JPH09223322A - Optical head device and its production - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical head of which adjustment work is easy and reduction of the assembly cost and parts cost is possible. SOLUTION: An imaging lens 22 is moved in parallel with the exit surface of a first beam splitter 14 so as to maximize the output of an APC(automatic output control) monitor photodetector 21 in the state of bringing the imaging lens 22 formed into a plane at one face into tight contact with the exit surface of the first beam splitter 14. As a result, a laser beam for monitor is converged to the photodetecting center of the APC monitor photodetector 21. At this time, the imaging lens 22 is fixed with a UV-curing type adhesive. As a result, the degradation in the output of the high-frequency band of the APC monitor photodetector 21 is prevented.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical head device for recording information on an optical disc as a recording medium and reproducing information from the optical disc, and a method for manufacturing the optical head device.

[0002]

2. Description of the Related Art An optical head device used for recording information on an optical disc as a recording medium and reproducing information from the optical disc irradiates a recording surface of the optical disc with a light beam and reflects the recording surface of the optical disc. It has an actuator (movable part) for extracting the reflected light beam, that is, a main body unit (fixed part) for providing the light beam to the actuator and for extracting the data recorded on the optical disk from the reflected light beam as an electric signal. doing.

The main body unit has a laser element as a light source for generating a light beam, a laser driving circuit for driving the laser element, a change in intensity of the light beam generated by the laser element, and a laser driving circuit for driving the laser beam. Automatic power control (Auto Power Con
trol, APC) mechanism and a photo detector for taking out the data recorded on the optical disk as an electric signal.

In the actuator, the light beam supplied by the laser element of the main body unit is focused on a predetermined depth of the recording surface of the optical disk, that is, the recording layer, and the reflected light beam reflected by the recording layer of the optical disk is formed in the main body unit. Objective lens for stable incidence on the photodetector, drive coil for moving the objective lens in the direction perpendicular to the recording surface of the optical disc, and propulsion for moving the objective lens by force generated by supplying current to the drive coil A magnetic circuit is arranged for conversion into force.

By the way, today, in order to increase the recording density, the recording pits are made finer, that is, the diameter of the light beam irradiated from the optical head device to the recording surface of the optical disk is reduced, the interval between the optical beams in the radial direction is reduced, and the optical disk is reduced. Various methods have been proposed, such as reducing the interval between recording pits on the track, and increasing the sensitivity of a photodetector that detects a reflected laser beam from the optical disk.

[0006]

However, since the size of the recording pit depends on the wavelength of the laser beam emitted from the laser element, the method of reducing the size of the recording pit inevitably has a limit point. Have. For the same reason, there is an upper limit on the extent to which the distance between recording pits can be reduced. Further, increasing the sensitivity of the photodetector has a problem that a noise component is undesirably increased when data is taken out from the reflected light beam reflected by the optical disc.

Separately from this, the size of the recording pit is reduced, that is, the diameter of the light beam is reduced, so that the APC monitor photodetector included in the APC mechanism is fixed so that the center of the light receiving portion coincides with the center of the light beam. There is a problem that high positional accuracy is required for work. The APC monitor photodetector is usually fixed to a predetermined position of the main unit by a method of fixing the monitor photodetector to the support member and then moving and fixing the support member to an appropriate position.

As a result, the center of the light receiving portion of the APC monitor photodetector and the center of the light beam are likely to be displaced, resulting in a problem that the band of the APC monitor photodetector is lowered and the response speed is slowed.

Further, when fixing the support member of the APC monitor photodetector to the main body unit, the support member and the AP are fixed.
There is a problem that a positional deviation occurs between the C monitor photo detector and the C monitor photo detector. When this displacement occurs, adjustment work for correcting the position of the APC monitor photodetector is required, which causes a problem of increasing the assembly cost of the optical head device. Since the supporting member is generally fixed to the main body unit with a screw or the like, the degree of positional deviation is one difference between the diameter of the screw hole of the supporting member and the outer shape of the screw.
If it exceeds / 2, it is necessary to replace the APC monitor photodetector, and as a result, there is a problem that the cost of parts of the optical head device increases. An object of the present invention is to provide an optical head device in which adjustment work is easy and assembly costs and component costs can be reduced.

[0010]

The present invention has been made based on the above-mentioned problems, and includes a semiconductor laser for emitting a laser beam, an objective lens for irradiating a recording medium with the laser beam from the semiconductor laser, It is arranged between the objective lens and the semiconductor laser and separates a laser beam directed from the semiconductor laser toward the recording medium and a laser beam reflected by the recording medium and a part of the laser beam directed toward the recording medium from the semiconductor laser. A beam splitter for extracting the laser beam from the laser beam toward the recording medium,
A photodetector that outputs an electric signal corresponding to the intensity of the monitor laser beam extracted by this beam splitter, and a central axis, and between the photodetector and the beam splitter, a central axis and a perpendicular line to the center of the photodetector. And a lens device for condensing a part of the laser beam extracted from the laser beam directed to the recording medium by the beam splitter on the photodetector, and the lens device for the photodetector and the beam splitter. The optical head device is characterized in that it has a fixing means for fixing it at a predetermined position therebetween.

According to the present invention, a semiconductor laser for emitting a laser beam, an objective lens for irradiating a laser beam from the semiconductor laser onto a recording medium, and an objective lens arranged between the objective lens and the semiconductor laser are provided. While passing the laser beam from the semiconductor laser toward the recording medium, the laser beam reflected from the recording medium is reflected to separate the laser beam toward the recording medium from the laser beam reflected from the recording medium, and A beam splitter that splits the laser beam toward the recording medium by reflecting a part of the laser beam toward the recording medium, and receives the laser beam reflected by the beam splitter and outputs a monitor signal corresponding to the light intensity. Including the photo detector for the monitor and the central axis,
One of the laser beams extracted from the laser beam directed to the recording medium by the beam splitter is arranged between the monitor photodetector and the beam splitter so that the central axis and the perpendicular of the center of the monitor photodetector coincide with each other. A lens unit for condensing a portion of the monitor photodetector on the monitor photodetector, and curing by irradiating light having a predetermined wavelength, the lens device being fixed at a predetermined position between the photodetector and the beam splitter. The optical head device is characterized in that it has a fixing member for fixing the optical head device.

