KR100234250B1 - Lens device with an equal magnification variable focus and optical pickup thereof - Google Patents

Abstract

A lens device for forming a variable magnification and an optical pickup for recording and reproducing for a 0.6 mm disc and a 1.2 mm disc using the same are disclosed. The lens device includes a first lens 26 which is movable along the optical axis and focuses incident light, and a second lens 27 which is fixed to the optical axis and focuses the light focused by the first lens 26 to form a focus. And an actuator 28 for driving the first lens 26. The optical pickup includes the first lens 26 and the second lens 27 as the objective lens. This lens device and optical pickup using the same have the advantage that the recording / playback characteristic of the disk having a high signal-to-noise ratio and different thickness does not change.

Description

Lens device with variable magnification and optical pickup using same

1 is a layout view showing an optical configuration of a conventional bifocal optical pickup.

2 is a partial layout view showing an optical path for a 0.6 mm disk by a conventional bifocal optical pickup.

3 is a partial layout view showing an optical path for a 1.2 mm disk by a conventional bifocal optical pickup.

4 is a layout view showing an optical configuration of an optical pickup including a lens device having a variable magnification according to the present invention.

5 is a layout view illustrating an optical path by the lens apparatus having the same magnification variable focus according to the present invention.

6 is a lens profile showing an optical path for a 0.6 mm disk by a lens device having a variable magnification according to the present invention.

7 is a lens profile showing an optical path for a 1.2 mm disk by a lens device having a variable magnification according to the present invention.

8 is a light profile showing an intensity distribution of a focal point formed on a 0.6 mm disk by a lens device having a variable magnification according to the present invention.

9 is a light profile showing an intensity distribution of a focal point formed on a 1.2 mm disk by a lens device having a variable magnification according to the present invention.

<Explanation of symbols for main parts of drawing>

21: 0.6 mm disc 22: 1.2 mm disc

23 laser diode 26 first lens

27: second lens 28: actuator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lens device having a variable magnification and an optical pickup for recording and reproducing using the same. In particular, a lens device having a dynamic magnification and a separate magnification that can move a focus to an image plane of another position as the same magnification and use thereof Therefore, the present invention relates to an optical pickup capable of recording and reproducing a disc having a different thickness at the same magnification focus.

Compact discs, now widely known as optical recording media, have a substrate thickness of 1.2 mm. Recently, discs with a thickness of 0.6 mm have also emerged for high density storage. In order to read information stored at high density, it is necessary to reduce the size of the light spot. For this purpose, it is necessary to use a short wavelength light source and an objective lens having a large numerical aperture (NA). However, a lens with a large NA is very unstable with respect to the aberration of the disk substrate when the disk is tilted, so strict regulation on the disk tilt at the time of reproduction is required. The aberration of the disk substrate is increased in proportion to the thickness and the degree of inclination of the substrate. Therefore, practical high-density reproduction can be realized by making the thickness of the substrate as thin as possible to increase the tolerance of the disc inclination.

As a result of the emergence of disks of different thicknesses, the user has demanded an optical pickup that can be shared with other disks. In this regard, dual focus optical pickups for 0.6 mm and 1.2 mm discs as shown in FIG. 1 have been limited through the International Symposium on Optical Memory (May 1994). Of course, in the optical pickup proposed in the document, the aberration due to the thickness difference of the disks is corrected.

In Fig. 1, reference numeral 1 denotes a 0.6 mm disc and 2 denotes a 1.2 mm disc. Substantially any one of the disks 1 and 2 is loaded into a disk drive (not shown). Conventional bifocal optical pickup includes a laser diode (3) for generating laser light, a half mirror (4) for partially reflecting and partially transmitting light, and the disk (1) in the half mirror (4). 2) a collimating lens (5) for advancing the reflected light in parallel to the light, and a hologram lens (6) for diffracting the collimated light by the collimating lens (5) And an object that focuses the transmitted zero order light 7 and the first order diffracted light 8 of the hologram lens 6 onto the disks 1 and 2, respectively. It consists of a lens 9 and a sensor lens 10 and a photo detector 11 arranged to detect a signal from the reflected light of the disks 1 and 2. The 0.6 mm disc 1 is read here as the transmitted zero-order light 7 of the hologram lens 6 as shown in FIG. 2, and the 1.2 mm disc 2 is shown as its hologram lens (as shown in FIG. 3). It is read by the 1st order diffracted light 8 of 6). According to the cited document, the above-described hologram lens 7 is blazed to diffract one of + 1st-order diffraction light and -1st-order diffraction light in order to prevent a decrease in light efficiency.

