JPH0470700B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an optical deflection device for laser light irradiated onto an optical disk. The present invention relates to an optical deflection device that enables tracking control of an optical pickup having a member without moving it in a direction across a track on an optical disk surface.

(Prior art) Conventionally, when a focused laser beam is irradiated onto a track of an optical disk and the focused laser beam is moved in a direction across the track of the optical disk, a reflector in an optical pickup or an objective lens is driven. a first moving means that operates at a relatively high speed and in response to a small movement width; and a second movement means that operates at a relatively low speed and in response to a large movement width by controlling the movement of the entire optical pickup in the direction. This was done by using these two means and operating these two means appropriately. There is also a method in which the entire movement is covered by only the second moving means, but in either case, means for moving the entire optical pickup is provided.

(Problems to be Solved by the Invention) When moving the irradiation point of the laser focused light on the optical disk to a desired opening, it is necessary to move the optical pickup in a direction across the track of the optical disk. However, because the inertial mass of this optical pickup is large, it takes time to move it.
It has the disadvantage that it is difficult to quickly write signals to and read signals from the optical disk.

The present invention provides an optical deflection device which eliminates the disadvantages of the conventional method without using means for moving the entire optical pickup.

(Means for solving the problem) Assuming a certain cone, it is possible to make an acute angle with a reference plane corresponding to the base of the cone, and whose cross section is an arc when cut along a plane parallel to this reference plane. a light reflecting means having a reflecting surface corresponding to a side surface; a light reflecting means centered on a point on the central axis of the cone in order to enter a laser beam of a predetermined optical path and irradiate a desired position of the reflecting surface with the laser beam; It also includes an optical path deflecting means for emitting the laser beam in a radiation direction forming a constant angle with the axis.

(Function) The optical path length of the laser beam emitted from the optical path deflecting means to the reference plane is always constant regardless of the radiation direction.

(Embodiment) Fig. 1 is a block diagram showing an embodiment of the optical path deflection device of the present invention.
(eraser blue direct read after write) type optical disk device.

Figure 1a shows the top view, Figure 1b shows the first
Main parts of a cross-sectional view taken along reference line A-A in Figure a are shown.

After the laser light emitted from the semiconductor laser 1 in the figure is made into parallel light by the collimator lens 2,
It is shaped by the shaping prism 3 so that its cross section becomes circular. This shaped laser beam is turned into a focused light by a condensing lens 4 consisting of a combination of a concave lens and a convex lens, and then passes through a half mirror 5.
The rotation mirror 6 is reached. This rotating mirror 6 has its rotating shaft 6 ₂ rotationally driven by a drive motor 16 , and the axis center of this rotating shaft 6 ₂ is perpendicular to the irradiation surface 8 ₁ of the magneto-optical disk 8 . The structure is such that one point coincides with the center of the light spot on the planar reflecting surface ₆₁ . Therefore, the planar reflective surface ₆₁ of the rotary mirror 6 rotates while maintaining a predetermined angle with the irradiation surface of the magneto-optical disk 8, and the laser focused light reflected by this reflective surface is caused by this rotation. The light is then reflected in the radial direction from the center of the light spot and reaches the arcuate mirror 7.

The laser focused light reflected by the arcuate mirror 7 is directed to the irradiation surface 8 of the magneto-optical disk 8 having a pre-groove.
It reaches ₁ .

The reflective surface 7 ₁ of the arcuate mirror 7 maintains a predetermined angle with the irradiation surface 8 ₁ of the magneto-optical disk 8.
It is formed in an arc shape centered on the rotation center of the rotation mirror 6 so as to cross the recording area 8 ₂ of the magneto-optical disk. By forming the rotating mirror 6 and the arcuate mirror 7 as described above, the condenser lens 4
The optical path distance of the laser focused light emitted from the magneto-optical disk 8 to the irradiation surface ₈₁ of the magneto-optical disk 8 is always constant regardless of the rotating position of the rotating mirror 6. Therefore, by adjusting the condenser lens 4 so that the irradiation surface ₈₁ of the magneto-optical disk 8 becomes the focus position of the laser beam at a certain rotational position of the rotational mirror 6, the rotation of the rotational mirror 6 can be controlled. Although the irradiation point of the laser focused light moves along an arc within the recording area ₈₂ of the magneto-optical disk 8 in accordance with the motion, its focal position always coincides with the irradiation surface of the magneto-optical disk.

