KR20050092553A - Optical pick-up and method for detecting spherical aberration signal - Google Patents

Abstract

The present invention relates to an optical pickup and a method for detecting spherical aberration of the optical pickup, and more particularly, to a method for detecting spherical aberration caused by an optical disc thickness difference.

The spherical aberration detection method of an optical pickup according to the present invention comprises the steps of generating a sub-beam having a different sign from the main beam from the beam emitted from the laser diode to be incident on the optical disk, and the beam reflected from the optical disk is Incident to the light-receiving element, detecting a push-pull signal at each sub-beam incident to the light-receiving element, and spherical through a differential signal in the push-pull signal of the two sub-beams Detecting an aberration.

Description

Optical pickup and spherical aberration detection method of optical pickup {OPTICAL PICK-UP AND METHOD FOR DETECTING SPHERICAL ABERRATION SIGNAL}

The present invention relates to an optical pickup and a method for detecting spherical aberration of the optical pickup, and more particularly, to a method for detecting spherical aberration caused by an optical disc thickness difference.

An optical disc is a product that records and reproduces information by using optical characteristics, and generally has a small disc shape.

In order to use an optical disc, an optical disc driver is required, and information of the optical disc is reproduced or recorded by an optical pickup device mounted inside the optical disc driver.

Conventional CDs (Compact Discs) and DVDs (Digital Versatile Disks) are used as optical disks, and BD (Blue-ray Disks) has recently been studied.

The optical disk detects a tracking error and a focus error in a three-beam and astigmatism manner composed of a main beam and a sub-beam, and detects an error signal. A method of recording / detecting an RF signal by performing a servo based on this is generally used.

In the case of BD (Blue-ray Disk), which has been recently studied, the lens whose NA (Numerical Aperture) of the objective lens is 0.85 or more is used to increase the influence of spherical aberration due to the thickness difference of the optical disk, thereby detecting and compensating it This is an important task.

1 is an example for explaining a conventional spherical aberration detection method.

In the spherical aberration detection method shown in FIG. 1, the effect of spherical aberration is that the central portion is small and the peripheral portion is large in the incident pupil of the light incident on the objective lens 10. The spherical aberration is detected by dividing the light into the central light and the peripheral light and making it incident on the four-segmented light receiving element 12 (13).

In more detail, the peripheral light is incident on one quadrature light-receiving element 13, and the central light is incident on the other four-split light-receiving element 12.

A spherical aberration signal (SAS) is detected by detecting a focus error signal (FES) obtained from the quadrature light receiving elements 12 and 13.

However, the above-described method is based on the spherical aberration of the quadrature light receiving element 13 which detects the peripheral light while the focus error signal of the quadrature light receiving element 12 which detects the center light is set to zero. As a result of detecting the defocus accordingly, the magnitude of spherical aberration is detected. Therefore, astigmatism such as astigmatism or spot size detection, which does not detect a focus error signal at a focus position, has a large astigmatism or defocus on the light receiving side. If (defocus) is large, there is a problem that the detection sensitivity of the spherical aberration falls.

2 is a view for explaining a spherical aberration detection method using a change in intensity distribution of a conventional light spot.

In the figure, an eight-segment light receiving element 20 is shown, which is divided into eight cells.

The spherical aberration is measured using the difference between the intensity distribution in the inner region and the intensity distribution in the outer region.

That is, the spherical aberration SAS is calculated by the difference between the light intensity distribution of the inner regions A, B, C, and D and the light intensity distribution of the outer regions E, F, G, and H as follows.

SAS = SUM (A, B, C, D) -SUM (E, F, G, H)

If the spherical aberration increases, the light intensity distribution further spreads as shown in FIG. 3.

However, the spherical aberration detection method as described above cannot distinguish between a change in light intensity distribution due to spherical aberration and a change in intensity due to defocus, and thus an actuator for compensating spherical aberration and an actuator for defocus compensation. ), There is a problem of going through a complicated process of determining which device must be driven to obtain an optimal condition.

4 is a diagram for explaining a method of detecting spherical aberration according to a conventional RF signal.

The method shown in FIG. 4 uses the property that the RF Maximum position for a short Pit (eg 2T) and RF Maximum position for a long Pit (eg 8T) are defocused by spherical aberration. It is a method for detecting spherical aberration.