Further, according to the present invention, a semiconductor laser for emitting a laser beam, an objective lens for irradiating a laser beam from the semiconductor laser onto a recording medium, and an objective lens arranged between the objective lens and the semiconductor laser are provided. While passing the laser beam from the semiconductor laser toward the recording medium, the laser beam reflected from the recording medium is reflected to separate the laser beam toward the recording medium from the laser beam reflected from the recording medium, and A beam splitter that splits the laser beam toward the recording medium by reflecting a part of the laser beam toward the recording medium, and receives the laser beam reflected by the beam splitter and outputs a monitor signal corresponding to the light intensity. Includes a monitor photodetector and a central axis. Between the detector and the beam splitter, the central axis is aligned with the perpendicular of the center of the monitor photodetector, and is arranged in close contact with the emission surface of the beam splitter, the recording medium by the beam splitter. A lens device for condensing a part of the laser beam extracted from the traveling laser beam on the monitor photodetector, and a fixing member for fixing the lens device by being cured by being irradiated with ultraviolet rays. It is characterized by an optical head device.

Further, according to the present invention, a semiconductor laser for emitting a laser beam, an objective lens for irradiating a laser beam from the semiconductor laser onto a recording medium, and an objective lens arranged between the objective lens and the semiconductor laser are provided. While passing the laser beam directed from the semiconductor laser to the recording medium, the laser beam reflected on the recording medium is reflected to separate the laser beam directed to the recording medium and the laser beam reflected on the recording medium, and the semiconductor laser From the laser beam toward the recording medium by reflecting a part of the laser beam toward the recording medium from the beam splitter, and the laser beam reflected by this beam splitter is received and a monitor signal corresponding to the light intensity is output. Including a photo detector for a monitor, a central axis and a flat portion, The emission surface of the beam splitter through the surface portion, the central axis is aligned with the perpendicular of the center of the monitor photodetector, and is arranged in close contact, is taken out from the laser beam toward the recording medium by the beam splitter. And a plano-convex lens device for condensing a part of the laser beam on the monitor photodetector, and is arranged between the plane part of the plano-convex lens device and the emission surface of the beam splitter and cured by being irradiated with ultraviolet rays. Then, the optical head device is characterized in that it has an ultraviolet curable adhesive for fixing the lens device.

Furthermore, according to the present invention, a semiconductor laser for emitting a laser beam, an objective lens for irradiating a laser beam from the semiconductor laser onto a recording medium, and an objective lens arranged between the objective lens and the semiconductor laser are provided. While passing the laser beam directed from the semiconductor laser to the recording medium, the laser beam reflected on the recording medium is reflected to separate the laser beam directed to the recording medium and the laser beam reflected on the recording medium, and the semiconductor laser From the laser beam toward the recording medium by reflecting a part of the laser beam toward the recording medium from the beam splitter, and the laser beam reflected by this beam splitter is received and a monitor signal corresponding to the light intensity is output. And a photo detector for the monitor A lens device that is disposed between the beam splitter and the beam splitter and focuses a part of the laser beam extracted from the laser beam directed to the recording medium through the beam splitter on the monitor photodetector. In the head device, the lens device is placed in a direction orthogonal to the central axis so that the central axis of the lens device and the perpendicular of the center of the monitor photodetector are aligned with the flat surface of the lens device and the exit surface of the beam splitter in close contact with each other. The method of manufacturing an optical head device is characterized in that the lens device is moved and fixed by a fixing member.

Still further, according to the present invention, a semiconductor laser for emitting a laser beam, an objective lens for irradiating a laser beam from the semiconductor laser onto a recording medium, and an objective lens arranged between the objective lens and the semiconductor laser are provided. While passing the laser beam directed from the semiconductor laser to the recording medium, the laser beam reflected on the recording medium is reflected to separate the laser beam directed to the recording medium and the laser beam reflected on the recording medium, and the semiconductor laser From the laser beam toward the recording medium by reflecting a part of the laser beam toward the recording medium from the beam splitter, and the laser beam reflected by this beam splitter is received and a monitor signal corresponding to the light intensity is output. And a photo detector for the monitor A lens device that is disposed between the beam splitter and the beam splitter and focuses a part of the laser beam extracted from the laser beam directed to the recording medium through the beam splitter on the monitor photodetector. In the head device, the lens device is placed in a direction orthogonal to the central axis so that the central axis of the lens device and the perpendicular of the center of the monitor photodetector are aligned with the flat surface of the lens device and the exit surface of the beam splitter in close contact with each other. The method of manufacturing an optical head device is characterized in that the lens device is fixed by injecting a fixing member between the flat surface of the lens device and the emission surface of the beam splitter.

