KR100518872B1 - Optical pick-up system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pickup system, in particular, having an actuator for compensating spherical aberration on an optical path and operating in an optical axial direction by electromagnetic force.

An optical pickup system according to an embodiment of the present invention includes a laser diode for generating a laser beam; It consists of a lens holder for mounting a collimator lens to allow the beam incident on the center to run in parallel, a coil provided on the left and right sides of the lens holder, a two-pole magnet and a single-pole magnet facing the coil, and the lens holder is movable. And a spherical aberration compensation actuator for preventing torsion and compensating spherical aberration; A beam splitter for selectively transmitting or reflecting the beam according to the polarization direction of the incident beam; An objective lens for condensing the transmitted beam at a point on the optical disk and transferring the beam reflected on the optical disk to the beam splitter; And a photo detector for detecting the beam reflected from the disk as an electrical signal.

Description

Optical pickup system {OPTICAL PICK-UP SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pickup system, in particular, having an actuator for compensating spherical aberration on an optical path and operating in an optical axial direction by electromagnetic force.

As the demand for high-definition video processing increases due to the increase in the speed and storage density of optical storage devices and the advancement of consumer preferences, the data storage capacity of optical disks is also required as a large capacity.

As such a demand, a blue laser diode (BD) class optical system has been proposed. This brew laser class optical system uses laser light of high numerical aperture (eg NA = 0.85) and short wavelength (eg 405 nm).

1 is a schematic configuration diagram of a blue laser class optical pickup system.

Referring to FIG. 1, a blue laser diode 101 generating a blue laser beam, a beam splitter 102 reflecting or transmitting a beam, and a beam incident from the beam splitter 102 are parallel beams. To the collimator lens 103 for converting the light to the collimator lens 103, the collimator lens 103 for condensing the parallel beam to the optical disk 105, and transmitting the reflected beam to the collimator lens 103, and to the beam splitter 102. And a photo detector 106 for detecting the beam reflected by the electrical signal.

The blue laser optical pickup system configured as described above is as shown in FIG.

As shown in FIG. 1, a laser beam generated from a blue laser diode (BD) 101 passes through a beam splitter 102, and the transmitted beam is an objective lens 104 as a parallel beam in the collimator lens 103. Is incident on. The objective lens 104 condenses the incident beam to a point on the optical disk 105 to record and reproduce information. The beam formed from the optical disk 105 is reflected, and the reflected beam is reflected on the objective lens 104. ), It is transmitted through the collimator lens 103 and reflected by the beam splitter 102 to the photodetector 106. The photo detector 106 converts the reflected information into an electrical signal.

Here, in the blue laser class optical system, two layers are present on the disk for high data integration and large capacity, and the spherical aberration caused by the disc cover layer deviation is out of the optical aberration tolerance because the wavelength of the light source being used is short. In addition, spherical aberration occurs due to the deviation of each layer while using a dual-layer disk to increase storage density. In particular, in order to compensate for spherical aberration caused by the deviation of each disk layer by recording / reproducing the dual layer disk, it is necessary to offset the optical element on the optical path.

In order to compensate for this spherical aberration, there is a need for a single-axis drive servo system that must move an optical element on an optical axis.

In the conventional single axis actuator for spherical aberration compensation, as shown in FIG. 2, in the case of the actuator 110 for spherical aberration compensation, the collimator lens 112 is mounted at the center of the lens holder 111, and the lens holder is mounted. Motor 113 for the operation of the 111, the lead screw (114), the lens holder (rotating by the motor 113 in one side of the lens holder 111 to operate the lens holder 111) The shaft 115 is configured to guide the movement of the lens holder on the other side of the 111.

That is, in order to compensate for spherical aberration caused by the collimator lens 112, the lens holder 111 should be moved in the optical axis direction. When the motor 113 is driven, the lead screw 114 connected to the motor shaft rotates. The lens holder 111 is moved in the forward / rear direction. As the shaft 115 of the other side of the double lens holder guides the movement of the lens holder, spherical aberration is compensated for.

