KR20080023478A - Apparatus for reproducing recording medium and optical pick-up apparatus - Google Patents

Abstract

An optical recording/reproducing device and an optical pick-up apparatus are provided to control servo driving by detecting a tilting error signal of a recording medium in a far field area. An optical recording/reproducing device comprises an optical block, and an optical pickup device. The optical block has a first photoelectric unit, and a second photoelectric unit. The first photoelectric unit generates a first beam and detects a servo signal in a near field area from a signal reflected from SIL(Solid Immersion Lens). The second photoelectric unit detects an electrical signal from an RF signal reflected from a recording medium. The optical pickup device includes a second laser diode generating a second beam, a third photo detector detecting the servo signal in a far field area from the signal of the second beam reflected from the recording medium, an object lens(121) and an SIL to project the first beam onto the recording medium, and an actuator(210) driven by a control signal according to the servo signal of the first beam and the second beam.

Description

Apparatus for reproducing recording medium and optical pick-up apparatus

1 is a side view of a SIL and a recording medium provided in the near field data recording apparatus.

2 is a diagram showing a relationship between the amount of feedback light and a gap;

3 is a view for explaining an optical system of the data recording and reproducing apparatus according to the embodiment of the present invention;

4 shows an optical pickup device according to the invention.

5 is a view for explaining a case where no skew occurs in the recording medium.

Fig. 6 is a diagram for explaining beam spots in the third photo detector when no skew is generated in the recording medium.

FIG. 7 is a diagram explaining a case where skew is generated on a recording medium. FIG.

8 and 9 illustrate beam spots in the third photodetector when no skew occurs in the recording medium.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical recording and reproducing apparatus and an optical pickup apparatus, and more particularly, to an optical recording and reproducing apparatus and an optical pickup apparatus capable of servo drive control by detecting gap error signals not only in the near field region but also in the far field region. will be.

In order to meet the miniaturization demand for the size of the optical recording medium, the track width must be narrow to have a high density recording capacity. However, the limitation due to the difference in the layer structure of the recording medium including the protective layer, the recording layer, and the reflective layer and consequently the condensing method, the diffraction of the spot size of the light condensed on the recording medium to form bits in the recording layer of the recording medium. Due to limitations such as limitations, studies on optical recording and reproducing methods for overcoming such limitations are being actively conducted.

In order to solve the problem of the conventional far-field optical recording and reproducing method, as a method for increasing the recording density in a region where no light diffraction occurs recently, an optical recording and reproducing method using a near-field Is being proposed.

FIG. 1 is a side view of a SIL and a recording medium included in a near field data recording apparatus, and FIG. 2 is a diagram showing a relationship between the amount of feedback light and a gap.

Between the recording medium 1 and the objective lens OL (not shown), a SIL (Solid Immersion Lens) 2 having a total reflection surface is provided so as to totally reflect light for a predetermined critical angle or more, and between the SIL 2 and the recording medium. It has a predetermined gap d.

The light passing through the objective lens is incident on the SIL 2 before being incident on the recording medium 1, and the light incident on the SIL 2 at a predetermined threshold angle or more is incident on the SIL 2. It is totally reflected at the reflecting surface and moved to the photo detector to observe it.

Then, in relation to the size of the light formed on the reflecting surface of the SIL 2 and the distance d between the SIL 2 and the recording medium 1, the wavelength? Of the light incident on the SIL 2 is d. The area defined by ≤ λ / 4 is a near-field.

The state in which the interval d satisfies d? Lambda / 4 and light does not leak into the data recording / reproducing layer is called a far-field state.

In the near field state, part of the light incident on the reflective surface of the SIL 2 at an angle greater than or equal to the critical angle is, as described above, the data of the recording medium 1 on the reflective surface (ie, the reflective boundary surface) of the SIL 2. It permeates the recording and reproducing layer. Therefore, as shown in FIG. 2, it can be seen that the return light amount of the totally reflected light decreases exponentially as it approaches the data recording / reproducing layer (exactly, the surface of the recording medium) of the recording medium 1.

Therefore, when the cross-sectional position of the SIL 2 is in the near field state, the feedback servo is performed as a gap error signal on a linear portion whose total reflection feedback amount changes according to the size of the interval d. It is possible to control the gap between the end face of the and the data recording / reproducing layer surface of the recording medium 1 constantly.

For example, as shown in Fig. 2, when the control is performed such that the total reflection feedback light amount becomes the control target value P, the interval d is kept constant.

