KR950014829B1 - Optical pick up apparatus - Google Patents

Abstract

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Description

Optical pickup

1 to 4 show a first embodiment of the optical pickup apparatus of the present invention.

1 is a plan view.

2 is a cross-sectional view taken along the line II-II of FIG.

3 is an enlarged perspective view.

4 is an enlarged exploded perspective view.

5 to 8 show a second embodiment of the optical pickup apparatus of the present invention.

5 is a plan view.

6 is a cross-sectional view along the VI-VI line of FIG.

7 is an enlarged perspective view.

8 is an enlarged perspective view showing the main parts in an exploded view.

9 to 12 show a third embodiment of the optical pickup apparatus of the present invention.

9 is a plan view.

FIG. 10 is a cross-sectional view taken along the line VII-VII of FIG. 9. FIG.

11 is an enlarged perspective view.

12 is an enlarged perspective view showing an exploded view of the main portion.

Fig. 13 is a schematic perspective view of the main portion showing an embodiment of a conventional optical pickup device.

14 is a schematic plan view of a main portion showing another embodiment of the conventional optical pickup device.

* Explanation of symbols for main parts of the drawings

1: optical pickup device 1A: optical pickup device

1B: Optical pickup device 2: Base substrate

13: parallel link 15: hinge

15a: hinge member 15b: hinge member

19: movable body 23: objective lens

33: parallel link 37: movable body

39: parallel link

[Industrial use]

The present invention relates to an optical pickup device. The present invention provides an optical pickup apparatus for reading out the signal by irradiating beam light to the recording surface of the optical disk or by reading the beam light on the recording surface of the recording body and detecting the returning light. An optical pick-up apparatus, comprising: an objective lens for condensing on a recording surface of the optical pickup device movably in an optical axis direction, i.e., a focusing direction and a direction orthogonal to the focusing direction, i.e., a tracking direction. The present invention seeks to provide a new optical pickup device in which the objective lens does not easily cause tracking misalignment even when an impact or acceleration in the tracking direction is applied.

[Overview of invention]

The present invention provides an optical pickup apparatus in which an objective lens for condensing beam light on a recording surface of an optical disc is movably provided in a focusing direction that is the light side direction and a tracking direction that is orthogonal to the focusing direction. By installing at an almost center position of the movable member for supporting the rotational central objective lens in the direction, it is characterized in that the position or posture of the objective lens in the tracking direction is not easily shifted even when an impact or the like is applied to the apparatus.

[Prior art]

[General background]

Recording using an optical disc is performed by modulating a signal to be recorded into a digital signal by a combination of 0's and 1's, and simultaneously forming a pit corresponding to the digital signal on the recording surface of the optical disc. Spiral "is formed while drawing one continuous track.

The reproduction of the recorded signal as described above is performed by irradiating the beam light oscillated by a laser oscillator such as a semiconductor laser onto the recording track of the optical disc and detecting the returning light to detect the presence or absence of pits.

Therefore, in a so-called laser disc player or the like which reproduces music or video recorded on an optical disc, an optical pickup device having an objective lens for condensing beam light on the recording surface of the optical disc is provided. The objective lens is configured to move as the optical axis follows the recording track.

In addition, in order to detect the signal recorded on the optical disk with good accuracy, the beam light needs to be focused as a spot having a predetermined diameter on the recording surface, and in order to do this, the distance between the objective lens and the recording surface of the optical disk is always kept constant. Need to be. The precision in supporting this distance constantly should be at least as high as the depth of the pit, i. However, it is very difficult to process the recording surface of the optical disc with such precision, and furthermore, the distance is remarkably changed depending on the precision of the spindle mechanism on which the optical disc is mounted.

Therefore, in this kind of optical pickup apparatus, the objective lens is configured to be movable in the optical axis direction so that the distance between the objective lens and the recording surface of the optical disc can be adjusted when it is out of a predetermined value. .

As described above, in the optical pickup device, the objective lens is provided so as to be movable in a tracking direction that is orthogonal to the focusing direction that is the optical axis direction and the focusing direction.

[First Embodiment of Conventional Optical Pickup Device (Fig. 13)]

FIG. 13 schematically shows an embodiment (a) of the conventional optical pickup apparatus provided such that the objective lens is movable in the focusing direction and the tracking direction.