Incidentally, the angle that each reflecting surface of the rotating mirror 6 and the arcuate mirror 7 makes with the irradiation surface ₈₁ of the magneto-optical disk is as follows:
The laser beam is set to be irradiated perpendicularly to the irradiation surface of the magneto-optical disk, which is determined depending on the setting of the optical path of the laser beam.

The reflected return light reflected by the irradiation surface 8 ₁ of the magneto-optical disk is reflected by the arc-shaped mirror 7 and the rotating mirror 6, respectively, and reaches the half mirror 5. The reflected return light reflected by the half mirror 5 is divided by the half mirror 9. One of the reflected return lights passes through a condenser lens 10 and reaches a two-split photodetector 11 for detecting a tracking error signal. The reflected return light passes through a condensing lens 12 and an analyzer 13 and reaches a recording signal detector 14.

Around the irradiation point, which moves on the irradiation surface 8 ₁ of the magneto-optical disk in accordance with the rotation of the rotating mirror 6, there is a yoke 15 ₁ around which a coil 15 ₂ is wound to form a bias magnetic field during recording and erasing. A bias magnet 15 is formed along the arcuate mirror 7. This bias magnet 15 is
By passing a direct current in a predetermined direction through the coil ₁₅₂ , a bias magnetic field is formed around the irradiation point.

An example of a motor control device for the drive motor 16 is shown in FIG. 1c.

In the figure, a subtracter 29 inputs the light intensity signals from the detectors 11a and 11b of the two-part photodetector 11, and calculates the position of the irradiation point with respect to the pregroove formed on the magneto-optical disk by taking the difference between these light intensity signals. Outputs a tracking error signal based on the information. Motor control circuit 21
inputs this tracking error signal and outputs a drive motor control signal to the motor driver 22 to control the drive motor 16 in order to regulate the irradiation point to a predetermined position in the pregroove.

The above control system performs tracking control of the irradiation point during normal recording and reproduction.

On the other hand, when track movement is performed to access the desired irradiation position on the magneto-optical disk 8, a command signal is output from the track movement command circuit 20. When the motor control circuit 21 receives the input command signal, it interrupts the tracking control described above, and outputs a control signal to the motor driver 22 to drive the drive motor 16 in accordance with the command signal.

This truck movement command circuit 20 outputs command signals based on various information, for example,
The positional information recorded on the magneto-optical disk 8 is selected from the reproduced signal detected by the recording signal detector 14, and a command signal is output or rotated so that this positional information and the specified position specified by the operator match. A potentiometer is provided to detect the rotational position of the movable mirror 6, and the output signal from this potentiometer, which is related to the radial position of the irradiation point on the magneto-optical disk, is matched with the radial position specified by the operator. It can be configured appropriately depending on the application, such as outputting a command signal, or outputting a track jump command for each rotation of the optical disc if the pregroove of the optical disc is formed in a concentric circle. However, since it is not directly related to the present invention, a detailed explanation thereof will be omitted.

When recording signals with the above configuration, in order to generate a bias magnetic field around the irradiation point of the magneto-optical disk 8, a DC current in a predetermined direction is supplied to the coil ₁₅₂ of the bias magnet 15 by a current supply means (not shown). Then, in this state, the laser beam outputted from the laser 1 is modulated with a recording signal to obtain a laser beam of a predetermined level.

On the other hand, when reproducing a signal from the magneto-optical disk 8, the laser beam output from the laser 1 is set to a predetermined reproduction level and passes through the analyzer 12 in accordance with the recorded signal recorded on the magneto-optical disk. This is done by detecting the reflected return light with the recording signal detector 14.

In addition, when recording and reproducing using the above-mentioned magneto-optical disk, at the time of recording, the Curie point recording is
During reproduction, the Kerr effect is used, but a detailed description of its principle, optimum laser output, modulation method, optimum bias magnetic field, etc. will be omitted.

FIG. 2 is a block diagram showing another embodiment using the device of the present invention, which is used in an E-DRAW type optical disk device using a magneto-optical disk, similar to FIG. 1.

The top view is shown in Fig. 2a, and Fig. 2a is shown in Fig. 2b.
The main parts of a cross-sectional view taken along the reference line BB inside are shown, and parts common to those in FIG. 1 are designated by the same reference numerals.