Furthermore, according to the present invention, a semiconductor laser for emitting a laser beam, an objective lens for irradiating a laser beam from the semiconductor laser onto a recording medium, and an objective lens arranged between the objective lens and the semiconductor laser are provided. While passing the laser beam directed from the semiconductor laser to the recording medium, the laser beam reflected on the recording medium is reflected to separate the laser beam directed to the recording medium and the laser beam reflected on the recording medium, and the semiconductor laser From the laser beam toward the recording medium by reflecting a part of the laser beam toward the recording medium from the beam splitter, and the laser beam reflected by this beam splitter is received and a monitor signal corresponding to the light intensity is output. And a photo detector for the monitor A lens device that is disposed between the beam splitter and the beam splitter and focuses a part of the laser beam extracted from the laser beam directed to the recording medium through the beam splitter on the monitor photodetector. In the head device, an ultraviolet curable adhesive is injected between the flat surface of the lens device and the exit surface of the beam splitter in a state where the flat surface of the lens device and the exit surface of the beam splitter are in close contact with each other. Is moved in a direction orthogonal to the central axis so that the vertical line at the center of the monitor photodetector and the center line of the monitor photodetector coincide with each other, and the ultraviolet curable adhesive is irradiated with ultraviolet rays of a predetermined wavelength to fix the lens apparatus. It is characterized by a method of manufacturing an optical head device.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below.
A detailed description will be given with reference to the drawings. As shown in FIG. 1, the optical head device 1 rotates a main body unit (fixed part) 2 and a main body unit 2 and the optical disk D that are arranged substantially parallel to a recording surface (not shown) of the optical disk D at a predetermined speed. And an actuator unit (movable part) 3 for irradiating a laser beam from the main body unit 2 toward a recording surface (not shown) of the optical disc D.

The actuator unit 3 has a carriage 4 for moving an objective lens, which will be described later, in a radial direction of the optical disc D, that is, along a recording surface and in a direction traversing a track formed on the optical disc.

The carriage 4 is formed so as to be movable in the radial direction of the optical disc D by a pair of radial drive coils 5 and a pair of guide rails 6, which are a part of a linear motor (not shown) formed integrally with the carriage 4. There is.

The main unit 2 has a housing 10 made of, for example, aluminum. A laser element (semiconductor laser) 11 that generates a laser beam having a predetermined wavelength is fixed to one end of the housing 10.

A collimator lens 12 for collimating the divergent laser beam L is arranged in the traveling direction of the laser beam L emitted from the semiconductor laser 11. In the direction in which the collimated laser beam L is guided through the collimator lens 12, the laser beam L is integrated with the ellipse correction prism 13 and the ellipse correction prism 13 for correcting the aspect ratio peculiar to the laser beam L, that is, the cross-sectional beam shape from an ellipse to a circle. The laser beam L having a substantially circular cross-sectional shape is transmitted toward the optical disc D, that is, the actuator unit 3, and the reflected laser beam L ′ reflected by a recording surface (not shown) of the optical disc D is transmitted to the optical disc D. A first beam splitter 14 that separates the traveling laser beam L is arranged.

In the direction in which the reflected laser beam L ′ separated from the laser beam L directed to the optical disk D is guided by the first beam splitter 14, the polarization direction of the polarization plane of the reflected laser beam L ′ is compensated for 1. / 2 wavelength plate 15
And a converging lens 1 which gives the reflected laser beam that has passed through the half-wave plate 15 a predetermined image forming characteristic and converging property.
6 are arranged.

In the direction in which the reflected laser beam L'passed through the converging lens 16 travels, the reflected laser beam L'passed through the converging lens 16 and given a predetermined image forming characteristic.
A second beam splitter 17 that divides the beam into two is arranged.

In the direction in which the two reflected laser beams L ′ split by the second beam splitter 17 are guided, the respective reflected laser beams L ′ are photoelectrically converted,
First and second photodetectors 18 and 19 that generate an electric signal corresponding to the light intensity of the laser beam L ′ are arranged. Each of the first and second photodetectors 18 and 19 is fixed to holders 18a and 19a holding the corresponding photodetectors by a fixing member such as an adhesive or a screw (not shown). The holders 18a and 19a of the first and second photodetectors 18 and 19 are fixed to the housing 10 by positioning the holders 18a and 19a at predetermined positions of the housing 10 via a fixing member such as an adhesive or a screw (not shown). It

A dustproof filter 20 for dustproofing the main unit 2 is arranged between the first beam splitter 14 and the actuator unit 3. In the direction in which a part of the laser beam L directed to the optical disc D is reflected by the first beam splitter 14, the fluctuation of the light intensity of the laser beam L from the semiconductor laser 11 is checked and is supplied to a laser drive circuit (not shown). Automatic output control (not shown) to instruct correction of the laser drive current
(Power Control, APC) mechanism is provided with an APC monitor photodetector 21 that detects the laser beam L ″ reflected by the first beam splitter 14 and generates an electric signal corresponding to the light intensity of the laser beam L ″. Has been done. The APC monitor photo detector 21 is fixed to the holder 21a by a fixing member such as an adhesive or a screw (not shown). The APC monitor photodetector 21 is fixed to the housing 10 in a state where the holder 21a is positioned at a predetermined position of the housing 10 by a fixing member such as an adhesive or a screw (not shown).

The laser beam L ″ is APC monitored on a predetermined position between the first beam splitter 14 and the APC monitor photodetector 21, for example, on the surface of the first beam splitter 14 where the laser beam L ″ is emitted. An image forming lens (image forming lens for APC monitor) 22 for forming an image at the light receiving center of the detection surface of the photo detector 21 is fixed by a fixing member 23. The imaging lens 22 is, for example,
Optical glass such as BK7 or polycarbonate (P
A plano-convex lens in which a surface in contact with the first beam splitter 14 is formed of a flat surface by a plastic such as C), acrylic (PMMA), or amorphous polyolefin (a-PO) is used.

The carriage 4 of the actuator unit 3 is used to make a laser beam L, which has passed through the first beam splitter 14 of the main body unit 2 and travels substantially parallel to the recording surface of the optical disc D, incident on an objective lens described later. A rising mirror 41 that bends is arranged.

The direction in which the laser beam L guided by the rising mirror 41 and reflected by the rising mirror 41 is directed, that is, between the rising mirror 41 and the optical disk D, has a predetermined depth of the recording surface of the optical disk D, that is, The laser beam L reflected by the rising mirror 41 is imaged on a recording layer (not shown), and the reflected light beam L ′ reflected by the recording layer of the optical disc D is reflected by the first and second photodetectors 18 of the main unit 2. An objective lens 42 is disposed so as to stably enter the light sources 19 and 19.

