JPH0620298A - Method and device for controlling aperture diaphragm of optical head - Google Patents

Abstract

PURPOSE:To realize application of a single optical head to optical discs having different recording densities or skew characteristics by adjusting the size of aperture diaphragm for a light beam projected from a light source in the way of optical path to a disc surface. CONSTITUTION:A section 6 for adjusting the aperture adjusting position with respect to an optical path surface or adjusting the size of aperture diaphragm to adjust the diameter of light beam is disposed between a beam splitter 5 and an optical disc 1. The aperture diaphragm adjusting section 6 comprises a variable aperture diaphragm section 6A3 and an actuator 6B3. The actuator 6B3 operates to adjust an iris diaphragm thus effectively adjusting the diameter of light beam passing through the variable aperture diaphragm section 6A3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for adjusting the size of an aperture stop of an optical head.

[0002]

2. Description of the Related Art Conventionally, in various optical disk devices, the numerical aperture NA of an optical head is individually determined according to the recording density and skew characteristics, and based on each numerical aperture NA,
The imaging spot size or depth of focus was determined.

[0003]

However, the numerical aperture NA of the optical disk device is fixed to each device, and for example, an optical head of an optical disk device having an optical head numerical aperture NA of 0.55 is used as it is in a compact disc with a large skew. There has been a problem that the error rate increases especially when reading and writing data using a CD device. On the contrary, if the numerical aperture NA of the optical head for the compact disc CD device is set to 0.45 and the optical head for the compact disc CD device is used for reading an optical disc on which high density recording is performed, data cannot be read. There was a problem. Therefore, in the conventional optical disk device,
One optical head could not be used for various optical discs having different recording densities and skew characteristics.

Therefore, the present invention can be applied to optical disks having different recording densities and skew characteristics even with one optical head by changing the diameter of the light beam in the optical head according to the type of the optical disk. It is an object of the present invention to provide an aperture stop adjusting method and device therefor.

[0005]

As a means for solving the above problems, the present invention is an optical head for an optical disk system, in which an optical beam emitted from a light source is irradiated onto a disk surface in the middle of an optical path. Adjust the aperture size of the beam. Further, the present invention is an optical head of an optical disk system, which is provided with means for adjusting the size of the aperture stop of the light beam.

[0006] Preferably, the means for adjusting the size of the opening has an opening having a constant size moved in a direction orthogonal or oblique to the optical path, and the opening with respect to the optical path. And an actuating means for moving in an orthogonal direction or an oblique direction. Further preferably, the means for adjusting the size of the aperture stop includes an opening having a constant size that can be tilted or rotated to a position substantially orthogonal to the optical path, and the opening with respect to the optical path. And an actuating means for tilting or rotating the opening so as to be located at a position substantially orthogonal to each other. More preferably, the means for adjusting the size of the aperture diaphragm is a variable aperture diaphragm part capable of varying the size of the aperture, and an operating means for operating the diaphragm of the variable aperture diaphragm part according to the size of the aperture. Composed of and.

[0007]

The function of adjusting the size of the aperture stop of the light beam is adjusted in the middle of the optical path for irradiating the disk surface with the light beam emitted from the light source. In the means for adjusting the size of the opening, the opening having a constant size is moved by the actuating means in a direction orthogonal to the optical path or an oblique direction. Further, in the means for adjusting the size of the aperture stop, the actuating means is used to tilt or rotate the aperture to a position substantially orthogonal to the optical path in the opening having a constant size.
Further, in the means for adjusting the size of the aperture stop, the size of the aperture is changed by using the actuating means in the variable aperture stop portion.

[0008]

An embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a partial perspective view showing the configuration of an aperture stop adjusting apparatus applied to an embodiment of an aperture stop adjusting method for an optical head and an aperture stop adjusting apparatus of the present invention, and FIGS. 2 to 4 are apertures used in FIG. It is a figure which shows the specific example of an aperture adjustment device.

The optical head described below is used in an optical disk system. In FIG. 1, an optical disc 1
Are various types of disks having different recording densities and skew characteristics. , This disc 1 is an optical disc O
D, compact disc CD and laser disc LD. The light beam output of the laser diode 2 is converted into parallel light through the collimator 3, and the beam splitter 5
Incident on.

