration will be described. At the time of data recording, digital data input from an external computer (not shown) through an interface is modulated by an error correction code (ECC) added by the signal modulation / demodulation unit 112. Based on the modulated digital data, pulses are generated by a drive control unit 108 that controls laser light, and the optical disk 10 is irradiated with laser light via the optical pickup 102, whereby digital data is recorded. Further, servo control is appropriately performed by the drive control unit 108.

  On the other hand, at the time of data reproduction, when the optical disk 10 is irradiated with laser light, the return reflected light is detected by the photodiode 138 of the optical pickup 102. The reflected light detected by the photodiode 138 is amplified, waveform equalized, and the like calculated by the signal processing unit 110, the reproduced signal is reproduced, and a bit string in which the reproduced signal is binarized is generated. The generated bit string is subjected to signal demodulation and error correction by the signal modulation / demodulation unit 112. The demodulated signal is separated into video data and audio data by video / audio processing in the system controller 114, and is subjected to D / A conversion and analog output. During the data reproduction, the drive control unit 108 performs servo control as appropriate.

  Next, the configuration of the optical pickup 102 according to the present embodiment will be described with reference to FIG. FIG. 2 is an explanatory diagram showing the configuration of the optical pickup 102 according to the present embodiment. FIG. 3 is a cross-sectional view showing the liquid crystal optical element 120 according to this embodiment, in which each component is shown divided and separated.

  As shown in FIG. 2, the optical pickup 102 includes, for example, a liquid crystal optical element 120, a light emitting unit 122, a collimator lens 126, a beam splitter 128, a quarter wavelength plate 130, an objective lens 132, and an adjustment lens. 136, a photodiode 138, and the like.

  The liquid crystal optical element 120 corrects aberrations caused by the manufacturing error of the optical pickup 102 and the tilt of the optical disc 10 when the optical disc 10 is placed on the optical disc apparatus 100. The liquid crystal optical element 120 is disposed on the optical path of laser light between the light emitting unit 122 and the optical disc 10. As shown in FIG. 3, the liquid crystal optical element 120 includes a liquid crystal molecular layer 142, transparent electrodes 144 and 146, a glass substrate 148, and the like. When the transparent electrodes 144 and 146 apply a voltage to the liquid crystal molecule layer 142, the orientation of the liquid crystal molecules in the liquid crystal molecule layer 142 changes, and the refractive index changes. The aberration is corrected by the laser light passing through the liquid crystal optical element 120. The liquid crystal optical element 120 sandwiches a liquid crystal molecular layer 142 and two transparent electrodes 144 and 146 between two glass substrates 148. The two transparent electrodes 144 and 146 sandwich the liquid crystal molecular layer 142.

  The light emitting unit 122 includes, for example, two laser diodes (light emitting elements) (hereinafter also referred to as a first laser diode and a second laser diode). The light emitting unit 122 receives the drive signal from the drive control unit 108 and emits laser light to the optical disc 10. The two laser diodes are installed in the same plane (for example, on the same substrate) in the light emitting unit 122. The two laser diodes emit laser light in the same direction. The installation interval between the two laser diodes is set to a predetermined interval.

  The collimator lens 126 converts the laser light emitted from the light emitting unit 122 into parallel light. The laser light output after passing through the collimator lens 126 becomes parallel light up to the objective lens 132.

  The beam splitter 128 has light transmission characteristics corresponding to the polarization direction of light incident on the beam splitter 128. The beam splitter 128 transmits the laser beam emitted from the light emitting unit 122 as it is to the optical disc 10 side. The beam splitter 128 reflects the return light of the laser beam reflected by the optical disc 10 toward the photodiode 138 side.

  The quarter-wave plate 130 converts laser light incident in a linearly polarized state from the light emitting unit 122 side into a circularly polarized state. The quarter-wave plate 130 converts the return light of the laser beam incident from the optical disc 10 side in a circular polarization state into a linear polarization state.