Laser light emitted from a semiconductor laser 1 in the figure is collimated by a collimator lens 2 and then shaped by a shaping prism 3 so that its cross section becomes circular. This shaped laser beam is passed through a condensing lens 4 consisting of a combination of a concave lens and a convex lens.
The light becomes a focused light, passes through the half mirror 5, and then reaches the light deflection element 17. The laser beam whose traveling direction is changed to a desired direction by the optical deflection element 17 is reflected by the above-mentioned arcuate mirror 7' and then reaches the reflecting surface ₈₁ of the magneto-optical disk 8 having a pre-group. After the reflected return light reflected by this reflective surface reaches the same optical path half mirror 5 and is reflected, the same processing as described above with reference to FIG. 1 is performed.

The light deflection element 17 is made of a crystal with a large photo-elastic effect (for example, a single crystal such as PbMO ₄ or TiO ₂ ),
By applying ultrasonic vibration of frequency f, it is possible to deflect light according to this frequency f.

Further, the arcuate mirror 7' has its reflecting surface ₇₁ ' at a predetermined angle with the irradiation surface of the magneto-optical disk 8, as in FIG. It is formed to be a point P. With the formation as described above, the optical path distance of the laser focused light emitted from the condensing lens 4 to the irradiation surface ₈₁ of the magneto-optical disk 8 is as follows.
It is always constant regardless of the deflection angle α by the optical path deflection element 17. Therefore, by adjusting the condenser lens 4 so that the irradiation surface 8 ₁ of the magneto-optical disk 8 becomes the focal point of the laser beam at a certain deflection angle, the irradiation point of the laser beam can be set to the irradiation point of the optical deflection element 17 . Although it moves along an arc within the recording area 8 ₂ of the magneto-optical disk 8 according to the deflection angle, its focal position always coincides with the irradiation surface of the magneto-optical disk.

The angle between the reflecting surface of the arc-shaped mirror 7' and the irradiation surface of the magneto-optical disk is set so that the laser focused light is irradiated perpendicularly to the irradiation surface of the magneto-optical disk. It is determined according to the setting.

Further, the bias magnet 15 disposed near the arcuate mirror 7' has the same structure and effect as in FIG. 1, and its explanation will be omitted.

FIG. 2c shows an example of a drive control device for the optical path deflection element 17.

In the figure, 19 is a drive voltage generator, 18 is a deflection signal generator, ₁₇₁ is an electroacoustic transducer for ultrasonically driving the optical path deflection element, and 23 is an optical path deflection element control circuit.

The optical path deflection element control circuit 23 includes the detector 11
A tracking error signal output from a subtracter 29 which inputs each light quantity signal from a and 11b is input, and a control signal is output to a drive voltage generator 19 to regulate the irradiation point to a predetermined position in the pregroove. The drive voltage generator 19 outputs a voltage signal according to the input control signal and outputs a voltage signal to the deflection signal generator 18.
Change the frequency of the output signal output from.
Then, the ultrasonic vibration frequency of the electroacoustic transducer 17 ₁ that ultrasonically drives the optical deflection element 17 is changed to control the deflection angle of the light by the optical deflection element. Tracking control of the irradiation point is performed by the above control system.

The operation when recording and reproducing signals in the above configuration and the track movement operation of the irradiation point by the track movement command circuit 20 are as follows.
This is the same as the figure, and the explanation will be omitted since it will be redundant.

FIG. 3 is a block diagram showing another embodiment using the device of the present invention, and shows a device for a DRAW (Direct Read After Write) or read-only optical disc.

Fig. 3a shows a top view thereof, and Fig. 3b shows a main part of a sectional view taken along the reference line C-C in Fig. 3a, and parts common to Fig. 1 are given the same reference numerals. Shown.

Laser light emitted from a semiconductor laser 1 in the figure is collimated by a collimator lens 2 and then shaped by a shaping prism 3 so that its cross section becomes circular. This shaped laser beam is passed through a condensing lens 4 consisting of a combination of a concave lens and a convex lens.
The light is focused into a polarized beam splitter 24.
After passing through the λ/4 plate 25, the rotating mirror 6
leading to. The laser focused light reflected by this reflective surface is reflected by the arcuate mirror 7 and then reaches the irradiation surface 8 ₁ ' of the optical disk 8'.

The configurations of the arc-shaped mirror 7, the rotary mirror 6, and the driving means for the rotary mirror are the same as those shown in FIG. 1, and their explanation will be omitted.

The reflected return light reflected by the irradiation surface 8 ₁ ' of the optical disk reaches the polarizing beam splitter 24 along the same optical path and is reflected, then passes through the condenser lens 26 and reaches the two-split photodetector 11.