However, since the lead screw 114, which is the shaft of the motor 113, is provided on one side of the lens holder, a case in which a force for driving the lens holder is concentrated on one side may occur. In addition, the use of the lead screw method has a disadvantage in terms of cost and assembly, such as the need to configure a separate motor-screw system.

In addition, since a single-axis actuator capable of minimizing spherical aberration requires high precision driving, the angular shift during driving should be minimized to secure driving precision of several tens of um or less and tilt margin of the optical device. In addition, when configuring a separate servo system, since feedback on the position information is required in real time, an additional configuration of a circuit system is required.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and includes a single-axis drive actuator that operates with electromagnetism on the optical axis to compensate for spherical aberration that may occur due to disc cover layer deviation in a BD optical pickup system. In addition, an object of the present invention is to provide an optical pickup system capable of moving a collimator lens along an optical axis direction.

Another object of the present invention is to provide a collimator lens to the lens holder of the spherical aberration compensation actuator, and to guide the movement in the optical axis direction and the magnetic circuit for generating the movable force in the optical axis direction on the left and right sides thereof. It is an object of the present invention to provide an optical pickup system that can be easily configured without using an expensive motor.

It is still another object of the present invention to provide a magnetic circuit for driving a lens holder, including a coil and a magnet, and to include a magnetic iron piece for magnetic resilience at an opposite position located at a polar boundary of the magnet, thereby changing sensitivity and resolution. It is an object of the present invention to provide an optical pickup system.

Still another object of the present invention is to use a coil attached to the left and right sides of the lens holder, a two-pole magnet opposite to the lens holder, and an optical pick-up system for preventing twisting of the lens holder while driving the single-pole magnet. The purpose is to provide.

Optical pickup system according to the present invention for achieving the above object,

A laser diode for generating a laser beam;

It consists of a lens holder for mounting a collimator lens to allow the beam incident on the center to run in parallel, a coil provided on the left and right sides of the lens holder, a two-pole magnet and a single-pole magnet facing the coil, and the lens holder is movable. And a spherical aberration compensation actuator for preventing torsion and compensating spherical aberration;

A beam splitter for selectively transmitting or reflecting the beam according to the polarization direction of the incident beam;

An objective lens for condensing the transmitted beam at a point on the optical disk and transferring the beam reflected on the optical disk to the beam splitter;

And a photo detector for detecting the beam reflected from the disk as an electrical signal.

Preferably, the spherical aberration compensation actuator comprises: a lens holder for mounting and operating a collimator lens; A two-pole magnet fixed to the coil and opposite to the left and right sides of the lens holder; A yoke to which the two-pole magnet is attached to the inner surface, and a single pole magnet installed to face the lower end of the coil; Rotation guide means for guiding the operation of the lens holder; It characterized in that it comprises a base for supporting the yoke and the movable guide means to support the movement of the lens holder.

Preferably, the magnetic iron piece for the magnetic restoring force is located opposite to the polarity boundary of the magnet on the left / right side of the lens holder.

Preferably, the rotation guide means is a shaft guide groove and a shaft coupled to the guide groove formed on the left and right of the lens holder in the lens height direction center and the lens reference symmetry, and for supporting and fixing both ends of the shaft And a shaft fixing groove formed in the base.

Preferably, the shaft guide groove is formed in a rectangular shape on one side of the lens holder to guide the lens holder in the up and down / left and right direction, the lens holder is treated as a long hole to guide the lens holder in the left / right direction .

The spherical aberration compensation servo may be further configured to control the operation of the spherical aberration compensation servo of the spherical aberration compensation actuator according to the jitter signal detected by the photo detector.

Preferably, the spherical aberration compensating actuator is disposed at the front or rear end of the beam splitter.

Hereinafter, with reference to the accompanying drawings as follows.

3 is a perspective view of a spherical aberration compensation actuator according to the present invention, and FIG. 4 is an exploded perspective view of FIG. 3.