The objective lens 42 is held by a lens holder 43 which holds the objective lens 42, and a spring 45 passed between a lens holder 43 and a support member 44 fixed at a predetermined position of the carriage 4 causes the lens holder 43 to be held. Is supported so as to be movable in the direction orthogonal to the recording surface of the optical disc D, so that it is movably held in the direction orthogonal to the recording surface of the optical disc D.

The lens holder 43 is placed on the optical disc D at a position around the lens holder 43, where the laser beam L guided to the rising mirror 41 and the reflected laser beam L'returned to the rising mirror 41 are not blocked. Of the driving coil 46 for moving in the direction orthogonal to the recording surface of the recording medium and the fixed magnet 47 for converting the force generated by supplying the current to the driving coil 46 into the propulsive force for moving the objective lens 42. Has been done.

Next, the flow of the laser beam in the optical head device 1 will be described. The laser beam L emitted from the semiconductor laser 11 is converted into a parallel light flux by the collimator lens 12 and transmitted through the first beam splitter 14. The laser beam L ″ reflected by the first beam splitter 14 is guided to the APC monitor photodetector 21 after being given a predetermined converging property by the imaging lens 22.

The laser beam emitted from the main unit 2 after passing through the first beam splitter 14 and the dustproof filter 20 has an optical path of 90 ° by the rising mirror 41.
It is changed and enters the objective lens 42. At this time, it goes without saying that the intensity center of the laser beam L and the center of the objective lens 42 are substantially coincident with each other.

The laser beam L incident on the objective lens 42 is guided to a recording surface (not shown) of the optical disc D by the objective lens 42, and has a beam spot size of a predetermined size, a predetermined depth of the recording surface, that is, a recording layer. Is focused on.

The reflected laser beam L'reflected by the recording layer of the optical disc D and whose light intensity is changed based on the data (presence or absence of pits) recorded in the recording layer is returned to parallel light by the objective lens 42. The light is reflected by the rising mirror 41, passed through the dustproof filter 20, and returned to the first beam splitter 14.

The reflected laser beam L ′ returned to the first beam splitter 14 is then reflected by the first beam splitter 14, passes through the half-wave plate 15 and the converging lens 16, and is then reflected by the second beam splitter 14. It is divided into two by the beam splitter 17.

The reflected laser beam L ′ split by the second beam splitter 17 is provided between the optical disc D and the objective lens 42 on the light receiving portions of the detection surfaces of the first and second photodetectors 18 and 19, respectively. Distance and guide groove (groove) formed in advance on the optical disc D
An image is formed with a cross-sectional beam spot diameter and a predetermined amount of light corresponding to a shift between the center of the object and the center of the objective lens 42.

The reflected laser beam L'light imaged on the light receiving portions of the detection surfaces of the first and second photodetectors 18 and 19 is the photodetectors 18 and 1.
It is photoelectrically converted by 9 and is output as a DC voltage that can be used as a data reproduction signal, a focus error signal and a tracking error signal.

The laser beam L ″ guided to the APC monitor photodetector 21 is photoelectrically converted by the APC monitor photodetector 21, and a correction amount for stabilizing the light intensity of the output laser beam L from the semiconductor laser 11 is determined. Used.

By the way, in many cases, when the main unit 2 is assembled, the AP attached to the housing 10 is used.
C monitor photo detector 21 or semiconductor laser 1
It is known that a mounting error occurs between 1 and the housing 10. As the mounting error, for example, the APC monitor photodetector 2 with respect to the housing 10
There is a position shift of 1 or a position shift of the semiconductor laser 11 with respect to the housing 10.

APC monitor photodetector 2 described above
The positional deviation of 1 and the positional deviation of the semiconductor laser 11 are
Light receiving center 2 on the detection surface of the PC monitor photo detector 21
1b and the center of the beam spot of the laser beam L ″ are displaced. In this case, as described above, the AP
The band of the C monitor photodetector 21 is lowered and the response speed becomes slower. In addition, by changing the position where the APC monitor photodetector 21 is fixed, the AP is centered on the beam spot of the laser beam L ″.
Light receiving center 21 on the detection surface of the C monitor photo detector 21
A method of matching b is already known, but also by this method, when the APC monitor photodetector 21 is fixed to the housing 10 of the main unit 2, the housing 21a of the APC monitor photodetector and the detection surface of the APC monitor photodetector receive light. There is a problem that the center 21b is misaligned. Although the first beam splitter 14 is also fixed to the housing 10, since the optical axis of the first beam splitter 14 and the objective lens 42 of the actuator unit 3 are aligned and fixed, The positional deviation between the semiconductor laser 11 and the APC monitor photodetector 21 and the housing 10 is substantially eliminated by correcting the positional deviation between the first beam splitter 14 and each of them. Further, the positional deviation of the semiconductor laser 11 with respect to the housing 10 can be regarded as the deviation of the luminous flux center of the laser beam incident on the first beam splitter 14 with respect to the optical axis connecting the first beam splitter 14 and the objective lens 42. .

A method for aligning the light receiving center of the detection surface of the APC monitor photodetector with the light beam center of the laser beam L ″ that is separated from the laser beam L directed to the objective lens by the first beam splitter will be described in detail below. .

FIG. 2 shows the center of the laser beam L ″ separated by the first beam splitter 14 and A for the sake of explanation.
The figure shows a state in which the positional deviation between the detection surface of the PC monitor photodetector 21 and the light receiving center is within the allowable range.
That is, the center of the first beam splitter 14 is aligned with the design optical axis O ₁ passing through the center of the objective lens 42, and the light receiving center of the detection surface of the APC monitor photodetector 21 is the center of the first beam splitter 14 and the design light is received. Axis O ₁
When it coincides with the second design optical axis O ₂ orthogonal to the first optical axis O 2 as shown in FIG.
The laser beam L ″ separated by 4 passes through the imaging lens 22 and the cross-sectional beam shape is converged to a predetermined size.
Light receiving center 21b on the detection surface of the PC monitor photo detector
Is imaged.

