KR100464080B1 - Actuator for optical pick-up - Google Patents

Abstract

The present invention relates to an actuator for optical pickup for compensating spherical aberration.

In order to realize this, the present invention changes the shape of the leaf spring to compensate for displacement of the movable part so that the movable part is horizontally moved in the optical axis direction, thereby compensating spherical aberration while preventing the movable part from tilting.

Description

Actuator for Optical Pickup {ACTUATOR FOR OPTICAL PICK-UP}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an actuator for optical pickup, and more particularly, to an optical pickup actuator capable of driving an optical element in one axis direction to compensate spherical aberration.

Recently, due to the rapid development of optical discs, various optical pickups for recording / reproducing information of optical discs have been developed.

Compact disks (CDs), now widely known as recording media such as optical disks, have a substrate thickness of 1.2 mm and have a reflective surface that reflects light as a recording layer, and is a combination of pits formed concave on the reflective surface. It stores information such as sound, text, and graphics. In addition, digital video disks (DVDs) having a high-density storage of a large amount of video information and having a substrate thickness of 0.6 mm have also emerged. Unlike CD, optical pickup for DVD uses a short wavelength light source and focuses light with an objective lens having a large numerical aperture (NA) to form a micro spot for high density reproduction.

Recently, a phase change disk (CD-R) has been put into practical use as a recording medium that can be reproduced only once, and the substrate thickness is the same as that of the above-described CD, and only the pit of the CD is used as the recording layer. Otherwise, it is made of a phase change material in which the reflectances of the recording wavelength and the reproduction wavelength in the specific wavelength band are changed. Such a CD-R can be recorded and reproduced in the same optical pickup environment as a CD.

As a result of the appearance of discs of different thicknesses or recording materials, a compatible optical pickup of such discs is required from the user's point of view. In accordance with such a requirement, a conventional optical pickup compatible with DVD and CD has been provided. Conventionally known DVD and CD compatible optical pickups generally use one short wavelength (650 nm) light source and have a means for adjusting the numerical aperture of the objective lens according to the thickness of the disc to be reproduced.

That is, a small spot is formed by using all the apertures (NA: 0.6) of the objective lens during DVD playback, and in the case of CD playback, the beam diameter of the light incident from the light source to the objective lens is limited or a small numerical aperture in the objective lens, for example, The spherical aberration is compensated for by adjusting the aperture to 0.45, such as using the paraxial region.

1 is a view showing an optical pickup structure according to the prior art.

As shown in FIG. 1, a laser diode 1 for generating a laser beam, a grating 3 for decomposing the laser beam generated from the laser diode 1 into three laser beams, and the grating 3 A beam splitter 5 for changing the reflection direction according to the incident direction of the three laser beams decomposed into a collimator lens 7 for converting the laser beam passing through the beam splitter 5 into a parallel beam; And converging the objective lens 9 which refracts the parallel laser beam propagated from the collimator lens 7 to form an optical spot to be irradiated on the optical disc 10 and the laser beam reflected from the optical disc 10. And a photodiode 13 for detecting a data signal from a laser beam converged from the boiling point lens 11.

The optical system structure used for the optical pickup as described above detects data in the following manner.

First, a laser beam irradiated from the laser diode 1 is decomposed into three laser lights while passing through the grating 3 in order to record / reproduce data on the optical disc 10. The laser beam decomposed from the grating lens 3 passes through the beam incident in one direction and proceeds to the beam splitter 5 having the property of refracting the beam incident in the other direction in the vertical direction.

Then, the laser beam passing through the beam splitter 5 is incident on the objective lens 9 forming a light spot, wherein the beam incident on the objective lens 9 is a laser beam having a radiation shape, The collimator lens 7 is placed at the front end in order to make it into a parallel laser beam.