However, since the method shown in Fig. 4 uses RF signals, it cannot be used for unrecorded discs.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a method for detecting spherical aberration, which facilitates discrimination between a focus error signal and a spherical aberration detection signal, and which has improved detection sensitivity.

The spherical aberration detection method of an optical pickup according to the present invention comprises the steps of generating a sub-beam having a different sign from the main beam from the beam emitted from the laser diode to be incident on the optical disk, and the beam reflected from the optical disk is Incident to the light-receiving element, detecting a push-pull signal at each sub-beam incident to the light-receiving element, and spherical through a differential signal in the push-pull signal of the two sub-beams Detecting an aberration.

In addition, the light receiving element is composed of a cell for detecting the signal of the main beam and two cells for detecting the signal of the two sub-beams, and the two cells for the sub-beams are each divided into two regions.

In addition, the optical disk is characterized in that the Blu-ray disk.

In the optical pickup according to the present invention, in the optical pickup for recording or reproducing information by causing the beam emitted from the laser diode to be incident on the optical disk and detecting the beam reflected from the optical disk to perform servo, the optical pickup is incident on the optical disk. A hologram element is formed on the path of the beam to generate two sub-beams having the spherical aberration different from the main beam, and the beam reflected from the optical disk is incident and the push- A light receiving element for detecting a pull signal is provided, and the control unit detects spherical aberration through the differential signal of the push-pull signal.

Hereinafter, a spherical aberration detection method according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 5 is a view for explaining a spherical aberration detection method according to the present invention, and the schematic structure of the optical pickup is shown.

Referring to FIG. 5, the light emitted from the laser diode 30 passes through the beam splitter 31 and is converted into parallel light by the collimator lens 32 to be incident on the hologram element 33.

The hologram element 33 is designed to have a predetermined inherent spherical aberration with different signs for ± diffracted light, resulting in a form of grating having a predetermined curvature. The light incident on the hologram element 33 is diffracted with a constant diffraction angle and diffraction ratio by the pitch and depth of the grating.

The zeroth order diffracted light passes through the objective lens 34 to form a main beam A on the optical disk, and the + 1st order diffracted light passes through the objective lens 34 to form a sub beam B, − The primary diffracted light passes through the objective lens 34 to form a subbeam C on the optical disk. Herein, the Blu-ray disc may be used as the optical disc.

As shown in FIG. 6, the three beams are arranged at the center of the track, and the sub beams B and C are arranged by pitch / 2 with respect to the main beam A. FIG. At this time, each of the arrayed beams has a unique spherical aberration as shown in FIG.

Since the spherical aberration is different in the case where there is a change in the thickness of the optical disk, that is, in the case where the thickness of the optical disk becomes thicker and thinner, as shown in FIG. 8, the sub-beam B is changed according to the thickness change of the optical disk. The spherical aberration of (C) is reduced or increased.

When the sub-beams (B) (C) cross the track, diffraction occurs due to the Pit or Land / Groove structure of the optical disk, and modulates the light including the track cross signal. As the spot becomes smaller, the signal appears with a larger modulation degree, and when the spherical aberration is large, the light spot becomes larger, so that the signal appears as a low modulation degree optical signal.

As described above, each light including the modulated signal is reflected by the optical disk, and is then focused on the objective lens 34 to be incident on the hologram element 33.

The incident light is diffracted by the hologram element 33 into 0th order and ± 1st order light, and then enters the light receiving element 37 through the collimator lens 32 and the beam splitter 31 as shown in FIG. 9. do.

The light incident on the light-receiving element 37 includes a track cross signal in an operation in which the light spot crosses the track by the Land / Groove structure of the Pit column or the optical disk as described above.

In general, in the optical pickup for recording, two sub-beams are formed separately from the main beam for recording / reproducing by the tracking servo, and the difference between the sum of the push-pull signal and the push-pull signal of the main beam The DPP (Differential Push-Pull) method is used to obtain a canceled track error signal.

Therefore, conventionally, the DPP signal was detected using the following equation.