3 and 4, a lens holder 210 mounted with a collimator lens 211 for traveling the beam in parallel and moving in the optical axis direction; Coil 212 and magnets 222 and yoke 221 provided on the left and right sides of the lens holder 210 and a shaft guide groove 223 for guiding movement of the lens holder 210 in the optical axis direction. ) And the shaft 224, the base 220 supporting both ends of the shaft 224, and the single pole magnet 230 facing the bottom surface of the left and right coils of the lens holder are attached to the yoke 221. Configuration.

Referring to the accompanying drawings, the blue laser optical system according to an embodiment of the present invention configured as described above is as follows.

First, the blue laser optical system has a short wavelength of the light source so that the spherical aberration is out of tolerance due to the disc cover layer deviation, or the spherical aberration is caused by the deviation of each layer while using the dual layer disc to increase the storage density. do. In order to compensate for this spherical aberration, there is a need for a single-axis drive servo system that must move an optical element on an optical axis.

3 and 4, the spherical aberration compensating actuator 200 installed on the optical axis has a linear motion in the direction of the optical axis as a single axis actuator, for which the lens holder 210 and the magnetic Circuitry, shaft 224, base 220.

The lens holder 210 has a collimator lens 211 is seated in the beam through hole (210a) formed in the center, and has a magnetic circuit for moving the lens holder 210 to the left / right side, the shaft for guiding operation 224 is provided in the optical axis direction.

Here, the shaft 224 is arranged to the left and right so that the two shafts 224 to the center of the lens height direction and the lens reference symmetry to guide the movement of the lens holder 210 in the optical axis direction.

The magnetic circuit includes a coil 212, a magnet 222, and a yoke 221, and generates a driving force for operating the lens holder 210. To this end, the coil 212 is attached to the left / right side of the lens holder 210, the magnet 222 is attached and fixed to the inner surface of the yoke 221 in a position opposite thereto.

Here, as shown in FIG. 5, the magnet 222 is provided with two poles (S: N) in the axial direction. The two magnets 222 may be provided as two monopolar magnets or a single bipolar magnet. In addition, the center of the coil 221 is disposed to face the polarity boundary of the magnet 222. These coils 212 and the magnet 222 is a force generated between each other to drive the collimator lens 211 with the direction of the Lorentz force in the optical axis direction.

In addition, the yoke 221 is installed in a U-shape for maximizing the magnetic flux and the magnet 222 is attached to the yoke inner side upright on both sides.

As shown in FIG. 7, a single pole magnet 230 is attached to the fixing groove 231 of the yoke 221 under the coil 212 of the lens holder 210. This unipolar magnet 230 can reduce the torsional driving that may result from misalignment between the coil 212 and the magnet 222 which governs the directional movement.

In addition, the base 220 supports the shaft 224 and the yoke 221 to support and fix the entire actuator. To this end, the yoke fixing protrusion 226 protrudes inward to the rear of the base so that the fixing groove 221a formed on the rear surface of the yoke is fitted therein, and the yoke flow preventing part 227 is formed therein to fit inside. The up / down flow of the 221 is prevented.

The shaft 224 for guiding the operation of the lens holder 210 is inserted into the shaft guide groove 223 formed in the axial direction at the center of the lens holder 210 and the shaft 224 of the shaft 224. Since both ends are seated by shaft fixing grooves 225 formed on the front and rear sides of the base 220, when the lens holder 210 is operated by a magnetic circuit, the front and rear directions along the shaft 224 (optical Axial direction).

Referring to this operation, the spherical aberration compensation actuator 200 mounts the collimator lens 211 on the optical axis and moves in the optical axis direction, thereby functioning as a spherical aberration compensation or optical path changing actuator.

When a current is applied to the coil 212 of the actuator 200, an electromagnetic force is generated between the coil 212 and the magnet 222 opposite to the coil 212, and the generated electromagnetic force is coupled to the coil 212 and the lens holder 210. Move it in the direction. In this case, the lens holder 210 moves along the shaft 224 and the shaft guide groove 223. At this time, according to the direction of the current applied to the coil 212 is moved in the forward or backward direction.