The laser beam passing through the collimator lens 7 forms an optical spot having a constant diameter focal point in the objective lens 9 and irradiates onto the optical disc 10. The laser beam reflected from the optical disk 10 is irradiated to the photodiode 13 through the beam split 5 and the boiling point lens 11. The photodiode 15 analyzes the amount of light of the reflected laser beam, converts it into a constant signal, and transmits the same to the data detector.

However, according to the trend of the optical disk, which has recently been densified, the optical pickup optical system according to the prior art increases the aperture ratio of the objective lens. In this case, when the aperture ratio is increased, the laser beam reacts sensitively to a small thickness error of the optical disc. There is a problem of generating aberrations.

In order to solve this problem, a method of compensating spherical aberration by mounting a collimator lens on a movable part, fixing the movable part to a fixed part by using a support member, and moving the collimator lens according to the driving of the movable part is proposed. It is becoming.

2 is a view schematically showing an actuator for compensating conventional spherical aberration. 2 is a view showing a state seen from the optical axis direction. 2A shows before the movable part moves, and FIG. 2B shows after the movable part moves.

As shown in FIG. 2, the actuator is provided with a collimator lens 15 in the movable portion 16. The leaf spring 17 is connected to the movable portion 16, and the leaf spring 17 is fixed to the fixed portion 18. In FIG. 2, one leaf spring is provided for convenience of description, but two leaf springs are provided to face each other.

Accordingly, the movable portion 16 supported by the leaf spring 17 may move the collimator lens 15 in the optical axis direction (one axis direction) to compensate for spherical aberration.

However, in the conventional optical pickup actuator, when the movable part moves in the optical axis direction as the plate spring is provided in a direction perpendicular to the optical axis direction, the collimator lens is not in the optical axis direction when the collimator lens is moved over a certain distance. Will tilt. Therefore, relative displacement occurs when comparing the movable part before and after the moving part.

When the collimator lens is inclined as described above, the collimator lens cannot be level with the objective lens with respect to the optical axis direction, so that the laser beam incident through the collimator lens is emitted in a direction other than the optical axis direction. Accordingly, a problem arises that it is impossible to focus the light spot at the correct point of the optical disk.

The present invention has been made in view of the above problems, and an object thereof is to provide an actuator for an optical pickup that can compensate for spherical aberration.

Another object of the present invention is to provide a spring structure for continuously moving the collimator lens in the optical axis direction.

1 is a view showing an optical pickup structure according to the prior art.

2 is a schematic representation of an actuator for compensating conventional spherical aberrations.

3 is a schematic representation of an actuator for compensating spherical aberration in accordance with a preferred embodiment of the present invention.

According to a preferred embodiment of the present invention for achieving the above object, the actuator for optical pickup, the movable portion is inserted into the optical element; Is formed in a 'c' shape, a protrusion having a predetermined length from the central one side of the 'c' shape is formed, the length of the first and second leaf springs provided on both sides of the 'c' shape is the length of the protrusion A leaf spring formed at least longer; And a fixing part connected to the protrusion to support the leaf spring, wherein an end of the protrusion is connected to the fixing part, and the first and second leaf springs are connected to the fixing part.

Hereinafter, with reference to the accompanying drawings will be described the present invention.

3 is a view schematically showing an actuator for compensating spherical aberration according to a preferred embodiment of the present invention. 3 is a view showing a state seen from the optical axis direction. 3A shows before the movable part moves, and FIG. 3B shows after the movable part moves.

As shown in FIG. 3, the actuator includes a movable part 51, a leaf spring 55, and a fixing part 63.

An optical element 53 is inserted into the movable part 51, and a predetermined coil (not shown) for driving the movable part horizontally moved in the optical axis direction may be wound and disposed. The optical element 53 may be one of a collimator lens or a beam expander. That is, the optical pickup actuator according to the present invention may be used in combination with a collimator lens or a beam diffuser that is movable to compensate for spherical aberration.