In FIG. 13, b denotes a lens support member, and an objective lens c is fixed to the lens support member b. d is a sliding member slidably supported in a direction along the optical axis direction of the objective lens c by a supporting member (not shown), and the lens support member b of the sliding member d is a direction perpendicular to the optical axis direction. It consists of a leaf spring material or the like which can be bent and connected by two parallel arms e extending parallel to each other.

Therefore, the objective lens c is supported in a state movable in a focusing direction and a tracking direction orthogonal to the focusing direction.

Second Embodiment of Conventional Optical Pickup Device

14 is a view schematically showing another embodiment (f) of the conventional optical pickup device.

In Fig. 14, g is a lens support member formed in a distance circumferential shape, and the lens support member g is connected to the support shaft i by inserting the support shaft i into the insertion hole h formed at the center thereof. It is supported by the state which can be moved to an axial direction, and is rotatable. Reference numeral j denotes an objective lens fixed to the lens support member g, and the objective lens j is provided in a direction in which the optical axis thereof extends along the axial direction of the lens support member g. Reference numeral k denotes a balance weight provided at a portion located on the opposite side with the support shaft i fitted to the lens support member g.

Therefore, the objective lens j is supported in a state movable in the focusing direction and the tracking direction orthogonal to the focusing direction.

[Problems to Solve Invention]

In the conventional optical pickup apparatus, the objective lenses c and j are provided to be movable in the focusing direction and the tracking direction as described above, but if the objective lenses c and j are supported by such a support mechanism, the optical When the pick-up devices a and f are subjected to an impact or acceleration from the outside, in particular an impact or acceleration in the tracking direction, there is a problem that tracking misalignment is likely to occur.

That is, in the optical pickup device a shown in Fig. 13, the lens support member b for supporting the objective lens c is supported by the swinging end of the parallel arm e made of the leaf spring material. When a certain impact or the like is applied from the direction as described above, a moment is generated in the lens support member b due to the impact or the like. Therefore, the objective lens c is shaken in the tracking direction by the distance x by the impact force. The position with respect to the recording track is shifted in the tracking direction.

In addition, in the optical pickup device f shown in FIG. 14, by providing the balance weight k, generation of the rotation moment of the support member g due to impact or acceleration can be suppressed, but the objective lens j is prevented. The lens supporting member g for supporting is supported by inserting the supporting shaft i into the insertion hole h, and thus the lens supporting member g between the supporting shafts i of the lens supporting member g. There is a clearance necessary to be rotatable about the support shaft i and also slidable. Therefore, also in this case, when the impact lamp as described above is applied, the lens support member g is shaken in the tracking direction by the distance of the gap at the maximum by the impact lamp, thereby recording the objective lens j. The position with respect to the track is shifted in the tracking direction.

As is known, in an optical disc, the recording track has a width, i.e., a width of each pit of about 0.5 to 0.8 microns, and a pitch between the tracks of about 1.6 microns, and furthermore, the beam light is at least condensed. The center of the beam spot needs to be irradiated so as to be located at the center of the width of the recording track. In other words, the position of the objective lenses c and j with respect to the recording track must be controlled with a precision of at least 0.5 microns to 0.8 microns or less.

However, if the objective lens is supported by the above-described support structure, tracking deviation can be easily caused by an external shock or acceleration.

[Means to solve the problem]

In order to solve the above-mentioned problems, the optical pickup apparatus according to the present invention supports one base member of the hinge rotatable in the focusing direction and the base end of the parallel link to the base substrate, and at the tip of the parallel link, It supports and fixes the other hinge member to the movable member provided with the objective lens, and the hinge axis of the hinge member passes through the substantially center position of the movable member.

Therefore, according to the present invention, even when acceleration from the outside is applied to the optical pick-up device, the impact lens or the acceleration does not act as a moment to the movable member, i.e., a rotational force that rotates in the tracking direction with the hinge axis as the rotation center. It does not move in the tracking direction.

EXAMPLE

First Embodiment (FIGS. 1 to 4)

1 to 4 show a first embodiment of the optical pickup device of the present invention.

Reference numeral 2 denotes a base substrate of the optical pickup device 1, and the base substrate 2 is a front-rear direction, i.e., a direction toward the left and right directions in FIG. And the rightward direction is "rear side". The upward direction is "left", and the downward direction is "right." In a slightly longer longitudinal direction, one corner is formed in a plate shape inclined cut, the other three corner portions are formed slightly thick, and the long hole 3 is formed in the thickly formed portion.

