KR100248023B1 - Super resolution optical pickup for various type disc - Google Patents

Abstract

An optical pickup has been disclosed for an ultra-high resolution recording and reproducing super resolution recording and reproducing apparatus having disc compatibility capable of reproducing a general compact disc. The disclosed optical pickup has a transparent plate having a thickness equal to the thickness difference and compatible with at least one hole therein for compatibility of discs having different thicknesses. The light beams passing through the transparent plate other than the holes are used for thin disks and the light beams passing through the holes are used for thick disks. In addition, the disclosed optical pickup includes a polarization beam deflector composed of a quarter wave plate and a birefringent prism for changing the polarization direction of the light beam generated from the light source, so that the reflected light can be focused next to the light source without splitting the light. This offers the advantage of miniaturization, increased light efficiency and ease of assembly adjustment.

Description

Optical pickup for super resolution recording and playback with disc compatibility.

1 is a diagram showing an optical arrangement of a conventional optical pickup for super resolution recording and reproduction.

2 is a diagram showing an optical arrangement of an optical pickup for super resolution recording / reproducing with disc compatibility according to an embodiment of the present invention.

3 is a plan view of a transparent plate used for an optical pickup for super resolution recording and reproduction having disc compatibility shown in FIG.

4 is a partial optical cross-sectional view showing an optical path to a thin disk in the optical pickup for super resolution recording and reproduction having the disk compatibility shown in FIG.

FIG. 5 is a partial optical sectional view showing an optical path to a thick disk in the optical pickup for super resolution recording and reproduction having the disk compatibility shown in FIG.

6 is a diagram showing an optical arrangement of an optical pickup for super resolution recording / reproducing with disc compatibility according to another embodiment of the present invention.

FIG. 7 is a perspective view showing a transmitter and receiver in an optical pickup for super resolution recording and reproduction having disc compatibility shown in FIG.

FIG. 8 is an optical sectional view showing the detailed structure of the polarizing beam deflector in the optical pickup for super-resolution recording and reproducing shown in FIG.

FIG. 9 is a partial optical cross-sectional view for explaining the positional relationship between a light source and a slit in the optical pickup for super resolution recording and reproduction having disc compatibility shown in FIG.

* Explanation of symbols for main parts of the drawings

1,11,22: light source 2,12: collimating lens

3: shield 4,14: beam splitter

5,14: objective lens 6,16,16 ': disc

7,17: Focusing lens 8,18,23: Slit

9,19,24: photodetector 15: transparent plate

20: transmitter and receiver 30: polarization beam deflector

31: 1/4 wave plate 32: birefringent prism

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pickup for super resolution recording and reproducing, which reads and writes super high-density information in a so-called super-resolution method in order to increase the resolution of an objective lens, and in particular, a disc capable of reading information on recording media having different media thicknesses. The present invention relates to an optical pickup for super resolution recording and reproduction having compatibility.

Techniques for increasing the resolution of objective lenses for writing and reading ultra high density information are well known. In order to explain the background on which the present invention was made, first, the optical pickup for conventional super resolution recording and reproduction is shown in FIG. In the drawings, reference numeral 1 denotes a laser diode, 2 denotes a collimating lens for advancing light emitted from the laser diode 1 in parallel in the form of a beam, and 3 denotes a light beam traveling in parallel by the collimating lens 2. A shield for shielding the central part of the beam splitter, 4 is a beam splitter for straightening the light beam split by the shield 3 and subsequently reflecting the returned light beam to separate their optical path, 5 is a beam splitter 4 is incident straight An objective lens for focusing the light beam on the disk 6, 7 is a focusing lens for converging the light beam reflected from the disk 6 and then passing through the objective lens 5 and reflected by the beam splitter 4, 8 is a focusing lens 7 A slit having a gap 8a formed so as to pass through the center of the light beam converged by the slit, and shielding the periphery thereof, and 9 a photodetector for receiving the light beam passing through the slit 8 to detect an electrical signal. The.

Here, the shield 3 crosses the center of the light beam and shields the center to divide the light beam in two. The light beam split in two is focused by the objective lens 5 above the diffraction limit and formed into minute spots on the disk 6. On the other hand, the slit 8 is provided such that the gap 8a is positioned at the focal point of the focusing lens 7 to block the peripheral portion of the light beam spot formed thereon. That is, when looking at the light intensity distribution of the micro-spots formed in the disk 6 described above, it can be seen that the so-called side-lobe is formed in the peripheral portion in which the light quantity having a constant intensity is distributed. The side lobe is prevented from being received by the photodetector 9 so that noise is not mixed in the detection signal.