However, in the dual focus optical pickup having the hologram lens as described above, since the incident light is divided into zero-order light and first-order diffraction light by the hologram lens, and one of them is used to read a signal of a loaded disk, the light efficiency is very low. As a result, the new-to-noise rate of the reproduction signal by the photodetector decreases. In addition, since one of the loaded disks has the focus for the other disk at the same time, practical recording is impossible due to the optical interference of the other focus, and two reflected light from the loaded disk are simultaneously received by the photodetector, which is also caused by the optical interference. It is difficult to detect a clean playback signal and an accurate focus position signal. In addition, when the objective lens and the hologram lens, which are refractive lenses, are used together, the objective lens generally has a high order aspherical coefficient, and thus its manufacture is difficult. Especially, when using a short wavelength light source, wavefront aberration There is a problem of increasing inversely proportional to the wavelength of light.

On the other hand, for constant recording and playback characteristics for discs of different thicknesses, the aberrations due to the thickness differences must be corrected, and it is necessary to form focal points of the same size and intensity on discs of different thicknesses.

Accordingly, it is an object of the present invention to provide a lens apparatus capable of forming a single focal point and changing the imaging position of the focal point in order to solve all the above-mentioned problems in view of the advantages.

It is another object of the present invention to provide an optical pickup that can be shared for recording and playback of discs of different thicknesses by using a lens device that can form a single focal point and change the imaging position of the focal point.

Another object of the present invention is to provide a lens device capable of changing the focusing position of a single focal point at the same magnification and an optical pickup using the same.

The lens device of the present invention, which achieves the above object, is a lens device for forming a variable focus of the same magnification, the lens device being movable in the optical axis direction and focusing the incident light, and fixed in space And a second lens for focusing light focused by a first lens to form a focus, and lens driving means for moving the first lens to change the position of the focus by the second lens. It is characterized by.

In addition, the optical pickup of the present invention to achieve the above object is, in the optical pickup for forming a focus of the same magnification on the disk having a different thickness, a light source for generating light, and is generated from the light source that is movable in the optical axis direction The first lens focuses the light, the second lens spatially fixed and focuses the light focused by the first lens to form a focus on the disk, and the focus by the second lens is thick. And lens driving means for moving the first lens to be formed in another disk, and means for detecting a signal from the light reflected by the disk.

That is, the present invention is provided with at least two lenses of the first lens and the second lens as an objective lens to form a variable focus by moving the first lens. Referring to the drawings in detail as follows.

4 shows a configuration of an optical pickup having a lens device forming a variable focus according to the present invention. In the figure, reference numeral 21 is, for example, a 0.6 mm disk, and 22 is, for example, a 1.2 mm disk. Of course, any one of these disks 21 and 22 is loaded into a drive not shown. The optical pickup forming the variable focus according to the present invention includes a laser diode 23 for generating laser light as a light source, a half mirror 24 for partially reflecting and partially transmitting light, and a disc 21, 22 in a half mirror 24. The collimating lens 25 for advancing the reflected light in parallel to the (), the first lens 26 is installed so as to move along the optical axis to focus the collimated light by the collimating lens 25 A second lens 27 and a second lens 27 that focus on the loaded disk by focusing again the light focused by the first lens 26 while being fixed to the optical axis. An actuator 28 for driving the first lens 26 provided for moving from the position of the sensor to another position, and a sensor lens arranged to detect a signal from the light reflected from one of the disks 21, 22. 29) and the photodetector 30 have.

Referring to FIG. 5, the focal position formed by the second lens 28 also changes according to the changing interval D ₀ between the first lens 26 and the second lens 27. Therefore, the first lens 26 is properly moved to read the 0.6 mm disc 21 as shown in FIG. 6 or to the 1.2 mm disc as shown in FIG. 7 with the focal point of the second lens 27 along the first lens 26. 22) can be read. According to the present invention, the distance D ₁ , D ₂ between the first lens 26 and the second lens 27, and the exit surface of the second lens 27 to the first surface of each of the disks 21, 22. By optimizing the working distances W ₁ and W ₂ , the focus is formed at the same magnification on both disks 21 and 22.

The following is an embodiment of the present invention, the lens data for the optimal design through the simulation verification for the 0.6mm disk and 1.2mm disk.