In addition, as shown in FIGS. 5 and 6, the magnetic iron pieces 213 are seated at the centers of both sides of the lens holder 210, respectively. The magnetic iron pieces 213 are elastic springs formed on both sides of the lens holder 210 and are respectively seated in the "c" -shaped iron piece fixing grooves 214 and face the polar boundary of the magnet 222.

Accordingly, the magnetic iron piece 213 can be fixed only by bonding after being inserted into the iron piece fixing groove 214 without a separate assembly jig. In addition, the steel piece fixing groove 214 is a predetermined depth, it can be changed only by the thickness of the magnetic iron piece 213 without modifying the lens holder 210 when adjusting the stiffness value of the magnetic spring.

Also, as shown in FIG. 6, the magnetic iron piece 213 is positioned at a polarity boundary S: N of the magnet 222 fixed to the left and right sides of the lens holder 210. This is due to the stable point of potential energy (magnetic spring) in which the highest magnetic density is formed between the poles of the magnet so that the magnetic iron piece 213 is located between the polarities. Deviation between these polarities results in a restoring force that tries to return to its original state.

Accordingly, the lens holder 210 may be fixed at a specific point due to the difference between the electromagnetic force generated by the coil 212 and the magnet 222 and the magnetic restoring force. That is, by adjusting only the thickness and size of the magnetic iron piece 213 and the distance to the magnet 222, the sensitivity and the resolution can be changed.

Meanwhile, shaft guide grooves 223 (223a and 223b) for guiding the shaft 224 at the left and right sides of the lens holder 210 are formed in different shapes, as shown in FIGS. 3 and 4. That is, one side guide groove 223a of the lens holder 210 may be a quadrangular and vertical / left and right guide, and the other guide groove 223b may be processed in a circular or long hole to guide in the vertical direction. Thus, the degree of freedom is released so that the driving is free even when the friction force between the shaft 224 and the lens holder 210 increases due to the tilt of the lens holder 210 that may occur during driving.

As shown in FIG. 7 and FIG. 8, the monopolar magnet 230 is fixed to the yoke fixing groove 231 in the optical axis direction at the lower side of the coil disposed on the left and right sides of the lens holder.

When the lens holder 210 moves in the main direction by the coil 212 and the magnet 222, the unipolar magnet 230 works with the coil 212 to reduce the torsion during driving. give. That is, the difference between the force Fy in the optical axis direction and the force Fx orthogonal to the optical axis is Fy >> Fx, so the lens holder is always pushed in one direction (X axis), so the lens holder is moved in the Y axis direction. By allowing the lens holder to always be in contact with the same surface, the tilt angle of the lens holder can be held to minimize the tilt angle.

In addition, since the shaft 224 fixed to the shaft fixing groove 225 of the base 220 has a smaller size than the diameter thereof, the shaft 224 has a small size. Therefore, when the shaft 224 is pushed in, the force is applied in the axial direction and the direction perpendicular to the shaft 224. By acting, the shaft 224 may contact the same surface of the shaft fixing groove 225 without shaking, thereby improving shaft alignment. In an embodiment, a jaw fitted into the shaft fixing groove may be formed at both ends to prevent rotation of the shaft.

In addition, the shaft 224 is coated with a teflon material on the outside in order to improve the sliding characteristics, and the material of the lens holder 210 in contact with the shaft 224 also has a poly phenylene sulfide (PPS) system having excellent sliding characteristics. Used.

The optical pickup system to which the spherical aberration compensation actuator is applied is as shown in FIGS. 8 and 9.

As shown in FIG. 8, the laser beam generated from the blue laser diode 301 is incident on the beam splitter 303 as a parallel beam through a collimator lens 302a mounted at the center of the spherical aberration compensation actuator 302. The beam incident on the beam splitter 303 is transmitted and condensed at one point on the optical disk 305 through the objective lens 304b of the pickup actuator 304.