FIGS. 3 and 4 are schematic diagrams showing a method of preventing the delay of the response speed of the APC monitor photodetector 21 due to the positional displacement of the semiconductor laser 11 with respect to the housing 10. The positional deviation of the semiconductor laser 11 with respect to the housing 10 is caused by the first beam splitter 14 with respect to the design optical axis O ₁ passing through the center of the objective lens 42.
It can be regarded as the center of the luminous flux of the laser beam incident on.

Hereinafter, the deviation in the direction parallel to the recording surface of the optical disk D and orthogonal to the radial direction of the optical disk D is x, and the deviation along the direction orthogonal to the recording surface of the optical disk D in the direction orthogonal to the x direction is y. And z is a direction orthogonal to each of the x direction and the y direction, that is, a direction parallel to the recording surface of the optical disc D and orthogonal to the radial direction of the optical disc D. Further, the respective deviations are caused by the design optical axis O ₁
Since it occurs in both the positive direction and the negative direction, which is the positive direction and the reverse direction with respect to O ₂ as the center, the deviation in the positive direction is as follows.
(+) Is added, and the following (-) is added to the deviation in the negative direction.

FIG. 3A shows the semiconductor laser 11 to the first
In this example, the laser beam L incident on the beam splitter 14 is shifted in the x (−) direction with respect to the design optical axis O ₁ of the objective lens 42 passing through the first beam splitter 14. Further, FIG. 3B shows an example in which the laser beam L is displaced in the x (+) direction with respect to the design optical axis O ₁ of the objective lens 42 passing through the first beam splitter 14. There is.

FIG. 4A shows the semiconductor laser 11 to the first
In this example, the laser beam L incident on the beam splitter 14 is shifted in the y (−) direction with respect to the design optical axis O ₁ of the objective lens 42 that passes through the first beam splitter 14. Further, FIG. 4B shows an example in which the laser beam L is displaced in the y (+) direction with respect to the design optical axis O ₁ of the objective lens 42 passing through the first beam splitter 14. .

As shown in FIGS. 3 (a), 3 (b), 4 (a) and 4 (b), the objective lens 4
In the state where the center of the first beam splitter 14 is aligned with the design optical axis O ₁ extending from the center of the first beam splitter 2, the light beam center of the laser beam L entering the first beam splitter 14 and the first If there is a deviation from the center of the beam splitter 14, the output current output from the APC monitor photodetector 21 is monitored by a monitor device (not shown) such as an ammeter, and the imaging lens 22 is moved so as to maximize the output current. By doing so, the position of the imaging lens 22 is accurately defined. As a result, even when the light beam center of the laser beam L incident on the first beam splitter 14 is displaced in any direction with respect to the design optical axis O ₁ of the objective lens 42 passing through the first beam splitter 14. , APC
The light beam center of the laser beam L ″ separated by the first beam splitter 14 can be made incident on the light receiving center 21b of the detection surface of the monitor photodetector. As is well known, when a parallel light beam is incident on a convex lens, all light rays incident at different distances (image height) from the optical axis peculiar to the lens are at the same position, that is, the focal point of the lens. The first beam splitter 14 utilizes the fact that it is converged (ignoring the spherical aberration of the lens).
Even if the luminous flux center of the laser beam L incident on the first beam splitter _{1 is} displaced with respect to the design optical axis O ₁ of the objective lens 42 passing through the first beam splitter 14.
This is applicable when the beam diameter of the laser beam L ″ separated by 4 is within the pupil diameter (not shown) of the imaging lens 22.
At the position where the output current output from the APC monitor photodetector 21 is maximum, optically, the optical axis O ₂₂ specific to the imaging lens 22 and the light receiving center 21b of the detection surface of the APC monitor photodetector are in the same straight line. It goes without saying that the position is aligned on the line, that is, on the design optical axis O ₂ .

In this way, the imaging lens 22 moved so that the light beam center of the laser beam L ″ can be converged on the light receiving center 21b of the detection surface of the APC monitor photodetector is the first beam splitter 14 and the image forming lens. An ultraviolet-curable adhesive 23 as a fixing member is applied to the surface to be joined with 22 and is irradiated with ultraviolet rays of a predetermined wavelength by an ultraviolet lamp (not shown) to firmly fix the adhesive in a short time. As the ultraviolet curable adhesive, preferably,
Loctite, trade name, LI-298, etc. are used.

According to this method, when the semiconductor laser 11 is fixed to the housing 10 of the main body unit 2, the semiconductor laser 11 is displaced, so that the light receiving center 21b on the detection surface of the APC monitor photodetector and the first beam splitter. The problem that the luminous flux centers of the laser beam L ″ separated by 14 do not coincide is solved, and the adjustment time required when assembling the optical head device 1 is shortened.
Therefore, the assembly cost is reduced.

FIGS. 5 and 6 are schematic diagrams showing a method of preventing a delay in the response speed of the APC monitor photodetector 21 due to the displacement of the APC monitor photodetector 21 with respect to the housing 10.

Hereinafter, the deviation in the direction parallel to the recording surface of the optical disk D and orthogonal to the radial direction of the optical disk D is x, and the deviation along the direction orthogonal to the recording surface of the optical disk D in the direction orthogonal to the x direction is y. And z is a direction orthogonal to each of the x direction and the y direction, that is, a direction parallel to the recording surface of the optical disc D and orthogonal to the radial direction of the optical disc D,
Shall be shown. Further, since the respective deviations occur both in the positive direction and the negative direction opposite to the positive direction with respect to the optical axis, the following (+) is added to the deviation in the positive direction,
The following (-) shall be added to the deviation in the negative direction.