(4) is an opening formed to extend along the front-rear direction at the center of the left and right direction of the base substrate 2, the width is approximately half of the left and right length of the base substrate 2, the front end portion is formed to form a semi-circle have.

5 is a base projecting between the rear edge of the upper surface of the base substrate 2 and the rear end of the opening 4, and both left and right ends are formed slightly higher than the other parts, and the upper and lower ends of the screw holes ( 6) is formed.

Reference numerals 7, 7 ', 8, and 8' are yokes formed in an upright shape on the upper surface of the base substrate 2. The yoke 7, 7 ′ is formed upright at a portion along the center portion in the front-rear direction of the side edge of the opening 4 of the upper surface of the base substrate 2, and is positioned outside the yoke 8, 8 ') is formed in the state which extends in parallel with the yoke 7,7' in the part along the left and right edges in the upper surface of the base substrate 2. As shown in FIG. Therefore, the yoke 7, 7 ', 8, 8' is formed in the shape of a plate in a substantially long direction that is long in the vertical direction.

In addition, the base substrate 2 is fixed on the optical block which is not shown in figure. The optical block includes, for example, a semiconductor laser that oscillates a laser beam, a corimeter lens and a quarter wave plate for guiding the beam to an objective lens described later, a laser beam oscillated by the semiconductor laser, and a recovery reflected from an optical disk. Computes a focus error signal and a tracking error signal from an optical product such as a polarizing beam splitter for separating the separated light and a photodetector for detecting the returned light, for example, the returned light detected by the photodetector A control circuit for supplying a correction current to a focusing coil and a tracking coil described later by an error signal is provided.

Further, the laser beam oscillated by the semiconductor laser provided in the disk is directed upward through the front end of the opening 4 formed in the base substrate 2 in the state of parallel light beam as shown by the dashed-dotted arrow in FIG. It is formed to exit.

Reference numerals 9 and 9 'denote magnets. The mark nets 9 and 9 'are formed in substantially the same shape as the yokes 7, 7', 8 and 8 ', and the yokes 8 and 8' positioned at the outer side and the yokes positioned at the inner side. It is fixed to the surface opposite to (7,7 ') by fixing means such as adhesive.

Therefore, the yoke 7, 7 ', the magnets 9, 9', and the yoke 8, 81 are formed in a magnetic path in which the force line is soft in the horizontal direction.

Moreover, the coil mentioned later is located in the magnetic path formed in this way.

Reference numeral 10 is a support arm for movably supporting the moving body to be described later in the focusing direction in the upward direction and in the tracking direction in the horizontal direction, wherein the support arm 10 has a base and a parallel link fixed to the base substrate 2 and The hinge is configured to be integrally molded by the synthetic resin.

Reference numeral 11 denotes a base of the support arm 10, and the base 11 is formed in a substantially planar shape with the base 5 formed on the base substrate 2 in a planar shape. The insertion hole 12 extending along is formed.

Reference numeral 13 is a parallel link. The parallel link 13 has a long rectangular shape in the front-rear direction when viewed from above, and is formed in a plate shape that forms a long large shape in the front-rear direction when viewed from the left-right direction. The rear end edge of the parallel link 13 and the front end portions of the upper and lower ends of the base 11 are connected via an extremely thin flexible portion 14.

Reference numeral 15 is a hinge. Since the hinge 15 is integrally formed with the flexible portions 15c connecting the central portions of the hinge members 15a and 15b of the two hinge members 15a1 and 5b positioned to face each other in the forward direction, are formed upward. It is formed to constitute almost H type when it sees. That is, the hinge members 15a and 15b are formed in the shape of a plate having a substantially square shape when viewed from the front-back direction, and the height thereof is formed to be substantially equal to the height of the base 11, and the two hinge members ( Between the center parts of the mutually opposing surfaces of 15a, 15b, it is connected by the flexible part 15c which has the shape which two circular arcs circumscribe from each other from the left-right direction in the state viewed from the upper side. That is, the center part of the flexible part 15c is formed very thinly, and the said thinly formed part is the axis | shaft of the hinge 15, ie, the hinge axis.