Here, a HOE 304a is provided on the front optical axis of the objective lens 304b, which is installed as a holographic optical element to reproduce or modify a waveform recorded in the hologram to obtain a desired waveform. .

Then, the laser beam formed on the optical disk 305 is reflected, the reflected beam is reflected by the beam splitter 303 through the objective lens 304b, and the reflected beam is reflected by the light collecting lens 306 by the light detector. Condensed at 307.

At this time, the photodetector 307 detects the reflected beam as an electrical signal and transmits it to the pickup servo 308, and the pickup servo 308 controls the operation of the pickup actuator 304, and also the photodetector 307. The electrical signal detected at is input to the spherical aberration compensation servo 309.

In addition, the spherical aberration compensation servo 309 outputs a servo signal to the spherical aberration compensation actuator 302 to compensate for the spherical aberration based on the electrical signal detected by the photodetector 307, thereby being positioned on the optical path. The actuator 302 and the collimator lens 302a attached thereto are controlled to move forward or backward, so that spherical aberration of the beam formed on the optical disk can be compensated for.

In addition, the spherical aberration compensation servo 309 analyzes the jitter value by using the signal detected by the photodetector 307, and sweeps the total operating range of the spherical aberration compensation actuator 302 while signal characteristics are obtained. Find and remember the best point to teach.

That is, the jitter value can be analyzed by using the operation characteristics of the spherical aberration compensation servo 309 and the change of the characteristics of the beams formed on the optical disk, and thus the signal characteristics based on the operation range of the spherical aberration compensation actuator 302. By finding and storing the optimal point of, it is possible to repeat learning based on this.

Here, in order to be able to learn the characteristic optimum point of the signal, after designating the reference value and applying a voltage to the spherical aberration compensation actuator to find the optimum point, and after passing through the reference point, if the optical characteristic worsens again, the direction of movement is changed. Repeatedly, the optimum point is stored.

Meanwhile, as shown in FIG. 9, the spherical aberration compensating actuator 313 is provided between the beam splitter 312 and the objective lens 314b. Accordingly, the laser beam transmitted through the beam splitter 312 is incident on the objective lens 314b by the collimator lens 313a mounted on the spherical aberration compensating actuator 313 as a parallel beam, and on the optical disk 315. Is condensed into one point.

When the beam formed on the optical disk 315 is reflected, it passes through the objective lens 314b and the collimator lens 314a, is reflected by the beam splitter 312, and is focused on the photo detector 317 by the condenser lens 316. And detected as an electrical signal.

The signal detected by the photo detector 317 is transmitted to the jitter signal detector 318 and input to the spherical aberration compensation servo 319. Then, the spherical aberration compensation servo 319 can servo the spherical aberration compensation actuator 313 using the jitter signal and the spherical aberration signal. In other words, it collects the reflected light and servos the spherical aberration compensation actuator from the spherical aberration signal.

Here, the spherical aberration compensation servo of FIG. 8 controls the servo based on the signal obtained from the objective lens. In the case of the spherical aberration compensation servo of FIG. 9, the optical signal is obtained when the spherical aberration compensation lens passes through the objective lens again. The signal is analyzed to control the servo.

The spherical aberration compensating actuator is operated by coarse driving at the initial stage, and then fine servo controlling precisely at the position where the maximum characteristic occurs. To this end, DC alignment is applied to enable position alignment and servo using the AC signal after the first servo.

As described above, the BD class optical pickup system of the present invention includes a single-axis actuator on the optical path, and utilizes the principles of electromagnetic and magnetic properties to compensate for nonlinearities that may occur in the actuator and tilt angles during driving. Thus, the actuator can be configured with a simple configuration.

So far, the present invention has been described with reference to the preferred embodiments, and those skilled in the art to which the present invention pertains to the detailed description of the present invention and other forms of embodiments within the essential technical scope of the present invention. Could be implemented. Here, the essential technical scope of the present invention is shown in the claims, and all differences within the equivalent range will be construed as being included in the present invention.