The leaf spring 55 is formed in a 'c' shape, and protrusions 59 having a predetermined length protrude from a central side of the 'c' shape, and are provided on both sides of the 'c' shape. The length of the two leaf springs 57a and 57b is formed at least longer than the length of the protrusion 59. At this time, the end of the protrusion 59 is connected to the fixing portion 63, while the first and second leaf springs (57a, 57b) are connected to the movable portion (51). In order to allow the shape to move freely, it is preferable that a cut is made at a predetermined distance between the outside of the protrusion 59 and the inside of the first and second leaf springs 57a and 57b. In addition, the protruding portion 59 is preferably formed in a horizontal length larger than the length in the vertical direction.

When the movable part 51 is horizontally moved in the optical axis direction in the leaf spring 55 formed as described above, a predetermined displacement occurs at one end 61 of the 'c' shape. That is, when the movable part 51 is horizontally moved in the optical axis direction, the first and second leaf springs 57a and 57b connected to the movable part 51 are bent, and thus the protrusion 59 is bent. . At this time, the one end 61 of the 'c' shape is simultaneously affected by the first and second leaf springs (57a, 57b) and the protrusion 59, a predetermined displacement occurs. Since the displacement of one end 61 of the 'c' shape generated in this way compensates for the displacement of the movable part 51, the movable part 51 is horizontally moved in the optical axis direction without being inclined.

In addition, the effective length of the leaf spring may be the sum of the length of the first and second leaf springs (57a, 57b) and the length of the protrusion (59). Here, the effective length means a range in which the leaf spring 55 actually affects the movement of the movable part 51 in the optical axis direction.

In the conventional leaf spring, the transverse length of the leaf spring is simply the effective length, whereas in the leaf spring 55 according to the present invention, the length of the protrusion 59 in addition to the length of the first and second leaf springs 57a and 57b. By adding more, the rigidity of the leaf spring can be reduced to increase the degree of freedom. The fixing portion 63 is connected to the protrusion 59 to support the leaf spring 55.

Therefore, in the present invention, when the movable portion 51 is moved in the optical axis direction by changing the shape of the leaf spring 55, displacement occurs at one end 61 of the 'c'-shape of the leaf spring 55, thereby causing the movable portion 51 to move. By compensating for the displacement of), the movable part 51 can be horizontally moved in the optical axis direction as it is.

Therefore, the present invention can effectively act to accurately compensate spherical aberration by horizontally moving the movable part by driving the actuator to which the leaf spring with the changed shape is simply applied.

According to the optical pickup actuator of the present invention configured as described above, the spherical aberration can be compensated by horizontally moving the movable part in the optical axis direction by using a leaf spring having a predetermined displacement to compensate for the displacement of the movable part. Due to the fixing of the length of the movable portion can be prevented from inclining in the direction of the fixed portion without moving horizontally.

As a result, by compensating for the displacement generated in the movable portion by the displacement generated in the leaf spring, the displacement generated in the movable portion can be suppressed to the maximum, thereby allowing the movable portion to move horizontally in the optical axis direction.

In addition, the present invention by increasing the effective length of the leaf spring compared with the conventional, it is possible to reduce the rigidity of the leaf spring to minimize the effect on the movable portion.

Claims (12)

In the optical pickup actuator for compensating spherical aberration, A movable part to which an optical element is inserted; Is formed in a 'c' shape, a protrusion having a predetermined length from the central one side of the 'c' shape is formed, the length of the first and second leaf springs provided on both sides of the 'c' shape is the length of the protrusion A leaf spring formed at least longer; And Fixing portion connected to the protrusion to support the leaf spring Made up of An end of the protrusion is connected to the fixing portion, the first and second leaf spring is connected to the movable portion, the actuator for the optical pickup. The optical pickup actuator of claim 1, wherein the optical device is one of a collimator lens and a beam diffuser. The optical pickup actuator of claim 1, wherein an effective length of the leaf spring is a sum of lengths of the first and second leaf springs and lengths of the protrusions. delete delete delete delete delete delete delete delete delete