The front edges of the parallel links 13 at the rear ends of the upper and lower end surfaces of the rear hinge members 15b of the two hinge members 15 and 15b are connected via a very thin flexible part 16.

The support arm 10 thus formed is located above the central portion of the opening portion 4 in which the hinge 15 is formed in the base substrate 2, and the base 11 is formed in the base substrate 2. The lower part of the bolt 17 passing through the insertion hole 12 at the same time as being mounted on (5) is attached to the screw hole 6 formed in the base 2 so as to be installed in the base substrate 2. 18 is a washer inserted between the base 11 and the head of the bolt 17.

In this way, the hinge 15 is supported by the base substrate 2 via the parallel link 13 and the base 11.

Therefore, when a moving force is applied to the hinge 15 in the focusing direction, the hinge 15 rotates in a state in which the parallel links 13 face each other in parallel to each other, and thus the hinge member 15b moves upward and downward. It moves in the focusing direction while maintaining the extended posture.

In addition, when a moving force in the tracking direction is applied to the hinge member 15a in front of the hinge 15, the hinge member 15a is rotated in the tracking direction with the hinge axis as the rotation center.

Reference numeral 19 is a movable body provided with the objective lens described later.

The height of the movable body 19 is almost the same height as the height of the hinge 15, and when viewed from above, the outer shape takes a similar form with one less rotation in the opening 4 formed in the base substrate 2. At the same time, the base 19a having the large-diameter lens attachment hole 20 in which the axial center extends in the vertical direction and the arm 19b extending parallel to each other from the left and right ends of the base 19a toward the rear are integrally formed. Formed.

Further, in the portion between the lens attachment holes 0 (20) at the rear end of the base (19a), a hinge attachment groove (21) extending in the vertical direction in a width approximately equal to the thickness of the hinge member (15a) of the hinge (15). ) Are formed to face each other.

Further, at the rear end of the arm 19b, attachment holes 22 are formed which extend in the horizontal direction and are located on the same axis.

In addition, an annular projection 20a is formed at a portion almost centered in the vertical direction of the lens attachment hole 20 formed in the base 19a.

In the movable body 19 formed as described above, both side ends of the hinge member 15a in front of the hinge 15 of the support arm 10 are coupled to the hinge attachment groove 21, and the hinge member The 15a is adhered to the rear surface of the base 19a so that it is supported by the support arm 10 via the hinge 15.

In this way, the movable body 19 is movably supported in the focusing direction by the parallel link 13 of the support arm 10 and is rotatably supported in the tracking direction by the hinge 15.

Reference numeral 23 is an objective lens. The objective lens 23 is supported and fixed to the lens holder 24 formed in a substantially cylindrical shape, and the lens attachment hole 20 in which the lower portion of the lens holder 24 is formed in the base 19a of the movable body 19 is provided. By press-fitting into the upper part of, the optical axis is provided at the front end of the movable body 19 in a state where the optical axis extends along the vertical direction.

Reference numerals 25 and 26 are balances provided in the movable body 19. These balances 25 and 26 are provided so that the parts of the movable body 19 which sandwich the hinge axis of the hinge 5 and which are positioned before and after and the vertically positioned portions thereof are parallel in weight.

The front balance 25 of the balances 25 and 26 is formed in a short cylindrical shape in the axial direction, and is formed from the annular projection 20a in the lens attachment hole 20 formed in the base 19a of the movable body 19. It can be mounted on the front end of the movable body 19 by being inserted into and fixed to the lower part.

In addition, the rear balance 26 is formed in a substantially cylindrical shape, and projections 26a are formed on both left and right end surfaces thereof, and these projections 26a are provided in the mounting holes 19b in the arm 19b of the movable body 19. By being inserted into 22, it is fixed to the rear end of the movable body 19.

The center of the movable body 19 is located at the same position as the hinge axis of the hinge 15 of the support arm 10. In detail, the hinge axis of the hinge 15 is positioned through the center of the movable body 19.

Therefore, in order for the movable body 19 to rotate in the tracking direction, from the tracking direction with respect to the position inclined to the objective lens 23 side from the center position of the movable body 19 or to the opposite side of the objective lens 23. It requires a moving force.

By the way, when an impact or the like in the tracking direction is applied to the optical pickup device 1 from the outside, a moving force such as shaking in the tracking direction acts on the movable body 19. In this case, if the center distribution before and after with respect to the hinge axis of the hinge 15 of the movable body 19 is different, a larger moment will be caused in the heavy part, and the movable body 19 will make the hinge axis the center of rotation. It will rotate in the tracking direction.