As described above, according to the optical pickup system according to the present invention, the spherical aberration compensation actuator is installed on the optical axis using electromagnetic and magnetic principles to compensate for spherical aberration that may occur in a blue laser class optical system. By not using additional motors, the cost savings are excellent.

In addition, it is necessary to adjust sensitivity and driving resolution during driving according to the requirements of the system, and it is possible to change the sensitivity and resolution by adjusting the thickness and size of the magnetic iron strip and the distance to the magnet.

In addition, since the movement of the lens holder is moved in the optical axis direction in which one direction is in close contact, the torsion caused by the driving of the lens holder can be eliminated, thereby improving optical characteristics.

1 is a block diagram showing a conventional BD-class optical pickup device.

Figure 2 is a structure of the spherical aberration compensation actuator conventionally applied to Figure 1;

Figure 3 is a perspective view showing the structure of the spherical aberration compensation actuator in the BD optical pickup apparatus according to an embodiment of the present invention.

4 is an exploded perspective view of FIG. 3.

5 is a magnetic circuit diagram of the spherical aberration compensation actuator according to the present invention.

Figure 6 is a view for showing the self restoring force by the magnetic spring according to the present invention.

7 is a partial side cross-sectional view showing the direction of generating electromagnetic force between the magnet and the coil according to an embodiment of the present invention.

8 is an optical pickup system including the spherical aberration compensating actuator of FIG. 3, wherein the optical pickup system is configured to servo using a light collecting unit jitter signal.

9 is an optical pickup system including the spherical aberration compensating actuator of FIG. 3, wherein the optical pickup system is configured to servo using a condenser jitter signal.

<Description of the symbols for the main parts of the drawings>

Spherical Aberration Compensation Actuator

210.Lens holder 211,302a, 313a ... Collector lens

212 Coil 213 Magnetic iron strip

220 ... Base 221 ... York

222 ... Magnet 223 ... Shaft guide groove

224 ... shaft 225 ... shaft fixing groove

Claims (7)

A laser diode for generating a laser beam; It consists of a lens holder for mounting a collimator lens to allow the beam incident on the center to run in parallel, a coil provided on the left and right sides of the lens holder, a two-pole magnet and a single-pole magnet facing the coil, and the lens holder is movable. And a spherical aberration compensation actuator for preventing torsion and compensating spherical aberration; A beam splitter for selectively transmitting or reflecting the beam according to the polarization direction of the incident beam; An objective lens for condensing the transmitted beam at a point on the optical disk and transferring the beam reflected on the optical disk to the beam splitter; And an optical detector for detecting the beam reflected from the disk as an electrical signal. The method of claim 1, The spherical aberration compensation actuator includes: a lens holder for mounting and operating a collimator lens; A two-pole magnet fixed to the coil and opposite to the left and right sides of the lens holder; A yoke to which the two-pole magnet is attached to the inner surface, and a single pole magnet installed to face the lower end of the coil; Rotation guide means for guiding the operation of the lens holder; And a base for supporting the yoke and the movable guide means to support the movement of the lens holder. The method of claim 2, And a magnetic iron piece for magnetic restoring force on the left and right sides of the lens holder opposite the polarity boundary of the magnet. The method of claim 2, The rotation guide means includes a shaft guide groove formed on the left and right sides of the lens holder so as to be symmetrical to the lens height direction and the lens reference symmetry, and a shaft coupled to the guide groove, and formed at a base to support and fix both ends of the shaft. And an optical shaft pickup groove. The method of claim 4, wherein The shaft guide groove is formed in a quadrangular shape on one side of the lens holder to guide the lens holder in the up / down / left and right directions, and is processed as a long hole on the other side of the lens holder to guide the lens holder in the left / right direction. . The method of claim 1, And a spherical aberration compensation servo for controlling the operation of the spherical aberration compensation servo of the spherical aberration compensation actuator according to the jitter signal detected by the optical detector. The method of claim 1, And the spherical aberration compensation actuator is disposed at the front or rear of the beam splitter.