  The objective lens 132 is driven while tracking control and focus control are performed by a biaxial actuator. The objective lens 132 condenses the laser light emitted from the light emitting unit 122 on the optical disc 10. The objective lens 132 can focus laser light on the optical disk 10 as a light spot.

  The biaxial actuator is a drive device that causes the objective lens 132 to follow the optical disk 10 that rotates at high speed. The biaxial actuator receives a drive signal from the drive control unit 108. The biaxial actuator can drive the objective lens 132 in the biaxial direction of the focus direction and the tracking direction. The biaxial actuator adjusts the focus of the laser beam on the data recording surface of the optical disc 10. The driving of the objective lens 132 is not limited to the biaxial actuator 118. A triaxial actuator may be used. At this time, the triaxial actuator not only performs focus control and tracking control of the objective lens, but also performs tilt control.

  The adjustment lens 136 condenses the light output from the beam splitter 128 on the photodiode 138.

  The photodiode 138 is an example of a light receiving element, and receives the reflected light of the laser light reflected by the optical disc 10. The photodiode 138 converts the received laser light into an electrical signal and outputs the signal to the signal processing unit 110.

  Next, the electrode pattern of the transparent electrodes 144 and 146 in the liquid crystal optical element 120 according to the present embodiment will be described. 4 to 8 are plan views showing the liquid crystal optical element 120 of the present embodiment.

  In the liquid crystal optical element 120, transparent electrodes 144 and 146 are arranged in an electrode pattern as shown in FIGS. The transparent electrodes 144 and 146 have a first electrode pattern that corrects aberrations that occur in the first laser light emitted from the first laser diode provided in the light emitting unit 122. In addition, the transparent electrodes 144 and 146 have a second electrode pattern that corrects an aberration generated in the second laser light emitted from the second laser diode provided in the light emitting unit 122.

  The first electrode pattern or the second electrode pattern has a predetermined shape corresponding to an aberration to be corrected, for example, coma aberration, astigmatism, spherical aberration, or the like. The transparent electrodes 144 and 146 correct aberration generated in the first laser light or the second laser light according to a predetermined shape of the first electrode pattern or the second electrode pattern. Thereby, the light spot formed on the optical disc 10 becomes a light spot with corrected aberration. The correction amount of the aberration corrected by the transparent electrodes 144 and 146 is adjusted according to the voltage value applied by the transparent electrodes 144 and 146.

  The first electrode pattern is formed by the transparent electrode 144 or the transparent electrode 146, and the second electrode pattern may be formed by the transparent electrode 146 or the transparent electrode 144 on which the first electrode pattern is not formed. Good. Alternatively, both the first electrode pattern and the second electrode pattern may be formed on either the transparent electrode 144 or the transparent electrode 146, and the electrode pattern may not be formed on the other transparent electrode.

  Further, the first electrode pattern and the second electrode pattern are arranged such that the center positions thereof do not coincide with each other and the center positions are different. The liquid crystal optical element 120 is arranged so that the center of the first light spot formed in the surface of the liquid crystal optical element 120 by the light flux of the first laser light coincides with the center point of the first electrode pattern. . Further, the liquid crystal optical element 120 is arranged so that the center of the second light spot formed in the surface of the liquid crystal optical element 120 by the light flux of the second laser light coincides with the center point of the second electrode pattern. Is done.

  The distance between the center of the first electrode pattern and the center of the second electrode pattern is determined by the distance between the center of the first light spot and the center of the second light spot. In addition, the distance between the center of the first light spot and the center of the second light spot is the distance between the first laser diode and the second laser diode in the light emitting unit 122, and the first laser light and the second laser. It is determined by the wavelength of light, the distance between the light emitting unit 122 and the liquid crystal optical element 120, and the like.