However, as described above, since the weight balance of the portions positioned at both the front and rear sides of the hinge shaft is maintained, the magnitudes of the moments caused at the portions positioned at the front and rear sides thereof are the same.

Therefore, even if gravity or collision in a predetermined direction generated by moving the device in a constant direction quickly is applied to the optical pickup device 1, the objective lens 23 is not rotated in the tracking direction because the movable body 19 is not rotated. There is no work.

Reference numerals 27 and 27 'denote drive coils provided on both the left and right sides of the movable body 19.

When the drive coils 27 and 27 'are viewed from above, the first coil bases 28 and 28' having a long rectangular shape in the longitudinal direction in the front-rear direction and the first coil bases 28 and 28 'are formed. ) Have second coil bases 29 and 29 'fixed to side surfaces positioned opposite to each other and formed in a substantially forward plate shape, and focusing coils 30 and circumference of the first coil base 28 and 28' 30 '), and the second coil bases 29 and 29' are provided with tracking coils 31 and 31 '(not shown in the drawing, formed on the second coil base 29 on the left side). have.

The driving coils 27 and 27 'are bonded to both left and right sides of the movable body 19 in a state where the first coil bases 28 and 28' are positioned with the yoke 7 inserted therein. It is fixed by fixing means.

Therefore, the drive coils 27 and 27 'are positioned in the above-described paths, that is, in the paths formed by the yokes 7 and 7', the magnets 9 and 9 'and the yokes 8 and 8'.

However, the driving coils 27 and 27 'are supplied with a moving force in the vertical direction while the current is supplied to the focusing coil 30 or 30', and the current is supplied to the tracking coil 31 or 31 '. The moving force is added to the left and right directions.

Therefore, focusing by the optical pickup device 1 configured as described above (i.e., control for uniformly supporting the distance between the objective lens 23 and the recording surface of the optical disc, not shown) and tracking (i.e., the objective The control for positioning the optical axis of the lens 23 in the center of the recording track on the disk is carried out as follows.

That is, the beam light irradiated to the optical disc through the objective lens 23 is reflected on the recording surface of the optical disc, and a part thereof returns to the optical block side through the objective lens 23. The control circuit provided inside the optical block reads the focusing error signal and the tracking error signal from the returned light detected by the photodetector, and simultaneously corrects the correction current having a value corresponding to the error amount. ) And tracking coils 31 and 31 ', respectively.

As a result, the moving force in the focusing direction is generated in the focusing coils 30 and 30 'by the relationship between the direction of the current passing through the focusing coils 30 and 30' and the magnetic flux direction of the magnetic path. ) Is moved in the focusing direction to perform focusing. In addition, since the movement force in the tracking direction is generated in the tracking coils 31 and 31 'by the relationship between the direction of the current through the tracking coils 31 and 31' and the magnetic flux direction of the magnetic path, The sieve 19 rotates in the tracking direction with the hinge axis of the hinge 15 as the rotational center, whereby the tracking of the objective lens 23 is performed.

Second Embodiment (FIGS. 5 to 8)

5 to 8 show a second embodiment 1A of the pickup apparatus of the present invention.

The only difference between the second embodiment and the first embodiment is that the parallel link is formed of a leaf spring material and formed of a member independent of the other parts.

Therefore, only portions different from those of the first embodiment will be described, and explanations thereof will be omitted. This also applies to the third embodiment described later.

In the figure, reference numeral 32 denotes a support arm. Reference numeral 33 is a parallel link formed of a leaf spring material, the front end of which is separately adhesively fixed to the upper and lower end surfaces of the rear hinge member 15b of the hinge 15, and the rear end thereof. The upper and lower end surfaces of the base 11 of the support arm 32 are respectively adhesively fixed. Reference numeral 34 is a washer.

Since the movable body 19 is supported by the base substrate 2 via the hinge 15, the parallel link 33, and the base 11, the movable body 19 is movably supported in the focusing direction by the flexibility of the parallel link 33. At the same time, the hinge 15 is rotatably supported in the tracking direction.

9 to 12 show a third embodiment 1B of the optical pickup apparatus of the present invention.