MPP (Main Push-Pull) = (VA + VD)-(VB + VC)

SPP1 (Sub Push-Pull 1) = VE-VF

SPP2 (Sub Push-Pull 2) = VG-VH

DPP (Differential Push-Pull) = MPP-α (SPP1 + SPP2)

However, in the present invention, the disk thickness error signal DTE is detected in addition to the signal conventionally detected.

DTE = SPP2-SPP1

Referring to the detection principle of the disk thickness error signal DTE, as illustrated in FIG. 7, the two sub-beams B and C each have unique spherical aberrations having different signs, and are generated by the difference in disk thickness. FIG. 8 illustrates that the spherical aberration is represented by different symbols according to the change direction of the thickness.

That is, as shown in FIG. 10, the sub-beam B has an inherent spherical aberration, and spherical aberration is canceled or increased due to spherical aberration caused by a change in the disk thickness.

Therefore, the spherical aberration of the sub-beam B becomes larger or smaller according to the change in the thickness of the disk, and the amplitude of the track cross signal is changed.

11 shows the change of SPP2 and SPP1 according to the change in the thickness of the disk.

That is, as shown in FIG. 12, a graph of SPP2-SPP1 is shown, and the controller (not shown) may detect the disk thickness error signal DTE according to the change of the disk thickness through the differential signal.

Therefore, spherical aberration generated in accordance with the change in the disk thickness can be detected.

As described above, the present invention simultaneously forms a main beam well corrected for spherical aberration and two sub-beams corrected for spherical aberration by ± respectively on the optical disk using a hologram element, and spherical aberration caused by a change in thickness of the optical disk The detection sensitivity of spherical aberration can be improved by detecting a differential signal using a property of canceling or degrading the spherical aberration of the two sub-beams.

The spherical aberration detection method according to the present invention can provide a spherical aberration detection method which facilitates the discrimination between the focus error signal and the spherical aberration detection signal and improves the detection sensitivity.

1 is an example for explaining a conventional spherical aberration detection method.

2 is a view for explaining a spherical aberration detection method using a change in intensity distribution of a conventional light spot.

3 is a diagram illustrating a distribution of beam intensities according to a change in spherical aberration.

4 is a diagram for explaining a method of detecting spherical aberration in accordance with a conventional RF signal.

5 is a view for explaining a spherical aberration detection method according to the present invention, the structure of the optical pickup is shown.

FIG. 6 is a diagram illustrating three beams formed in a track of an optical disc. FIG.

7 is a diagram for explaining spherical aberration inherent in a subbeam;

8 is a diagram illustrating a change in spherical aberration according to the thickness of an optical disk.

9 illustrates a light receiving element.

Fig. 10 is a diagram for explaining spherical aberration inherent in the sub-beams and changes in the thickness of an optical disk.

11 is a diagram showing changes in SPP2 and SPP1 according to the change in the thickness of the disk.

12 is a diagram for explaining a disk thickness error signal detected through a differential signal between SPP2 and SPP1.

<Explanation of symbols for main parts of drawing>

10; Objective lens 11; Hologram element

12; 4-split light receiving element 13; 4-split light receiving element

20; 8-split light receiving element 30; Laser diode

31; Beam splitter 32; Collimator lens

33; Hologram element 34; Objective

35; Optical disc 37; Light receiving element

Claims (4)

Generating two sub-beams having a different sign from the main beam from the beam emitted from the laser diode to be incident on the optical disk; Allowing the beam reflected from the optical disk to be incident on the light receiving element; Detecting a push-pull signal at each sub-beam incident on the light receiving element; And detecting spherical aberration through the differential signal in the push-pull signals of the two sub-beams. The method of claim 1, The light receiving element includes a cell detecting a signal of a main beam and two cells detecting a signal of two sub beams, and two cells for the sub beam are each divided into two regions. Spherical aberration detection method. The method of claim 1, And the optical disk is a Blu-ray disk. An optical pickup for recording or reproducing information by causing a beam emitted from a laser diode to be incident on an optical disk, and detecting and performing a servo beam reflected from the optical disk. On the path of the beam incident to the optical disk is formed a hologram element for generating the incident beam and two sub-beams having spherical aberrations different from the main beam, the beam reflected from the optical disk is incident and the two And a light receiving element for detecting a push-pull signal of a sub-beam of the light beam, and a control unit for detecting spherical aberration through the differential signal of the push-pull signal.