As described above, the servo operation is controlled through the detection of the gap error signal in the near field state, and it is assumed that all of the proposals as a tilting configuration for this are in the near field state.

On the other hand, in the far field state, all the light incident on the SIL 2 cross section at an angle equal to or greater than the critical angle is totally reflected to become the return light. Therefore, as shown in FIG. 2, the total reflection feedback light amount in the far field state is a constant value.

However, when a tilting error occurs due to skew of the recording medium, the distance between the SIL and the recording medium may be in a far field state, and at this time, the light totally reflected by the SIL becomes constant. There is a problem in that it is difficult to detect a gap error signal using the same.

That is, in the prior art, a configuration for detecting a gap error signal by using the amount of light totally reflected by the SIL has been proposed, but these configurations are totally reflected by the SIL when placed in a far field state by tilting of the recording medium. Since the amount of light to be made becomes constant, the detection of the gap error signal using these light amount differences becomes impossible.

In addition, in order to record data on the recording medium or reproduce the data recorded on the recording medium, the actuator equipped with the seal (SIL) and the objective lens approaches the near field area from the far field area with the recording medium. If the recording medium is tilted, the seal SIL may collide with the surface of the recording medium before reaching the near field area.

Therefore, it is necessary to control the servo operation by detecting the gap error signal in the far field region.

SUMMARY OF THE INVENTION The present invention has been proposed to solve the above problems, and an optical recording and reproducing apparatus capable of controlling servo drive by detecting a tilting error signal of a recording medium even in a far field region in recording or reproducing data. It is an object to provide a pickup device.

An optical recording and reproducing apparatus according to an embodiment of the present invention comprises a first photoelectric means for generating a first beam and detecting a servo signal in a near field region from a signal reflected in a SIL, and from an RF signal reflected from a recording medium. An optical block having a second photoelectric means for detecting an electrical signal and a servo signal in a far field region from a signal generated by the second beam and reflected from the recording medium, the first beam being incident on the recording medium The optical pickup device includes an objective lens and the SIL, and an actuator driven by a control signal according to a servo signal of the first beam or the second beam.

An optical pickup apparatus according to an embodiment of the present invention includes a second laser diode for generating a second beam, a third photo detector for detecting a servo signal from a signal of the second beam reflected from a recording medium, an objective lens on the upper side, A lens holder having a SIL and a magnetic circuit formed in the lens holder for operating the lens holder are provided, and the actuator is driven by a control signal according to the servo signal of the second beam.

Hereinafter, an optical recording and reproducing apparatus according to the present invention will be described in detail with reference to the accompanying drawings. However, one of ordinary skill in the art who understands the spirit of the present invention may easily propose another embodiment by adding, adding, deleting, or modifying elements within the scope of the same spirit, but this also belongs to the scope of the present invention. I will say.

First, in the embodiment of the present invention, the optical recording / reproducing apparatus includes a device capable of recording data on or reproducing data recorded on the recording medium, and also includes a device capable of recording and reproducing data.

3 is a view for explaining an optical system of the data recording and reproducing apparatus according to the embodiment of the present invention.

Referring to FIG. 3, the recording and reproducing apparatus according to the present invention includes an RF signal for recording or reproducing data on a recording medium 123, and a gap servo signal for controlling an interval between the recording medium 123 and the SIL 122. The optical block for detecting the light, and the actuator 210 having the SIL 122 and the objective lens 121 is formed so that the light is incident on the recording medium 123 and the light reflected from the recording medium 123 is incident A mounted optical pickup device (not shown) is included.

In addition, the optical block includes a laser diode 110 for emitting a first beam, a collimator lens 111 for converting the first beam emitted from the laser diode 110 into parallel light, and a polarization component of an incident beam. The first polarized beam splitter (PBS) 112 and the second polarized beam splitter 114 for transmitting or reflecting the incident beam and the divergence angle or convergence angle of the beam are adjusted to adjust the size of the first beam. And an expander 116, and a QWP (Quarter Wave Plate) 117 for converting the wavelength of the incident beam.

The optical block includes a second photo detector (second photoelectric means 115) for detecting an RF signal reflected from the recording medium 123 and incident through the second polarization beam splitter 114, and the recording. A first photodetector (first photoelectric means, 113) is included for detecting a gap error signal reflected from the medium 123 and incident through the first polarization beam splitter 112.