Each light amount signal output from each detector 11a, 11b of this two-divided photodetector 11 is as follows.
Recording signal information recorded on the optical disc is detected by the addition signal, and tracking error signal based on positional information of the irradiation point with respect to the pregroove or pit formed on the optical disc is detected by the difference signal.

One method of tracking control performed using this tracking error signal can be achieved by the motor control device shown in FIG. 1c, but a description of recording signal information detection will be omitted.

In the above configuration, when a signal is recorded on an optical disk using the DRAW method, the laser beam output from the laser 1 is modulated with a recording signal to obtain a laser beam of a predetermined level.
In addition, when reproducing signals from an optical disk, the laser beam output from the laser 1 is set to a predetermined reproduction level, and the reflected return light, which changes depending on the recording signal recorded on the optical disk, is divided into two photodetectors 11. This is done by detecting the

The principle of signal recording and reproduction using this optical disk,
The laser control method, tracking error, signal detection method, etc. are well-known techniques and are not directly related to the present invention, so a detailed explanation thereof will be omitted.

FIG. 4 shows another embodiment of the device of the present invention, in which E-DRAW using a magneto-optical disk is performed similarly to FIG. 1.
Although it is a type of device, it is configured to perform recording and reproduction using two lasers.

Components common to those in FIG. 1 are designated by the same reference numerals.

In the figure, the parts numbered 1 to 14 are the same as those in FIG. 1, and their explanation will be omitted. However, at the reference rotational position of the rotational mirror 6 shown in the figure, the irradiation point of the laser beam from the semiconductor laser 1 is set to be located at the innermost track of the recording area ₈₂ of the magneto-optical disk 8. . On the other hand, the laser beam emitted from the semiconductor laser 1' is made into parallel light by the collimator lens 2', and then
It is shaped by a shaping prism 3' so that its cross section becomes circular. This shaped laser beam is passed through a condensing lens 4' consisting of a combination of a concave lens and a convex lens.
The light becomes a focused light, passes through the half mirror 5', and then reaches the rotating mirror 6. The laser focused light reflected by the reflection surface 6 ₁ of this rotary mirror is reflected by the arcuate mirror 7 and then reaches the irradiation surface 8 ₁ of the magneto-optical disk 8 . The returned light reflected by the irradiation surface 8 ₁ is reflected by the arc-shaped mirror 7 and the rotating mirror 6, respectively, and reaches the half mirror 5'. The reflected return light reflected by this half mirror 5' is transmitted to the condenser lens 1.
2', passes through the analyzer 13' and records the signal on the detector 1.
It reaches 4'.

The position of the irradiation point by this semiconductor laser 1' is determined at the recording area 8 of the magneto-optical disk 8 when the rotating position of the rotating mirror 6 is at the reference position described above.
It is set to be located at the center track of ₂ .
Therefore, the rotating mirror rotates from the reference position in the direction of arrow B in FIG.
When the irradiation point P ₁ moves through the recording area 8 ₃ in the inner half of the recording area 8 ₂ , the irradiation point P ₂ of the semiconductor laser 1' moves across the recording area 8 ₂ while maintaining the same distance from the irradiation point P ₁ . Outer half recording area 8 ₄
move.

Further, as an example of driving the rotary mirror 6, the drive motor 16 and motor control device shown in FIG. 1 are referred to.

When two semiconductor lasers are used as in the configuration described above, the moving distance of the irradiation point is halved compared to the case where only one semiconductor laser is used, and parallel recording and reproduction becomes possible. Therefore, the time required for signal recording, reproduction, and access can be halved.

Next, by using the device of the present invention, a tracking control method that can be easily achieved without forming a pregroove on the irradiated surface of a magneto-optical disk will be described.
This will be explained using FIGS. 5 and 6.

In this method, a slit-shaped reflective portion and a non-reflective portion are formed on the reflective surface 71 of the arcuate mirror 7 of the optical disk device shown in FIG. ₁ , corresponding to the desired recording radial position of the magneto-optical disk. FIG. 5a shows an optical disk device having an arc-shaped mirror 28 formed with a reflective portion and a non-reflective portion.

FIG. 5b shows the reflective portion 28 ₂ formed on the reflective surface 28 ₁ of the arc-shaped mirror, the non-reflective portion 28 ₃ , the reflection point R ₁ of the laser focused light, and the photodetectors 11a and 11b of the two-split photodetector 11. Each hypothetical light amount detection range on the reflective surface is shown.