Between the beam splitter 5 and the optical disk 1, an aperture stop adjusting section 6 is provided for adjusting the diameter of the light beam by adjusting the aperture adjustment position with respect to the optical path surface or the size of the aperture stop. ing. The light beam that has passed through the aperture stop adjustment unit 6 has a 90 ° angle of incidence.
The track surface of the optical disc 1 is irradiated through a 45 ° mirror 7 and an objective lens 8 that are deflected by an angle of °. Further, the light reflected by the track surface of the optical disc 1 is the objective lens 8, the mirror 7,
The light enters the beam splitter 5 through the aperture stop adjusting unit 6.

The beam splitter 5 splits incident light and the photodiode 4 detects the light at that time. Further, the light from the beam splitter 5 passes through the prism lenses 9 and 10 and is received by the photodiode 11, which is a light receiving element, and the data read from this output is decoded. In FIG. 1, as shown in FIG. 4, the aperture stop adjusting unit 6 includes a variable aperture stop unit 6A3 and an actuator 6B3.
Consists of. This will be described later.

2 and 3 show an example in which a fixed aperture having a fixed aperture size is used as the aperture stop adjusting unit 6. The aperture stop adjusting unit 6 in FIG. 2 includes a fixed opening 6A1 that moves in the direction orthogonal to the optical path, and an actuator 6B1 that moves the fixed opening 6A1 and the direction orthogonal to the optical path. The fixed opening 6A1 is
For example, it is formed in a square shape, and a circular opening is formed in the center. Therefore, by operating the actuator 6B1 in the direction orthogonal to the optical path, the diameter of the light beam passing through the fixed opening 6A1 can be adjusted by a simple operation of the actuator 6B1.

In the aperture stop adjusting section 6 shown in FIG. 3, a fixed opening 6A2 is tilted or rotated until it is located at a position substantially orthogonal to the optical path, and the fixed opening 6A2 is positioned substantially orthogonal to the optical path. And an actuator 6B2 for tilting or rotating up to. The fixed opening 4A2 is tiltably or rotatably fixed to the support shaft 6B2 = 1 of the actuator 6B, and the actuator 6B2.
The tilting or pivoting position is maintained with the rotation of the.
Therefore, the actuator 6 is tilted until the fixed opening 4A2 is located at a position substantially orthogonal to the optical path surface.
By operating B2, the diameter of the light beam passing through the fixed opening 6A2 can be adjusted more effectively.

The aperture stop adjusting section 6 shown in FIG. 4 is a variable aperture section 6A3 whose aperture size can be varied by an iris stop, and the iris stop is opened / closed according to the aperture size of the variable aperture stop section 6A3. Actuator 6
It consists of B3. Therefore, by operating the actuator 6B3 so as to adjust the iris diaphragm, the aperture of the light beam passing through the variable aperture diaphragm 6A3 can be adjusted more effectively. The actuators 6B1 to 6B3 are operated manually or automatically.

By the way, generally, the numerical aperture NA of the optical lens is
Where n is the refractive index of the lens, r ₀ is the effective radius of the optical lens, f is the focal length, and θ is the angle of view at the object point, the following equation (1) or equation (2) Can be defined as NA = nSinθ (1) = nr ₀ / √ (f ² + r ² ) (2) On the other hand, the spot diameter at the focal point is defined by the numerical aperture NA of the optical lens and the wavelength λ of the light. It is represented by the function λ / NA. That is, the spot diameter at the focal point is the numerical aperture N of the optical lens.
It decreases in inverse proportion to A. Therefore, in order to read the data of higher recording density, it is necessary to make the focal spot small, that is, increase the numerical aperture NA of the optical lens.

On the other hand, the tolerance due to the inclination of the optical disc 1 is expressed as follows. That is, the tolerance for the tilt and skew of the optical disc 1 is a value proportional to λ / (NA) ³ . Therefore, the tolerance for the skew decreases in inverse proportion to the cube of the numerical aperture NA of the optical lens. Further, the tolerance for the uneven thickness of the optical disc 1 is a value proportional to λ / (NA) ⁴ . Therefore, the tolerance for the thickness unevenness of the optical disc 1 decreases in inverse proportion to the fourth power of the numerical aperture NA of the optical lens. From the above,
In the optical head for high recording density optical disc 1 having a large numerical aperture NA of the optical lens, the skew of the optical disc 1
The tolerance for thickness unevenness becomes low. On the other hand, an optical disc 1 having a large shape tolerance such as a compact disc CD
Then, the error rate can be reduced by reducing the aperture stop and decreasing the numerical aperture NA of the optical lens.