The difference between the third embodiment and the first embodiment is that one hinge member of the hinge is fixed to the base substrate, and the base end of the parallel link is fixed to the hinge member on the other side of the hinge, and is movable to the tip of the parallel link. This is to support the end portion on the opposite side of the objective lens in the member.

Reference numeral 35 is a circular opening formed at a position approximately midway between the central portion and the front edge of the base substrate 2, and 36 is a position inclined backward from the opening 35 in the upper surface of the base substrate 2; It is a hinge attachment plate formed in an upright shape.

The hinge member 15a is fixed to the rear surface of the hinge attachment plate 36 by fixing means such as adhesive.

Reference numeral 37 is a movable body. The movable body 37 is formed in the shape of the front end portion 37a substantially the same as that of the base portion 19a of the movable body 19 shown in the first embodiment. 37b) is formed to form a long rectangular frame in the front-rear direction when viewed from above, and the rear frame member 38 is formed to be considerably thicker than other portions.

Reference numeral 39 is a parallel link formed of a leaf spring material, the front end of which is separately adhesively fixed to the upper and lower end surfaces of the hinge member 15b, and the rear end thereof is a rear frame member 38 of the movable body 37. The upper and lower sections of the upper and lower ends are separately adhesively fixed.

The movable body 37 has the optical axis of the objective lens 23 provided at its front end located on the axis center of the opening 35 formed in the base substrate 2, and also through the base link through the parallel link 39 and the hinge 15. It is supported by (2).

In addition, since the objective lens 23 and the balance 25 are provided in the front end of the movable body 37, and the rear end thereof is formed to be considerably thick, the hinge of the hinge 15 is almost the center in the front-back direction. It is comprised so that the weight of the part located back and front by sandwiching the part which a shaft communicates is supported in parallel.

Therefore, when an impact lamp is applied to the optical pickup device 1B in the tracking direction, the moving force in the tracking direction is added to the movable body 37, but the hinge axis, which is the rotation center of the movable body 37, is movable. Since the moment that shifts the position of the objective lens 23 is not generated in the movable body 37 because it is disposed so as to pass through the center position of the X, the objective lens 23 is not moved in the tracking direction.

[Effects of the Invention]

As is apparent from the foregoing, the optical pickup device of the present invention provides an optical lens for movably providing an objective lens for condensing beam light on a recording surface of an optical disk in a focusing direction in its optical axis direction and a tracking direction perpendicular to the focusing direction. A pick-up apparatus comprising: supporting a base end portion of a parallel link rotatable in a focusing direction to a base substrate while supporting one hinge member of the hinge rotatable in a tracking direction at the tip end of the parallel link, and the other hinge member provided with an objective lens; It is fixed to a movable body, It is characterized by making the hinge axis of the hinge member pass through the substantially center position of the said movable body.

Therefore, according to the present invention, the objective lens moves in the tracking direction only when a moving force is applied to the installed movable body with respect to the part inclined from the center direction toward the objective lens side or the opposite side of the objective lens.

However, even if an impact or the like is applied to the optical pickup device from the outside, the impact is usually applied to the whole of the movable member, so that the movable member does not rotate with the hinge axis as the rotation center.

And even if an external shock or the like is applied to the optical pickup device, the objective lens is not easily moved in the tracking direction.

Claims (2)

An objective lens 23 for condensing beam light onto the recording surface of the optical disc, a movable body 19 as lens support means to which the objective lens 23 is attached, and the movable body 19 to the objective lens 23; A pair of parallel links 33 serving as support members for displaceably supporting in a direction parallel to the optical axis, a hinge member 15b to which one end side of the pair of parallel links 33 is attached, and the hinge member 15b And a flexible portion 15c disposed between the movable body 19 and supporting the objective lens 23 so as to be displaceable in a direction orthogonal to the optical axis of the objective lens 23, and the pair of parallel links 33 And the fixing means (2, 11, 17) to which the other end side of the lens is attached, and the objective lens (23) is formed by the pair of parallel links (33) and the flexible portion (15c) of the optical axis of the objective lens (23). And the flexible part 15c is displaceablely supported in a direction parallel to the optical axis and in a direction orthogonal to the optical axis. Optical pickup device, characterized in that installed so as to pass through almost the center of the. The optical pickup apparatus of claim 1, wherein the parallel links are each formed of a leaf spring.