For reference, it should be noted that the present invention is explained by exemplifying a photo detector as a photoelectric means.

In addition, the actuator 210 includes a SIL 122 for focusing the incident first beam onto the recording medium 123 and an objective lens 121 having a predetermined refractive index.

In addition, a second laser diode (not shown) and a third photo detector (not shown) are installed adjacent to the actuator 210 in the optical pickup device (not shown) to detect a gap error signal in the far field region. do. A detailed description of the third laser diode (not shown) and the third photo detector (not shown) will be described later.

The operation of the optical recording and reproducing apparatus configured as described above is as follows.

The first beam emitted from the laser diode 110 is converted into parallel light by the collimator lens 111, and passes through the first polarizing beam splitter 112 and the second polarizing beam splitter 114 to expand the expander 116. Divergence angle or convergence angle is controlled.

In addition, the light is linearly polarized by the QWP 117 into circularly polarized light and is incident to the reflection mirror 119.

The first beam reflected by the reflective mirror 119 is incident on the recording medium 123 after passing through the objective lens 121 and the SIL 122. However, at this time, the first beam incident on the reflective surface of the SIL 122 at a predetermined critical angle or more is totally reflected at the reflective surface of the SIL 122 and re-entered into the reflective mirror 119.

In addition, a coil and a magnetic circuit are formed in the actuator 210 to perform servo operation for gap error and tracking error.

Meanwhile, the first beam reflected from the recording medium 123 is converted into linearly polarized light by the QWP 117. However, it is changed to the polarization direction perpendicular to the original polarization direction.

In the near field optical recording and reproducing apparatus, the SIL is caused by a coupling between the SIL 122 and the recording medium 123 and the refractive index between the SIL 122 and the recording medium 123 and the air. Of the light incident on 122, light incident at a critical angle or more is totally reflected, and the rest is incident on the recording medium 123.

That is, part of the first beam is totally reflected at the SIL 122. If the distance between the SIL 122 and the recording medium 123 is small, the total amount of beams is small. If the distance between the SIL 122 and the recording medium 123 is large, the amount of the total beams is increased. do.

This is due to the correlation between the refractive index of the air between the SIL 122, the recording medium 123, the SIL 122 and the recording medium 123, and the wavelength of the beam, and the SIL 122 and the recording medium 123. In the case where the gap between the SIL 122 is less than or equal to 100 nm (ie, in the near field area), the gap between the SIL 122 and the recording medium 123 and the amount of beam totally reflected by the SIL 122 have a correlation.

Accordingly, a first beam having a polarization component that can be reflected through the second polarization beam splitter 114 among the first beams reflected from the recording medium 123 is incident to the second photo detector 115. The signal incident on the second photo detector 115 becomes an RF signal.

The second photo detector 115 converts the RF signal into an electrical signal to reproduce data stored in the recording medium 123.

In addition, the first beam totally reflected by the SIL 122 is reflected through the first polarization beam splitter 112 and is incident to the first photo detector 113, and the first photo detector 113 has a SIL ( A gap servo signal is extracted from the first beam reflected at 122.

On the other hand, in the optical recording and reproducing apparatus according to the embodiment of the present invention, a second laser diode (not shown) is used to detect a gap error signal for controlling the distance between the SIL 122 and the recording medium 123 in the far field region. C) and a third photo detector (not shown) are installed adjacent to the actuator 210.

The second beam generated by the third laser diode (not shown) is reflected by the recording medium 123 and is incident to the third photo detector (not shown).

In this case, the third photo detector (not shown) extracts a gap servo signal for controlling the distance between the SIL 122 and the recording medium 123 by sensing the light amount of the incident second beam.

Then, even when the distance between the SIL 122 and the recording medium 123 is 100 nm or more (that is, in the far field region), the servo drive by the actuator 210 can be performed, and thus the recording with the SIL 122 is possible. Collision of the medium 123 can be prevented.

That is, the actuator 210 closes the gap between the SIL 122 and the recording medium 123 from the gap servo signal when approaching the recording medium 123 from the farfield area to the nearfield area. Servo driven to control.

As described above, the first beam emitted from the first laser diode 110 is a signal for detecting the RF signal and the gap servo signal in the near field region, and the second laser diode (not shown) The emitted second beam is used as a signal for detecting a gap servo signal in the farfield region.