In the above conventional super resolution recording and reproduction optical pickup, the slit 8 should be provided so that the gap 8a is positioned at the correct focus of the focusing lens 7. By the way, since the installed position of the slit 8 is not known correctly and the space | interval 8a is smaller than the spot formed there, the position adjustment becomes very difficult. In addition, in the conventional super resolution recording and reproduction optical pickup, the light beam reflected from the disk is separated from the light beam directed to the disk through the beam splitter 4 in a 90 ° direction, so that the overall utilization efficiency of the light is low and the space is miniaturized. There is a limit to this.

On the other hand, a short wavelength light source and an objective lens having a large numerical aperture are essential for high density recording and reproduction. However, since an objective lens having a large numerical aperture is more unstable with respect to the inclination of the recording medium as the medium thickness of the recording medium is thicker, a thinner disc medium has emerged for high density storage. With the advent of disk media having such different thicknesses, compatibility with the user, which makes it possible to use disks having different thicknesses in the same optical pickup, has become an important problem. However, the conventional optical pickup for super resolution recording and reproduction as described above is difficult to reproduce due to an increase in aberration due to the thickness difference of the medium when the disc having a different thickness, that is, the conventional compact disc, is substantially compatible. This is impossible.

Accordingly, an object of the present invention is to increase the resolution of an objective lens for a thin disk medium, and to write and read ultra high density information as well as to reproduce a thick disk medium, which is capable of reproducing super-resolution recording. To provide optical pickup.

The present invention to achieve the above object, and a light source for generating a light beam; An objective lens for focusing the light beam on a disk medium; A photodetector for detecting an information signal and a servo signal from the light beam reflected from the disk medium; In a super resolution recording and reproduction optical pickup having means for increasing optical resolution, the means for increasing optical resolution includes:

The transparent medium including a transparent plate disposed between the objective lens of the disc medium, the transparent plate having at least one hole penetrating straight through a portion of the incident light beam, the transparent plate having a predetermined thickness to refractively transmit the remaining light beam. The light beams refracted and transmitted at portions other than the holes of the plate are used for ultra-high density writing and reading of information about a relatively thin disk medium, and the light beams passing through the holes are used for information about a relatively thick disk medium. Characterized in that it is configured to be used for reading.

Preferably, the photodetector is disposed to be located next to the light source, and further includes an optical path changing means for converting the optical path so that the optical path of the light beam reflected from the disk medium can be concentrated next to the light source. Characterized in that it can be miniaturized.

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

The optical pickup for super-resolution recording and reproducing according to the present invention has a light source 11, a collimating lens 12, and a light source 11 for advancing the light beam emitted from the light source 11 in parallel, as shown in FIG. Beam splitter 13 separating the light beams directed toward the discs 16 and 16 'from the light reflected from the disc 16, and the light beams incident straight through the beam splitter 13 to receive the discs 16 and 16'. The objective lens 14 to focus on the transparent lens 15 positioned between the objective legs 14 and the disks 16 and 16 'as a means of increasing the optical resolution, and reflected from the disks 16 and 16'. After the objective lens 14 and the focusing lens 17 for converging the light beam reflected by the beam splitter 13, the slit 18 for shielding the periphery of the light beam converged by the focusing lens 17, and the slit 18 It consists of a photodetector 19 for receiving an optical beam passing through the) to detect an electrical signal.

Here, the thin disk 16 of the disks 16 and 16 'has a thickness of 0.6 mm, for example for high density, and the thick disk 16' has a substrate thickness of 1.2 mm, for example, as a conventional compact disk. Of course, one of these disks 16 and 16 'is loaded in a disk drive (not shown) to which the optical pickup of the present invention is mounted. The transparent plate 15 has two holes 15a and 15b which are long and open side by side and longitudinally at predetermined intervals in the spot 20 formed therein as shown in FIG.

According to the present invention, the objective lens 14 is optically optimized for the thick disk 16 ', and the transparent plate 15 is made of the same optical properties as the substrate of the disks 16 and 16'. The disks 16 and 16 'have a thickness equal to the thickness difference (0.6 mm).

In the above-described configuration, the transparent plate 15 may be provided on the incident side of the objective lens 14, and one or three or more holes may be drilled therein.

Referring to FIG. 4, the light beams (hatched portions) transmitted from portions other than the holes 15a and 15b of the transparent foil 15 are used to write and read information on the thin disk 16. Referring to FIG. The light beam (hatched portion) passing through the holes 15a and 15b of the transparent plate 15 is used to read the thick disk 16 '. That is, even when the thin disk 16 'is used for the objective lens 15 optimized for the thick disk 16', a light beam that transmits portions other than the holes 15a and 15b of the transparent plate 15 is used. This can overcome the aberration problem caused by the thickness difference. Therefore, it is possible to write and read each piece of information in an optimized environment regardless of the disk thickness.