In FIG. 5A, the light receiving center 21b of the detection surface of the APC monitor photodetector is the second optical axis O ₁ passing through the first beam splitter 14 and the second optical axis O ₁ which is orthogonal to the center of the first beam splitter 14. X with respect to the design optical axis O ₂
An example is shown in which it is shifted in the (-) direction.

In the example shown in FIG. 5A, the imaging lens 2
The center of 2 or the optical axis O ₂₂ peculiar to the imaging lens ₂₂ is A
Light receiving center 21b on the detection surface of the PC monitor photo detector
By moving the imaging lens 22 in the z (-) direction so as to be located on the extension line of the APC monitor, the center of the beam spot of the laser beam L ″ given a predetermined convergence by the imaging lens 22 is measured by the APC monitor. It can be made to coincide with the light receiving center 21b on the detection surface of the photodetector.

In FIG. 5B, the light receiving center 21b of the detection surface of the APC monitor photodetector is the second optical axis O ₁ passing through the first beam splitter 14 and the second optical axis O ₁ which is orthogonal to the center of the first beam splitter 14. X with respect to the design optical axis O ₂
An example is shown in which it is shifted in the (+) direction.

In the example shown in FIG. 5B, the imaging lens 2
The center of 2 or the optical axis O ₂₂ peculiar to the imaging lens ₂₂ is A
Light receiving center 21b on the detection surface of the PC monitor photo detector
By moving the image forming lens 22 in the z (+) direction so as to be positioned on the extension line of the APC monitor, the center of the beam spot of the laser beam L ″ given a predetermined convergence by the image forming lens 22 is measured. It can be made to coincide with the light receiving center 21b on the detection surface of the photodetector.

As is apparent from FIG. 5, the imaging lens 22
Center and the APC the imaging lens 22 so that the shift amount is reduced between the light receiving center 21b of the detection surface of the monitor photodetector in a direction perpendicular to the optical axis O _2, the optical axis O ₂₂ is APC monitor of the imaging lens 22 of the By moving so as to be located on the extension line of the light receiving center 21b on the detection surface of the photodetector, it is possible to reduce the influence of the deviation that occurs when the APC monitor photodetector 21 is fixed. When the imaging lens 22 is moved, as described above, the output of the APC monitor photodetector 21 is monitored by a monitor device (not shown) such as an ammeter, and the imaging lens 22 is placed at a position where the output current is maximum. Just fix it.

The image forming lens 22 is an ultraviolet curing adhesive as a fixing member on the surface where the first beam splitter 14 and the image forming lens 22 are joined in a state of moving in parallel to the first beam splitter 14. The agent 23 is applied and is irradiated with ultraviolet rays of a predetermined wavelength through an ultraviolet lamp (not shown), so that the agent 23 is reliably fixed in a short time.

According to this method, when the APC monitor photodetector 21 is fixed to the housing 10 of the main unit 2, the housing 2 of the APC monitor photodetector is used.
Even if 1a and the light receiving center 21b of the detection surface of the APC monitor photodetector are deviated, the adjustment time required when assembling the optical head device 1 is shortened. Therefore, the assembly cost is reduced.

In FIG. 6A, the light receiving center 21b on the detection surface of the APC monitor photodetector is a second optical axis O ₁ passing through the first beam splitter 14 and orthogonal to the design optical axis O ₁ at the center of the first beam splitter 14. Y with respect to the design optical axis O ₂
An example is shown in which it is shifted in the (-) direction.

In the example shown in FIG. 6A, the imaging lens 2
By moving the imaging lens 22 in the y (+) direction so that the optical axis O _{22 of} 2 is located on the extension line of the light receiving center 21b of the detection surface of the APC monitor photodetector, a predetermined convergence is achieved via the imaging lens 22. It is possible to make the center of the beam spot of the laser beam L ″ given the property coincide with the light receiving center 21b of the detection surface of the APC monitor photodetector.

In FIG. 6B, the light receiving center 21b of the detection surface of the APC monitor photodetector is a second optical axis O ₁ passing through the first beam splitter 14 and orthogonal to the design optical axis O ₁ at the center of the first beam splitter 14. Y with respect to the design optical axis O ₂
An example is shown in which it is shifted in the (+) direction.

In the example shown in FIG. 6B, the imaging lens 2
By moving the imaging lens 22 in the y (-) direction so that the optical axis O _{22 of} 2 is located on the extension line of the light receiving center 21b of the detection surface of the APC monitor photodetector, a predetermined convergence is achieved via the imaging lens 22. It is possible to make the center of the beam spot of the laser beam L ″ given the property coincide with the light receiving center 21b of the detection surface of the APC monitor photodetector.

As is clear from FIG. 6, the imaging lens 22
Center and the APC the imaging lens 22 so that the shift amount is reduced between the light receiving center 21b of the detection surface of the monitor photodetector in a direction perpendicular to the optical axis O _2, the optical axis O ₂₂ is APC monitor of the imaging lens 22 of the By moving so as to be located on the extension line of the light receiving center 21b on the detection surface of the photodetector, it is possible to reduce the influence of the deviation that occurs when the APC monitor photodetector 21 is fixed. Needless to say, when moving the imaging lens 22, it is sufficient to check the position where the output of the APC monitor photodetector 21 is maximum, as described above.

FIG. 7 is a schematic view showing an example of another optical head device different from the optical head device shown in FIG. The same components as those of the optical head device shown in FIG. 1 are designated by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 7, the optical head device 10
Reference numeral 1 denotes a reflected laser beam returned from the movable part 3 while supplying a laser beam to a movable part 3 which holds an objective lens 42 facing an unillustrated recording surface of an optical disk so as to be movable along the recording surface. It has a fixed part 102 for taking out the data recorded on the optical disc.