First lens (aspherical lens)

Thickness: 1.13㎜

Refractive Index: 1.515

1st surface curvature: 4.05㎜

Conical Constant: 0.20

Aspheric coefficient: 0.72e ^-3 , -0.12e ^-4 , -0.89e ^-5 , 0.92e ^-6

Second surface curvature: 4.72 mm

Cone constant: -0.17

Aspheric coefficient: -0.14e ^-2 , 0.10e ^-3 , 0.27e ^-4 , -0.33e ^-6

Second lens (aspherical lens)

Thickness: 3.48㎜

Refractive Index: 1.515

First curvature: 3.04㎜

Cone Constant: 0.07

Aspheric coefficient: -0.79e ^-2 , -0.63e ^-3 , 0.27e ^-3 , -0.21e ^-4

Second surface curvature: -8.44㎜

Conical Constant: 8.80

Aspheric coefficient: -0.79e ^-2 , 0.41e ^-1 , -0.14e ^-2 , 0.55e ^-3

When 0.6 mm disc (substrate refractive index: 1.51) is used

Distance between the first lens and the second lens (D ₁ ): 0.26mm

Working distance (W ₁ ): 1.91㎜

When using a 1.2 mm disc (substrate refractive index: 1.51)

Distance between the first lens and the second lens (D ₂ ): 1.57mm

Working distance (W ₂ ): 1.5㎜

As described above, the present invention corrects the aberration due to the thickness difference of the disk using an aspherical lens. The first lens according to the embodiment has almost no optical magnification. Therefore, the second lens forms a focal point at a constant magnification regardless of the moved position of the first lens. On the other hand, the moving distance of the first lens is within 0.3 mm. This distance can be simply driven using a piezoelectric element as the actuator described above. Next, the light intensity distributions of the focal points formed on the 0.6 mm and 1.2 mm discs, respectively, are attached to Figs. In the figure, the horizontal axis represents the size of the light spot. According to this result, it can be seen that the rate of change of the size of the spot formed on the 0.6 mm disk and the 1.2 mm disk according to the present invention is within 5% and hardly changes, that is, formed at the same magnification.

As described above, the present invention forms a separate focus of equal magnification with two lenses, and forms the same magnification on disks having different thicknesses. According to the present invention, since the light is not divided, the signal band at the time of recording and reproduction with high optical efficiency The noise ratio can be improved and the same magnification focus can be made even for discs of different thicknesses, which can provide optical pickups whose characteristics do not change depending on the thickness of the discs.

Claims (4)

An optical pickup having a variable magnification of focus capable of forming a focal magnification focus on a disk having a different thickness, the optical pickup having a light source for generating light and a first light source for focusing light generated from the light source and movable in the optical axis direction A second lens for focusing on the disk by refocusing the lens, the spatially fixed and primarily focused light by the first lens, and the focal position by the second lens to vary according to the selected disk thickness And lens driving means for moving the first lens, and means for detecting a signal from the light reflected from the disk. The optical pickup of claim 1, wherein the moving range of the first lens is within 0.3 mm. The optical pickup of claim 1, wherein the operating distance from the second lens to the disk is set differently according to the thickness of the disk. The optical pickup of claim 1, wherein the first lens and the second lens satisfy the following conditions for the 0.6 mm disk and the 1.2 mm disk. First lens (aspherical lens) Thickness: 1.13㎜ Refractive Index: 1.515 1st surface curvature: 4.05㎜ Conical Constant: 0.20 Aspheric coefficient: 0.72e ^-3 , -0.12e ^-4 , -0.89e ^-5 , 0.92e ^-6 Second surface curvature: 4.72㎜ Cone constant: -0.17 Aspheric coefficient: -0.14e ^-2 , 0.10e ^-3 , 0.27e ^-4 , -0.33e ^-6 Second lens (aspherical lens) Thickness: 3.48㎜ Refractive Index: 1.515 1st surface curvature: 3.04㎜ Cone Constant: 0.07 Aspheric coefficient: -0.79e ^-2 , -0.63e ^-3 , 0.27e ^-3, -0.21e ^-4 Second surface curvature: -8.44㎜ Conical Constant: 8.80 Aspheric coefficient: -0.79e ^-2 , 0.14e ^-1 , -0.41e ^-2 , 0.55e ^-3 When 0.6 mm disc (substrate refractive index: 1.51) is used Distance between the first lens and the second lens: 0.26 mm Working distance: 1.91㎜ When using a 1.2 mm disc (substrate refractive index: 1.51) Distance between the first lens and the second lens: 1.57 mm Working distance: 1.5 mm