Next, FIG. 6 shows an example in which the disc is compatible and its assembly adjustment is easy and miniaturized as another embodiment of the present invention. In this embodiment, the transmitter / receiver 20 is placed together at the above-described light source position, and is reflected from the disk 16.16 'instead of deleting the beam splitter (13 in FIG. 2) and the focusing lens (17 in FIG. 2). An optical path changing means for changing the optical path of the light beam is arranged. The optical path converting means includes the collimating lens 12 and the polarizing beam deflector 30 disposed between the collimating lens 12 and the objective lens 14.

In the light-receiving unit 20, as shown in FIG. 7, a light source 22 is installed at one side on the stem 21, and slits 23 are arranged side by side next to the light source 22, and a photodetector 24 is behind the slit 23. ) Is located. The light source 22 is a point light source as a laser diode chip of a small size, and the slit 23 lies on the same plane as the light emitting point of the light source 22. The exact positional relationship of this slit 23 will be described later in detail.

6 and 8, the aforementioned polarizing beam deflector 30 includes a birefringent prism 31 and a quarter wave plate 32. If P polarization is used among the light transmitted from the light source 22, the P polarization 33 is advanced to the right polarization 34 by the quarter wave plate 22, which is the disk 16, 16 '. B) is reflected back to the left circularly polarized light 35 The left circularly polarized light 35 is changed to the S polarized light 36 by the quarter wave plate 22. Here, the P-polarized light 33 has an optical axis whose refractive index n _o corresponds to the ordinary ray of the birefringent prism 31.

(n _o -1) × θ

While being tilted at an angle of, the returned S-polarized light 36 becomes an extraordinary ray of the birefringent prism 31, and its optical axis is changed by the refractive index no.

-(n _o -1) × θ

Is tilted at an angle of Therefore, the reflected S-polarized light 36 is reflected to the incident P-polarized light 33 at the birefringent prism 31.

n × θ, where n = n _o -n _e )

Will be tilted at an angle of.

Next, referring to FIG. 9, the reflected light passing through the polarizing beam deflector 30 is collected by the collimating lens 12 next to the light source 22, the collecting position of which is located from the collimating lens 12. The focal length f, which is the same distance as (22), from the light source in accordance with the above-mentioned tilt angle

n × θ × f

As far away as Therefore, the position of the slit 23 can be correctly specified. Also here the polarization beam deflector 30 When rotated by as much as the focusing position in the direction orthogonal to the slit direction of the slit 23

n × θ × f ×

By moving horizontally as much as possible to precisely adjust the condensing position on the slit (23). That is, according to the present embodiment, the optical pickup for super resolution recording and reproduction is not only provided with disc compatibility allowing playback of ordinary discs having different thicknesses, but also the light is not divided, so that the optical efficiency is increased and downsized, and the slit position is adjusted. It is possible to make it easier.

As described above, the present invention is effective in various aspects, such as providing optical compatibility for super-resolution recording and reproducing, giving users compatibility with different thicknesses, increasing the practicality of the user, and improving optical efficiency as a small size and easy assembly and adjustment. Invention.

It is to be understood that the invention is not limited to what has been described above and illustrated in the drawings and that many more modifications and variations are possible within the scope of the following claims.

Claims (5)

A light source for generating a light beam; An objective lens for focusing the light beam on a disk medium; A photodetector arranged to be located next to the light source and detecting an information signal and a servo signal from a light beam reflected from the disk medium; At least one of the light beams irradiated from the light source is disposed between the disk medium and the objective lens so as to be used for writing and reading information about the disk medium having different thicknesses, and at least one of the light beams penetrated to pass a portion of the incident light beams. A transparent plate having a hole and having a predetermined thickness so as to refractively transmit the remaining light beams; And optical path changing means including a polarizing beam deflector for changing the polarization direction of the light generated from the light source so that the path of the light beam reflected from the disk medium can be collected next to the light source. Optical pickup for super resolution recording reproduction. The method of claim 1, wherein the transparent plate, An optical pickup for super-resolution recording and reproducing, having a thickness corresponding to a difference in thickness between the thin disk medium and the thick disk medium, and having the same medium as the disk media. The method of claim 1, wherein the hole, And two holes formed so as to be disposed at right and left sides with respect to the center of the spot so as to be inscribed to the spot of the light beam formed on the transparent plate. The method of claim 1, wherein the optical path conversion means, And a collimating lens for advancing the light generated by the light source in parallel and converging the light reflected from the disk medium. The polarizing beam deflector of claim 1 or 4, Of the light generated from the light source, a predetermined linearly polarized light is used, and the polarization direction is rotated so that the linearly polarized light is rotated into circularly polarized light and the circularly polarized light reflected from the disk medium is converted into linearly polarized light rotated at an angle different from the linearly polarized light. And a birefringent prism that refracts a 1/4 wavelength plate and its linearly polarized light at different refractive indices according to respective polarization angles.