The fixed portion 102 has a housing 110. At a predetermined position of the housing 110, the semiconductor laser 11, the collimator lens 12, the ellipse correction prism 1 are provided.
3, the first beam splitter 14, the half-wave plate 15,
The second beam splitter 17, the first and second photodetectors 18 and 19, the dustproof filter 20, and
The APC monitor photodetector 21 is arranged similarly to the example shown in FIG.

Between the position where the first beam splitter 14 is arranged in the housing 110 and the position where the APC monitor photodetector 21 is arranged, the first beam splitter 14 reflects the light toward the APC photodetector 21. APC monitor laser beam L ''
A lens holding portion 111 that holds an imaging lens 22 that forms an image at the light receiving center of the detection surface of the monitor photodetector 21 is formed.

The imaging lens 22 is fixed to the light receiving center of the detection surface of the APC monitor photodetector 21 in the same manner as the optical head device 1 shown in FIG. The position of the imaging lens 22 is slightly adjusted so that the optical axis of the imaging lens 22 is located on the same straight line, and the imaging lens 22 is fixed to the lens holding portion 111.

[0069]

As described above, according to the present invention,
With one surface of the imaging lens as a flat surface, the imaging lens is brought into close contact with the exit surface of the beam splitter, and the optical axis of the imaging lens is accurately aligned with the light receiving center of the detection surface of the APC monitor photodetector. The laser beam is AP
It is focused on the light receiving center of the C monitor photo detector.

At this time, the imaging lens is moved in a direction parallel to the emission surface of the beam splitter so that the output of the APC monitor photodetector is maximized, and then fixed by an ultraviolet curable adhesive.

This prevents the output of the APC monitor photodetector from falling in the high frequency band. Therefore, the intensity of the laser beam emitted from the semiconductor laser is stabilized, and errors in reproducing the data stored in the optical disc are reduced.

Further, the cost is reduced by preventing the yield of the optical head device from being lowered due to the position of the APC monitor photodetector being undesirably shifted and fixed.

[Brief description of drawings]

FIG. 1 is a schematic plan view showing an optical head device of the present invention.

2A and 2B are schematic diagrams illustrating the APC monitor photodetector of the optical head device shown in FIG. 1 and a positional deviation of a laser beam guided by the APC monitor photodetector.

FIG. 3 is a schematic view showing a state in which the semiconductor laser is displaced and fixed with respect to the beam splitter in the optical head device shown in FIG.

FIG. 4 is a schematic view showing a state in which the semiconductor laser is displaced and fixed to the beam splitter in the optical head device shown in FIG.

FIG. 5 is a schematic view showing a state where the APC monitor photodetector is displaced and fixed with respect to the semiconductor laser in the optical head device shown in FIG.

FIG. 6 is a schematic view showing a state where an APC monitor photodetector is displaced and fixed to a semiconductor laser in the optical head device shown in FIG.

FIG. 7 is a schematic view showing an example of another head device different from the optical head device shown in FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Optical head device, 2 ... Main body unit, 3 ... Actuator unit, 4 ... Carriage, 5 ... Radial drive coil, 6 ... Guide rail, 10 ... Housing, 11 ... Semiconductor laser, 12 ... Collimator lens, 13 ... Elliptic correction prism , 14 ... First beam splitter, 15 ... 1/2 wavelength plate, 16 ... Converging lens, 17 ... Second beam splitter, 18 ... Photodetector, 19 ... Photodetector, 20 ... Dust filter, 21 ... APC monitor photodetector, 22. ... Imaging lens (imaging lens for APC monitor), 23 ... Fixing member, 41 ... Stand-up mirror, 42 ... Objective lens, 43 ... Lens holder, 44 ... Supporting member, 45 ... Spring, 46 ... Drive coil 47 ... Fixed magnet.

Claims (7)