In FIG. 3, a photo detector for detecting a gap servo signal from light totally reflected by the reflection surface of the SIL using a single beam (first beam) as a configuration for detecting a gap servo signal is provided to the first optical system. In the optical recording and reproducing apparatus described later, in addition to using the two beams (the first beam and the second beam) as described above, a separate second is used for detecting the gap servo signal. It can also be implemented by forming an optical system.

4 is a view showing an optical pickup device according to the present invention.

Referring to FIG. 4, the optical pickup apparatus 200 according to the present invention includes the actuator 210, a pickup base 201 on which the actuator 210 is mounted, and an agent mounted on one side of the pickup base 201. The second laser diode 202 and the third photo detector 203 are included.

In detail, the second laser diode 202 generates a second beam for detecting a gap error signal in the farfield region. Here, the second laser diode 202 may be a laser diode emitting red light of 650nm band.

In addition, the third photo detector 203 detects a gap servo signal from the second beam that is generated from the second laser diode 202 and is reflected by the recording medium 123.

Here, the third photo detector 203 is a photo detector divided into four cells. However, in order to more sensitively detect the skew of the recording medium 123, a photo detector divided into 9 or 16 cells may be used.

In addition, the actuator 210 has a lens holder 211 in which the objective lens 121 and the SIL 122 are formed on the upper side, and a magnetic circuit formed in the lens holder 211 for the operation of the lens holder 211. It is configured to include.

The magnetic circuit includes a first coil 213, a second coil 212, a yoke 216, and a multipole magnet 215. In addition, a third coil 214 may be further formed in the magnetic circuit.

A first coil 213 is formed on both sides of the lens holder 211 to move the lens holder 211 in the Y-direction (focusing direction), and the first coil 213 is formed of a magnet having a different polarity. It is located opposite the vertical boundary.

In addition, a second coil 212 for moving the lens holder 211 in the X-direction (tracking direction) is formed at the central portions of both sides of the lens holder 211, and the second coil 212 has a polarity. It is located opposite the horizontal boundary of the other magnet.

In addition, a third coil 214 is formed on the upper side of the lens holder 211 to move the lens holder 211 in the Z-direction (tilting direction), and the third coil 214 is the lens holder. A portion of the third coil 214 is formed on the circumferential surface of the 211 and is located opposite to a horizontal boundary of the magnets having different polarities.

The magnet 215 may be formed of a multi-pole magnet, and generates a magnetic field facing the first, second, and third coils 213, 212, and 214, and when the current is applied to the first, second, and third coils 213, 212, 214, The lens holder 211 can be driven in the X-direction, the Y-direction, and the Z-direction under control.

In addition, the magnet 215 is fixed to the inner surface of the yoke 216, a ferromagnetic material structure formed adjacent to the lens holder 211, respectively. Here, the yoke 216 serves to provide a path of the magnetic field generated by the magnet 215.

One end of the wire suspension 217 is fixed to both side surfaces of the lens holder 211, and the other end of the wire suspension 217 is fixed to the frame 218 provided on one side of the lens holder 211. The wire suspension 217 supports the lens holder 211 and serves to supply a current.

Referring to the operation of the optical pickup device 200 configured as described above is as follows.

When the optical pickup device 200 approaches the farfield area from the farfield area to the recording medium 123, a second beam generated by the second laser diode 202 is reflected from the recording medium 123. The third photo detector 203 is incident on the third photo detector 203.

In this case, the third photo detector 203 determines the degree of skew of the recording medium 123 and detects a gap servo signal for controlling the servo drive of the actuator 210 accordingly.

In addition, the actuator 210 enables the lens holder 211 to be driven in the X-, Y-, and Z-directions according to the detection of the gap servo signal by the third photo detector 203.

That is, when a current flows through the first coil 213, a force acts on the first coil 213 in a vertical direction by interacting with a magnetic field generated at a vertical boundary of the opposing magnet, thereby the lens holder 211. Moves in the Y-direction.

When a current flows in the second coil 213, a force acts on the second coil 213 in a horizontal direction by interacting with a magnetic field generated at a horizontal boundary of the opposing magnet so that the lens holder 211 is moved. Move in the X-direction.

When a current flows through the third coil 214, a force is applied to the third coil 214 in the upward and downward directions by interaction with a magnetic field generated at a horizontal boundary of the opposing magnet, thereby causing the lens holder 211. ) Rotates in the Z-direction.