In the above-mentioned embodiment, the aperture stop adjusting section 6 shown in FIGS. 2 to 4 is provided to adjust the diameter of the parallel light beam and the objective lens 8 is adjusted.
The numerical aperture N of the optical lens is adjusted by adjusting the diameter of the light incident on
Substantially change A. On the other hand, if the size of the aperture stop of the aperture stop section is opened to the maximum, the optical disc 1 having a high recording density can be handled with the maximum numerical aperture NA of the optical lens. Further, if the size of the aperture stop is reduced and the numerical aperture NA of the optical lens is reduced, it becomes possible to deal with the optical disc 1 having a large shape tolerance.

In the above embodiment, the aperture stop adjusting unit 6
2 to 4 have been described as above, it goes without saying that the aperture stop adjusting unit 6 is not limited to this.
It is sufficient if the radius of the parallel light beam can be reduced or increased to substantially adjust the numerical aperture NA of the optical lens.

[0018]

As described above, according to the present invention, by adjusting the size of the aperture stop to substantially change the numerical aperture of the optical head, different recording densities with a single optical head,
It can also be applied to various optical discs that use skew characteristics and the like.

[Brief description of drawings]

FIG. 1 is a partial perspective view showing a configuration of an aperture stop adjusting apparatus applied to an embodiment of an optical head aperture stop adjusting method and apparatus according to the present invention.

FIG. 2 is a diagram showing an example of a fixed aperture portion that is moved to a position orthogonal to an optical path in the aperture stop adjusting device used in FIG.

FIG. 3 is a diagram showing an example of using the fixed aperture part that tilts or rotates so as to be positioned substantially orthogonal to the optical path surface in the aperture stop adjusting device used in FIG.

FIG. 4 is a diagram showing an example of using the variable aperture part of the aperture stop adjusting device used in FIG. 1 that can change the size of the aperture with respect to the optical path by an iris stop.

[Explanation of symbols]

 1 Optical Disc 2 Laser Diode 3 Collimator Lens 4 Photodiode 5 Beam Splitter 6 Aperture Adjusting Part 6A1 Fixed Aperture 6A2 Fixed Aperture 6A3 Variable Aperture 6B1 Actuator 6B2 Actuator 6B3 Actuator 7 Mirror 8 Objective Lens 9 Wollaston Prism Lens 10 Lens 11 Photodiode

Claims (5)

[Claims] 1. An optical head for an optical disk system, wherein the size of an aperture stop of the light beam is adjusted in the middle of an optical path for irradiating the disk surface with the light beam emitted from a light source. Aperture stop adjustment method. 2. An optical head of an optical disk system, wherein an opening of an optical head provided with means for adjusting the size of an aperture stop of the light beam in the middle of an optical path for irradiating the disk surface with the light beam emitted from a light source. Aperture adjustment device. 3. The means for adjusting the size of the opening includes an opening having a constant size moved in an orthogonal direction or an oblique direction with respect to the optical path, and the opening with respect to the optical path. 3. An aperture stop adjusting device for an optical head according to claim 2, further comprising an operating means for moving the optical head in an orthogonal direction or an oblique direction. 4. A means for adjusting the size of the aperture stop,
An opening having a constant size that can be tilted or turned to a position substantially orthogonal to the optical path, and an opening that is tilted or rotated so that the opening is positioned substantially orthogonal to the optical path. 3. The aperture stop adjusting device for an optical head according to claim 2, further comprising an operating means for moving the optical head. 5. A means for adjusting the size of the aperture stop,
3. The aperture stop adjustment of an optical head according to claim 2, comprising a variable aperture stop unit capable of changing the size of the aperture, and actuating means for operating the stop of the variable aperture stop unit according to the size of the aperture. apparatus.