[Claims] 1. A semiconductor laser that emits a laser beam, an objective lens that irradiates a laser beam from the semiconductor laser onto a recording medium, and an objective lens that is arranged between the objective lens and the semiconductor laser.
A beam splitter that separates the laser beam from the semiconductor laser toward the recording medium and the laser beam reflected by the recording medium, and extracts a part of the laser beam from the semiconductor laser toward the recording medium from the laser beam toward the recording medium; A photodetector that outputs an electric signal corresponding to the intensity of the monitor laser beam extracted by the beam splitter, and a central axis, and between the photodetector and the beam splitter, the central axis and a perpendicular line to the center of the photodetector are A lens device which is arranged so as to match and focuses a part of the laser beam extracted from the laser beam directed to the recording medium by the beam splitter on the photodetector, and the lens device of the photodetector and the beam splitter device. And fixing means for fixing the predetermined position,
An optical head device comprising: 2. A semiconductor laser that emits a laser beam, an objective lens that irradiates a recording medium with the laser beam from the semiconductor laser, and a semiconductor laser disposed between the objective lens and the semiconductor laser.
While passing the laser beam directed from the semiconductor laser to the recording medium, the laser beam reflected on the recording medium is reflected to separate the laser beam directed to the recording medium and the laser beam reflected on the recording medium, and the semiconductor laser From the laser beam toward the recording medium by reflecting a part of the laser beam toward the recording medium from the beam splitter, and the laser beam reflected by this beam splitter is received and a monitor signal corresponding to the light intensity is output. A monitor photodetector that includes a central axis, and is disposed between the monitor photodetector and the beam splitter so that the central axis and a perpendicular line of the center of the monitor photodetector are aligned with each other, and the beam splitter allows a recording medium to be recorded. Taken out of the laser beam A lens device for condensing a part of the laser beam on the monitor photodetector, and curing by irradiating light having a predetermined wavelength. The lens device is provided with the photodetector and the lens device. A fixing member that is fixed at a predetermined position between
An optical head device comprising: 3. A semiconductor laser that emits a laser beam, an objective lens that irradiates a laser beam from this semiconductor laser onto a recording medium, and a semiconductor laser disposed between the objective lens and the semiconductor laser.
While passing the laser beam directed from the semiconductor laser to the recording medium, the laser beam reflected on the recording medium is reflected to separate the laser beam directed to the recording medium and the laser beam reflected on the recording medium, and the semiconductor laser From the laser beam toward the recording medium by reflecting a part of the laser beam toward the recording medium from the beam splitter, and the laser beam reflected by this beam splitter is received and a monitor signal corresponding to the light intensity is output. And a monitor photodetector, which includes a central axis, between the monitor photodetector and the beam splitter, so that the central axis coincides with the perpendicular of the center of the monitor photodetector, and on the exit surface of the beam splitter. The beam splitters that are placed in close contact A lens device that focuses a part of the laser beam extracted from the laser beam toward the recording medium on the monitor photodetector, and a fixing member that fixes the lens device by being cured by being irradiated with ultraviolet rays. An optical head device comprising: 4. A semiconductor laser that emits a laser beam, an objective lens that irradiates the recording medium with the laser beam from the semiconductor laser, and is arranged between the objective lens and the semiconductor laser.
While passing the laser beam directed from the semiconductor laser to the recording medium, the laser beam reflected on the recording medium is reflected to separate the laser beam directed to the recording medium and the laser beam reflected on the recording medium, and the semiconductor laser From the laser beam toward the recording medium by reflecting a part of the laser beam toward the recording medium from the beam splitter, and the laser beam reflected by this beam splitter is received and a monitor signal corresponding to the light intensity is output. And a monitor photodetector that includes a central axis and a flat surface portion, and the output surface of the beam splitter through the flat surface portion is in close contact with the central axis and the perpendicular line of the center of the monitor photodetector. A laser beam that is arranged and is directed to the recording medium by the beam splitter. A plano-convex lens device for condensing a part of the laser beam extracted from the photo-detector for monitoring, and a plano-convex lens device arranged between the plane part and the emission surface of the beam splitter, and irradiated with ultraviolet rays. And an ultraviolet curable adhesive that cures to fix the lens device. 5. A semiconductor laser which emits a laser beam,
An objective lens for irradiating a recording medium with a laser beam from the semiconductor laser, and an objective lens arranged between the objective lens and the semiconductor laser for allowing a laser beam traveling from the semiconductor laser to the recording medium to pass while reflecting on the recording medium. The reflected laser beam is reflected to separate the laser beam directed to the recording medium and the laser beam reflected on the recording medium, and a part of the laser beam directed from the semiconductor laser to the recording medium is reflected to the recording medium. A beam splitter that splits the laser beam, a monitor photodetector that receives the laser beam reflected by the beam splitter, and outputs a monitor signal corresponding to the light intensity, and is arranged between the monitor photodetector and the beam splitter. Is recorded via the beam splitter. In an optical head device having a lens device for condensing a part of a laser beam extracted from a laser beam directed to a medium on the monitor photodetector, a flat part of the lens device and an emission surface of the beam splitter are closely contacted with each other. In this state, the lens device is moved in a direction orthogonal to the central axis so that the central axis of the lens device coincides with the perpendicular of the center of the photodetector for monitoring, and the lens device is fixed by a fixing member. Device manufacturing method. 6. A semiconductor laser for emitting a laser beam,
An objective lens for irradiating a recording medium with a laser beam from the semiconductor laser, and an objective lens arranged between the objective lens and the semiconductor laser for allowing a laser beam traveling from the semiconductor laser to the recording medium to pass while reflecting on the recording medium. The reflected laser beam is reflected to separate the laser beam directed to the recording medium and the laser beam reflected on the recording medium, and a part of the laser beam directed from the semiconductor laser to the recording medium is reflected to the recording medium. A beam splitter that splits the laser beam, a monitor photodetector that receives the laser beam reflected by the beam splitter, and outputs a monitor signal corresponding to the light intensity, and is arranged between the monitor photodetector and the beam splitter. Is recorded via the beam splitter. In an optical head device having a lens device for condensing a part of a laser beam extracted from a laser beam directed to a medium on the monitor photodetector, a flat part of the lens device and an emission surface of the beam splitter are closely contacted with each other. In this state, move the lens device in the direction perpendicular to the center axis so that the center axis of the lens device and the perpendicular of the center of the photodetector for monitoring coincide with each other, and fix it between the flat surface of the lens device and the exit surface of the beam splitter. Inject the material,
A method of manufacturing an optical head device, comprising fixing a lens device. 7. A semiconductor laser which emits a laser beam,
An objective lens for irradiating a recording medium with a laser beam from the semiconductor laser, and an objective lens arranged between the objective lens and the semiconductor laser for allowing a laser beam traveling from the semiconductor laser to the recording medium to pass while reflecting on the recording medium. The reflected laser beam is reflected to separate the laser beam directed to the recording medium and the laser beam reflected on the recording medium, and a part of the laser beam directed from the semiconductor laser to the recording medium is reflected to the recording medium. A beam splitter that splits the laser beam, a monitor photodetector that receives the laser beam reflected by the beam splitter, and outputs a monitor signal corresponding to the light intensity, and is arranged between the monitor photodetector and the beam splitter. Is recorded via the beam splitter. In an optical head device having a lens device for condensing a part of a laser beam extracted from a laser beam directed to a medium on the monitor photodetector, a flat part of the lens device and an emission surface of the beam splitter are closely contacted with each other. In this state, inject UV-curable adhesive between the flat surface of the lens device and the exit surface of the beam splitter, and align the lens device with the center axis so that the center axis of the lens device and the perpendicular of the center of the photodetector for monitoring are aligned. A method of manufacturing an optical head device, comprising moving in a direction orthogonal to each other and irradiating an ultraviolet ray curable adhesive with ultraviolet rays of a predetermined wavelength to fix the lens device.