  When the liquid crystal optical element 120 is installed in the optical pickup 102, first, the liquid crystal optical element 120 is installed at a predetermined position so as to be perpendicular to the optical axis in the optical axis direction of the laser beam. Then, the liquid crystal optical element 120 is moved in the plane so that the center of the first electrode pattern coincides with the center of the first light spot. Next, the liquid crystal optical element 120 is rotated in the plane so that the center of the second electrode pattern coincides with the center of the second light spot. Thereby, the liquid crystal optical element 120 can be quickly installed at an appropriate position.

  The installation direction of the first laser diode and the second laser diode of the light emitting unit 122 and the in-plane inclination of the liquid crystal optical element 120 to be finally installed are uniquely determined. Therefore, at the stage where the liquid crystal optical element 120 is placed on the optical axis of the laser light, the in-plane inclination of the liquid crystal optical element 120 is taken into consideration and the installation directions of the first laser diode and the second laser diode of the light emitting unit 122 are taken into consideration. If the liquid crystal optical element 120 is moved in the plane, the center of the first electrode pattern and the center of the first light spot are aligned with each other. The center of the second electrode pattern and the center of the second light spot can be simultaneously matched without rotating in the plane.

  Example 1 shown in FIG. 4 is an example of an electrode pattern for correcting coma aberration. In the liquid crystal optical element 120, for example, an electrode pattern 152 (first electrode pattern) is formed on the transparent electrode 144, and an electrode pattern 154 (second electrode pattern) is formed on the transparent electrode 146. The electrode pattern 152 is formed by arranging two substantially elliptical shapes symmetrically around the center point A, and the electrode pattern 154 is formed by arranging two substantially elliptical shapes symmetrically around the central point B. . The center point A and the center point B have a predetermined interval. In the first embodiment, the size of the ellipse of the electrode pattern 152 and the size of the ellipse of the electrode pattern 154 are determined according to the wavelengths of the first laser beam and the second laser beam.

  The liquid crystal optical element 120 is disposed so that the center of the first light spot formed in the surface of the transparent electrode 144 by the light beam of the first laser light coincides with the center point A. The liquid crystal optical element 120 is arranged so that the center of the second light spot formed in the surface of the transparent electrode 146 by the light beam of the second laser light coincides with the center point B.

  Thereby, the coma aberration of the first laser beam is corrected by the electrode pattern 152, and the coma aberration of the second laser beam is corrected by the electrode pattern 154.

  The second embodiment shown in FIG. 5 includes an electrode pattern 156 (first electrode pattern) for correcting coma aberration using the first laser beam and an electrode pattern for correcting astigmatism or spherical aberration using the second laser beam. This is an example of 158 (second electrode pattern). In the electrode pattern of Example 2, the electrode pattern 156 is contained in the electrode pattern 158. In the liquid crystal optical element 120, for example, an electrode pattern 156 is formed on the transparent electrode 144, and an electrode pattern 158 is formed on the transparent electrode 146. Alternatively, in the liquid crystal optical element 120, for example, both the electrode patterns 156 and 158 may be formed on the transparent electrode 144.

  The electrode pattern 156 is formed by arranging two substantially elliptical shapes symmetrically around the center point C, and the electrode pattern 158 is formed by arranging one substantially circular shape around the center point D. The center point C and the center point D have a predetermined interval. In Example 2, the size of the ellipse of the electrode pattern 156 and the size of the circle of the electrode pattern 158 are determined according to the wavelengths of the first laser beam and the second laser beam.

  The liquid crystal optical element 120 is arranged so that the center of the first light spot formed in the plane of the liquid crystal optical element 120 by the light beam of the first laser light coincides with the center point C. Further, the liquid crystal optical element 120 is arranged so that the center of the second light spot formed in the plane of the liquid crystal optical element 120 by the light beam of the second laser light coincides with the center point D.

  Accordingly, the coma aberration of the first laser light is corrected by the electrode pattern 156, and astigmatism or spherical aberration of the second laser light is corrected by the electrode pattern 158.