In this case, by controlling the rotating mirror 6 based on the amount of light detected by each of the detectors 11a and 11b, the position of the reflection point _R1 can be controlled to be approximately at the center of the reflection section ₂₈₂ .

FIG. 6 is a configuration diagram in which a group ₂₈₄ is formed instead of forming a non-reflective portion on the reflective surface ₂₈₁ , and FIG. 6a shows the reflective surface 28 of the circular arc mirror.
₁ is a front view showing the group 28 ₄ formed in 1, the reflection point R ₁ of the laser focused light, and each virtual light amount detection range on this reflection surface by each of the detectors 11a and 11b of the 2-split photodetector 11. FIG. 6b shows a cross-sectional view taken along line D-D.

The depth h of the group 28 ₄ to be formed is set so that the difference between the optical path length of the laser beam reflected in this group and the optical path length of the laser beam reflected outside the group is 1/2 wavelength of the laser beam. It is determined by the wavelength λ of the laser beam, the incident angle θ of the laser beam with respect to the reflecting surface 28 ₁ , etc.

The laser beam reflected by the reflection surface 28 ₁ of the arc-shaped mirror in which the group 28 ₄ is formed is detected by the two-split detectors 11a and 11b, and is reflected by controlling the rotary mirror 6 based on the amount of each detected light. The position of point _R1 can be controlled between groups.

However, the recording tracks formed using the above arc-shaped mirror 28 are concentric circles.

It should be noted that the present invention is not limited to the above-mentioned embodiment, and for example, a piezo element may be used instead of the drive motor 16 of the rotary mirror 6, and the control circuit for controlling the piezo element may be changed as appropriate.

In addition, when performing focus control of the laser beam, an optical system such as an astigmatism method or a critical angle method, a 4-split photodetector, and a focus control circuit may be employed to drive and control the condensing lens 4 as necessary. Various aspects are possible, such as becoming possible.

(Effects of the Invention) According to the optical deflection device of the present invention, tracking of the irradiation point on the irradiation surface of the optical disk is controlled by controlling the optical path deflection means with small inertial mass such as the rotating mirror 6 and the optical deflection element 17. , and movement control, it becomes possible to quickly write signals to and read signals from the optical disk.

In addition, by providing a predetermined slit-shaped non-reflective portion or group on the reflective surface of the arcuate mirror, tracking control can be performed without forming pre-groups on the recording surface of the optical disk, so that concentric recording tracks can be formed. becomes possible.

[Brief explanation of drawings]

FIGS. 1 to 6 each show a configuration of an embodiment of the present invention. 1... Semiconductor laser, 2... Collimator lens, 3... Molded prism, 4, 10, 12, 26
...Condensing lens, 5, 9...Half mirror, 6...
... Rotating mirror, 7... Arc-shaped mirror, 8... Magneto-optical disk, 11... Two-segment photodetector,
13...Analyzer, 14...Record signal detection circuit, 1
5... Bias magnet, 16... Drive motor, 17... Optical deflection element, 18... Deflection signal generator, 19... Drive voltage generator, 20... Track movement command circuit, 21... Motor control circuit , 22...
... Motor driver, 23 ... Optical deflection element control circuit, 24 ... Polarization beam splitter, 25 ...
λ/4 board, 29...subtractor.

Claims (1)

[Claims] 1. Assuming a certain cone, a side surface of the cone that makes an acute angle with a reference plane corresponding to its base and whose cross section when cut along a plane parallel to this reference plane is a circular arc. a light reflecting means having a corresponding reflecting surface; comprising an optical path deflecting means for emitting the laser beam in a radiation direction forming a constant angle with the axis, and configured so that the optical path length of the laser beam emitted from the optical path deflecting means to the reference plane is always constant. A light deflection device featuring: 2. The optical path deflecting means is characterized by being constituted by a rotating mirror whose planar reflecting surface rotates while maintaining a predetermined angle with the reference plane, and whose rotation center coincides with the central axis. An optical path deflection device according to claim 1. 3. The optical path deflection device according to claim 1, wherein the optical path deflection means is constituted by an optical deflection element. 4. The optical path deflection device according to claim 1, wherein a slit-shaped non-reflective portion or group is formed on the reflective surface of the light reflecting means. 5. Claim 5, characterized in that a plurality of laser beams are configured to be incident on the flat reflecting surface of the rotating mirror from different incident directions but having the same optical path angle with respect to the reference surface. The optical path deflection device according to item 2.