Therefore, as the actuator 210 is operated as described above, when the optical pickup device 200 approaches the nearfield area from the farfield area with the recording medium 123, the recording medium 123 and the SIL 122 are moved. Collision can be prevented.

FIG. 5 is a diagram illustrating a case where no skew is generated in the recording medium, and FIG. 6 is a diagram illustrating a beam spot in the third photo detector according to the skew of the recording medium.

5 and 6, when the recording medium 123 and the optical pickup device 200 are parallel because no skew occurs in the recording medium 123, the second laser diode 202 may be used. Is generated by the second beam and is reflected by the recording medium 123 to be incident on the center of the third photo detector 203.

In this case, since the third photo detector 203 senses that skew does not occur in the recording medium 123 using the value of the signal (A + B)-(C + D), the optical pickup device 200 may approach the near field area from the far field area with the recording medium 123 without servo driving.

FIG. 7 is a diagram illustrating a case where skew occurs in the recording medium, and FIGS. 8 and 9 are diagrams illustrating beam spots in the third photo detector according to skew of the recording medium.

7 to 9, when a skew occurs in the recording medium 123 and the recording medium 123 and the optical pickup device 200 are not parallel to each other, the second laser diode ( The second beam generated at 202 is reflected by the recording medium 123 and is not incident to the center of the third photo detector 203, but is incident to one side.

That is, as shown in FIG. 8, when skew occurs in the recording medium 123 in the X-direction (ie, the tracking direction), the second beam reflected from the recording medium 123 is shifted to the right to the third. The light is incident on the photo detector 203. Of course, in some cases, the second beam may be incident to the third photo detector 203 by being biased to the left.

In this case, the third photo detector 203 may know the skew of the recording medium 123 using the values of the (A + D)-(B + C) signals, and accordingly, the SIL 122 and the recording medium ( A gap servo operation may be performed to prevent the collision of 123.

In addition, as shown in FIG. 9, when skew occurs in the Z-direction (tilting direction) of the recording medium 123, the second beam reflected from the recording medium 123 is shifted upward to the third photo detector. It enters (203). Of course, in some cases, the second beam may be incident downward to the third photo detector 203.

In this case, the third photo detector 203 may know the skew of the recording medium 123 using the values of the (A + B)-(C + D) signals, and accordingly, the SIL 122 and the recording medium ( A gap servo operation may be performed to prevent the collision of 123.

Accordingly, in the optical recording and reproducing apparatus according to the embodiment of the present invention, a gap servo operation for preventing collision between the recording medium 123 and the SIL 122 in the near field region may be performed by the second beam. A gap servo operation may be performed in the far field to prevent collision between the recording medium 123 and the SIL 122 by the second beam.

According to the optical recording and reproducing apparatus and the optical pickup apparatus according to the present invention having the above structure, the servo drive can be controlled by detecting the skew error signal of the recording medium not only in the near field area but also in the far field area.

Claims (9)

A first photoelectric means for generating a first beam and detecting a servo signal in the near field region from the signal reflected at the SIL, and a second photoelectric means for detecting an electrical signal from the RF signal reflected from the recording medium. With optical blocks, A second beam is generated and the servo signal in the far field region is detected from the signal reflected from the recording medium, and the objective lens and the SIL are formed so that the first beam is incident on the recording medium, and the first beam or the second beam is formed. And an optical pickup device having an actuator driven by a control signal according to a servo signal of a beam. The method of claim 1, The optical pickup apparatus includes a second laser diode for generating the second beam, and a third photo detector for detecting a servo signal from a signal of the second beam reflected from the recording medium. The method of claim 1, And the first beam is shorter in wavelength than the second beam. The method of claim 1, And the first beam is a beam in a blue light wavelength band, and the second beam is a beam in a red light wavelength band. The method of claim 1, And the servo signal is a gap servo signal corresponding to skew of a recording medium. A second laser diode for generating a second beam; A third photo detector for detecting a servo signal from the signal of the second beam reflected from the recording medium; And A lens holder having an objective lens and a SIL formed on the image side, and a magnetic circuit formed in the lens holder for operation of the lens holder, the actuator being driven by a control signal according to the servo signal of the second beam; Optical pickup device. The method of claim 6, The optical pickup apparatus further comprises an optical pickup base on which the second laser diode, the third photo detector, and the actuator are mounted. The method of claim 6, And the second laser diode generates the second beam in the farfield region and enters the recording medium. The method of claim 6, And the second beam is light of a red light wavelength band.

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