  The third embodiment shown in FIGS. 6 and 7 includes electrode patterns 162A and 162B (first electrode patterns) for correcting aberrations using the first laser beam, and electrode patterns for correcting aberration using the second laser beam. This is an example having 164A, 164B (second electrode pattern). The electrode pattern 162A is an electrode pattern for correcting astigmatism or spherical aberration using the first laser beam, and the electrode pattern 162B is an electrode pattern for correcting coma aberration using the first laser beam. The electrode pattern 164A is an electrode pattern for correcting astigmatism or spherical aberration using the second laser beam, and the electrode pattern 164B is an electrode pattern for correcting coma aberration using the second laser beam.

  In the liquid crystal optical element 120, for example, electrode patterns 162A and 162B are formed on the transparent electrode 144, and electrode patterns 164A and 164B are formed on the transparent electrode 146. When the wavelength of the first laser beam is longer than that of the second laser beam, the electrode patterns 162A and 162B are positioned inside the circular shape of the electrode patterns 164A and 164B.

  As shown in FIG. 6, the electrode pattern 162 </ b> A is formed by symmetrically arranging two substantially elliptical shapes around the center point E, and the electrode pattern 162 </ b> B is formed by one substantially circular deformation shape having the center point E. It is arranged as a center. Further, as shown in FIG. 7, the electrode pattern 164A is formed by symmetrically arranging two substantially elliptical shapes around the center point G, and the electrode pattern 164B also has one substantially circular deformation shape as the center point. It is formed with G being the center.

  In the third embodiment, the center point E and the center point G have a predetermined interval. In Example 3, the size of the ellipse shape of the electrode patterns 162A and 162B and the size of the circular deformed shape of the electrode patterns 164A and 164B are determined according to the wavelengths of the first laser beam and the second laser beam. Is done.

  The liquid crystal optical element 120 is arranged so that the center of the first light spot 12 formed in the surface of the liquid crystal optical element 120 by the light beam of the first laser light coincides with the center point E. Further, the liquid crystal optical element 120 is disposed so that the center of the second light spot 14 formed in the surface of the liquid crystal optical element 120 by the light beam of the second laser light coincides with the center point G.

  As a result, the astigmatism or spherical aberration of the first laser beam and the second laser beam is corrected by the electrode patterns 162A and 164A, and the first laser beam and the second laser beam by the electrode patterns 162B and 164B. Aberration is corrected.

  Example 4 shown in FIG. 8 includes an electrode pattern 166 (first electrode pattern) for correcting coma aberration using the first laser beam and an electrode pattern for correcting astigmatism or spherical aberration using the second laser beam. This is an example of 168 (second electrode pattern). In the electrode pattern of Example 4, the electrode pattern 166 is contained in the electrode pattern 168. In the liquid crystal optical element 120, for example, the electrode pattern 166 is formed on the transparent electrode 144, and the electrode pattern 168 is formed on the transparent electrode 146. Alternatively, in the liquid crystal optical element 120, for example, both electrode patterns 166 and 168 may be formed on the transparent electrode 144.

  The electrode pattern 166 is formed by arranging two substantially elliptical shapes symmetrically around the center point E, and the electrode pattern 168 is formed by arranging one substantially circular shape around the center point F. The center point E and the center point F have a predetermined interval. In Example 4, the size of the elliptical shape of the electrode pattern 166 and the size of the circular shape of the electrode pattern 168 are determined according to the wavelengths of the first laser light and the second laser light.

  The liquid crystal optical element 120 is arranged so that the center of the first light spot formed in the plane of the liquid crystal optical element 120 by the light beam of the first laser light coincides with the center point E. Further, the liquid crystal optical element 120 is arranged so that the center of the second light spot 14 formed in the plane of the liquid crystal optical element 120 by the light beam of the second laser light coincides with the center point F. The electrode pattern 168 is smaller than the diameter of the second light spot 14.

  Thereby, the coma aberration of the first laser beam is corrected by the electrode pattern 166, and the astigmatism or spherical aberration of the second laser beam is corrected by the electrode pattern 168.

As described above, according to the present embodiment, the shape of the electrode pattern for aberration correction corresponding to each of the first laser beam and the second laser beam can be determined.
In the liquid crystal optical element 120 of the present embodiment, the position of the center of the electrode pattern for correcting the aberration of the first laser beam is different from the position of the center of the electrode pattern for correcting the aberration of the second laser beam. Therefore, it is not necessary to accurately adjust the irradiation directions of the plurality of laser beams. For example, even in the case of the light emitting unit 122 in which a plurality of laser diodes of laser light are installed on the same substrate as in the present embodiment, and the adjustment of the irradiation direction of the laser light is difficult, the aberration is accurately obtained. It can be corrected.

  Usually, when laser diodes of a plurality of laser beams are installed on the same substrate, the centers of the light beams of the plurality of laser beams match only at the aperture position and do not match at other positions. The aperture is provided in the vicinity of the objective lens. Therefore, unlike the liquid crystal optical element 120 of the present embodiment, the conventional liquid crystal optical element has a problem that it cannot be installed other than the aperture because the centers of the plurality of electrode patterns coincide. Alternatively, there has been a problem that a liquid crystal optical element has to be installed at a position where the centers of the light beams of a plurality of laser beams substantially coincide.

  The centers of the light beams of a plurality of laser beams can be matched by correcting the direction of the light using a member such as a wavelength-selective axial hologram. However, since the number of members increases, the optical pickup and the optical disc apparatus It became a factor that hindered thinning.

  On the other hand, according to the present embodiment, the liquid crystal optical element 120 can be installed even at a position where the centers of the light beams of the plurality of laser beams do not coincide. Therefore, for example, the liquid crystal optical element 120 can be provided not near the objective lens 132 but near the light emitting unit 122. As a result, the liquid crystal optical element 120 receives the laser light in the vicinity of the light source of the laser light, so that the accuracy of aberration correction can be improved. Further, the liquid crystal optical element 120 can be reduced in size.

  Moreover, if the liquid crystal optical element 120 of this embodiment is used, it is not necessary to adjust the irradiation direction of the laser beam from a light emitting element. Therefore, the light-emitting portion 122 having a plurality of light-emitting elements over the same substrate can be used. As a result, it is possible to reduce the installation space of the light emitting unit 132 and to reduce the thickness of the optical pickup 120 as compared with an optical pickup in which light emitting elements are individually provided to adjust the irradiation direction of laser light.

  The preferred embodiments of the present invention have been described in detail above with reference to the accompanying drawings, but the present invention is not limited to such examples. It is obvious that a person having ordinary knowledge in the technical field to which the present invention pertains can come up with various changes or modifications within the scope of the technical idea described in the claims. Of course, it is understood that these also belong to the technical scope of the present invention.

  For example, in the above embodiment, the electrode pattern has been described based on four examples, but the present invention is not limited to such an example. The first electrode pattern for correcting the aberration of the first laser beam is different from the first electrode pattern in the center position, and the transparent electrode is arranged in the second electrode pattern for correcting the aberration of the second laser beam. Other examples may be used as long as they are.

  Moreover, although the said embodiment demonstrated the case where two light emitting elements were installed in the light emission part 120, this invention is not limited to this example. For example, the light emitting unit 120 may be provided with three or more light emitting elements.

  Moreover, although the said embodiment demonstrated the case where the collimator lens 126 was installed as shown in FIG. 2, this invention is not limited to this example. For example, the present invention can be applied to a case where the collimator lens 126 is not installed as shown in FIG. FIG. 9 is an explanatory diagram illustrating a configuration of the optical pickup 102 according to the modified example of the present embodiment.

  Conventionally, it is necessary to match the centers of the light beams of a plurality of laser beams as much as possible for the function of the liquid crystal optical element. Therefore, the use of a collimator lens was indispensable. On the other hand, according to the liquid crystal optical element 120 of the present embodiment, the aberration can be corrected properly even when the centers of the light beams of the plurality of laser beams are deviated, or in the vicinity of the light emitting unit 122. Since 120 can be installed, a collimator lens is unnecessary. Therefore, according to the modification of the present embodiment, the optical pickup and the optical disc apparatus can be further reduced in thickness.

1 is a block diagram showing a configuration of an optical disc device according to an embodiment of the present invention. It is explanatory drawing which shows the structure of the optical pick-up concerning the embodiment. It is sectional drawing which shows the liquid crystal optical element which concerns on the same embodiment. It is a top view which shows the liquid crystal optical element which concerns on the same embodiment. It is a top view which shows the liquid crystal optical element which concerns on the same embodiment. It is a top view which shows the liquid crystal optical element which concerns on the same embodiment. It is a top view which shows the liquid crystal optical element which concerns on the same embodiment. It is a top view which shows the liquid crystal optical element which concerns on the same embodiment. It is explanatory drawing which shows the structure of the optical pick-up which concerns on the example of a change of the embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Optical disk 12, 14 Light beam 100 Optical disk apparatus 102 Optical pick-up 104 Spindle motor 106 Feed motor 108 Drive control part 110 Signal processing part 112 Signal modulation / demodulation part 114 System controller 116 Operation part 120 Liquid crystal optical element 122 Light emission part 126 Collimator lens 128 Beam splitter 130 1/4 wavelength plate 132 Objective lens 136 Adjustment lens 138 Photo diode 142 Liquid crystal molecular layer 144, 146 Transparent electrode 148 Glass substrate 152, 154, 156, 158, 162A, 162B, 164A, 164B, 166, 168 Electrode pattern

Claims (7)

A transparent electrode irradiated with a first laser beam emitted from the same plane and a second laser beam different from the first laser beam;
A liquid crystal molecular layer to which a voltage is applied by the transparent electrode,
The transparent electrode is
A first electrode pattern for correcting the aberration of the first laser beam;
A liquid crystal optical element, wherein a center position is different from the first electrode pattern, and the second electrode pattern is arranged to correct an aberration of the second laser beam. The center of the first light spot formed in the transparent electrode surface by the first laser light coincides with the center of the first electrode pattern,
2. The liquid crystal optical element according to claim 1, wherein a center of a second light spot formed in the transparent electrode surface by the second laser light coincides with a center of the second electrode pattern. When the wavelength of the first laser beam is longer than the second laser beam,
The second electrode pattern is circular;
The liquid crystal optical element according to claim 1, wherein the first electrode pattern is located inside a circular shape of the second electrode pattern.   The liquid crystal optical element according to claim 3, wherein the second electrode pattern is located inside a second light spot formed in the transparent electrode surface by the second laser light. A light emitting unit for emitting a first laser beam and a second laser beam different from the first laser beam from the same plane;
An objective lens for condensing the first laser beam and the second laser beam on a recording medium surface;
A liquid crystal optical element having a transparent electrode irradiated with the first laser light and the second laser light, and a liquid crystal molecular layer to which a voltage is applied by the transparent electrode,
The transparent electrode is
A first electrode pattern for correcting the aberration of the first laser beam;
An optical pickup device arranged by a second electrode pattern having a center position different from that of the first electrode pattern and correcting the aberration of the second laser beam.   The optical pickup device according to claim 5, wherein the light emitting unit emits one or more other laser beams in addition to the first laser beam and the second laser beam from the same plane. A light emitting unit for emitting a first laser beam and a second laser beam different from the first laser beam from the same plane;
An objective lens for condensing the first laser beam and the second laser beam on a recording medium surface;
A liquid crystal optical element having a transparent electrode irradiated with the first laser light and the second laser light, and a liquid crystal molecular layer to which a voltage is applied by the transparent electrode,
The transparent electrode is
A first electrode pattern for correcting the aberration of the first laser beam;
An optical disc apparatus, wherein a center position is different from that of the first electrode pattern and the second electrode pattern is arranged to correct an aberration of the second laser beam.

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