JP2005182930A - Objective lens driving device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an objective lens driving device capable of obtaining a small amount of an effective damper effect by arranging damper agents in proper positions in the actuator of the objective lens driving device of a symmetrical type equipped with a suspension wire, thereby contributing a cost reduction. <P>SOLUTION: The objective lens driving device 100 used for an optical pickup is provided with a damper base having an objective lens holder 20 for holding an objective lens 30, a suspension wire 1 on both sides of the holder 20 with each one end fixed to a first fixing part, second and third fixing parts 12 and 13 for supporting the other end side of the suspension wire 1. A distance between the second and third fixing parts 12 and 13 is set larger by 1/5 to 2/5 times than that between the first and third fixing parts, and a damper agent 3 is applied on the second fixing to flexibly support the suspension wire 1. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an objective lens driving device used for an optical disk drive, and more particularly to a support structure for the objective lens holder.

  An optical disc drive reads information recorded on an optical disc (CD, CD-ROM, CD-R, CD-RW, DVD-ROM, DVD + R, DVD-R, DVD-RAM, DVD + RW, DVD-RW, etc.) Or a device for writing information. This type of optical disk drive includes an optical pickup for irradiating the optical disk with laser light and detecting the reflected light in order to read information from the optical disk or write information to the optical disk. Yes.

  In general, an optical pickup includes a laser light source that emits a laser beam and an optical system that guides the emitted laser beam to an optical disc and guides the reflected light to a photodetector. The optical system includes an objective lens disposed so as to face the optical disc.

  The objective lens used in the optical pickup is focused on the focus direction along the optical axis and the track direction along the radial direction of the optical disc so that the laser beam is accurately focused on the recording surface (track) of the optical disc driven to rotate. The position needs to be accurately controlled. Recently, with the improvement in recording density, there is an increasing need to eliminate or suppress the influence of warping of the optical disc, and the objective lens needs to be tilted.

  A conventional objective lens driving device elastically supports an objective lens holder that holds an objective lens by a plurality of suspension wires in order to enable focusing control, tracking control, and tilting control.

  Further, a focusing coil, a tracking coil, and a tilting coil are wound or attached to the objective lens holder, and these coils are partially positioned in the gap of the magnetic circuit. In such a configuration, by controlling the current flowing through each coil, the conventional objective lens driving device can finely adjust the position and inclination of the objective lens (see, for example, Patent Document 1).

  FIG. 11 is a perspective view of the objective lens driving device disclosed in Patent Document 2. FIG. FIG. 12 is a perspective view showing a state in which the metal top cover 57 of the objective lens driving device of FIG. 11 is removed.

  As shown in FIGS. 11 and 12, the objective lens driving device includes a base 51, an objective lens 52, an objective lens holder 53, and four pieces that support the objective lens holder 53 in a swingable manner with respect to the base 51 ( Only two suspension wires 54, a pair of yokes 55 fixed to the base 51, and a magnet 56 fixed to each yoke 55.

  This objective lens driving device is mounted on an optical base of an optical disk driver (not shown) and constitutes an optical pickup. The optical base is attached to the guide bar so as to be movable along the radial direction (tracking direction Tr) of the optical disc introduced into the optical disc apparatus. In addition, a laser diode, a photodetector, and a predetermined optical system are attached to the optical base. Laser light from the laser diode is irradiated onto the optical disc through the objective lens 52, and the reflected light is guided to the photodetector. It is configured to be.

  As will be described later, a tilting coil, a focusing coil, and a tracking coil are wound around the objective lens holder 53, and the objective lens holder 53 is controlled by a yoke 55 by appropriately controlling the current flowing through these coils. And tilting in the tracking direction (Tr) based on the relationship with the magnetic field created by the magnet 56 (rotating with an axis parallel to the tangential direction Tg as a rotation axis), and moving along the tracking direction (Tr), Or it moves along the focusing direction (F).

  The objective lens holder 53 includes an upper member 60 as shown in FIG. 13 and a lower member 65 as shown in FIG.

  As shown in FIG. 13, the upper member 60 has a substantially square plate shape (the surface facing the lower member 65 is substantially square), and a through hole 61 for attaching the objective lens is formed at the center thereof. Has been. Further, four rectangular holes 62 for inserting a part of the yoke 55 are formed in symmetrical positions near the four corners of the upper member 60. The yoke 55 has a U-shaped cross section, and one opposing surface is composed of two vertical bar pieces.

  The upper member 60 also has fixing portions 63 for fixing the suspension wire 54 on both sides of the tracking direction (Tr). Further, on both sides of the upper member 60 in the tangential direction (Tg), four first hook portions 64 for winding the tracking coil are projected in the tangential direction in the vicinity of the end portions thereof. Is formed.

  On the other hand, as shown in FIG. 14, the lower member 65 protrudes in a vertical direction from a plate-like portion 66 having a substantially square shape (a surface facing the upper member 60 is substantially square) and one surface of the plate-like portion 66. And a tilting coil winding part 67. The size of the plate-like portion 66 is the same as that of the upper member 60 at least in the tangential direction (Tg).

  In the center of the plate-like portion 66, a through hole 69 for allowing laser light to pass is formed. Further, four rectangular holes for inserting a part of the yoke 55 are formed in the vicinity of the four corners of the plate-like portion 66. The tilting coil winding frame 67 is formed so as to surround the square hole incompletely.

  Further, the lower member 65 has four second hook portions 68 for winding the tracking coil in the vicinity of the end portions on both sides of the tangential direction (Tg) along the tangential direction. It is formed to protrude.

  The upper member 60 and the lower member 65 described above are combined with each other to form the objective lens holder 53. Before the combination, the tilting coil 70 and the focusing coil 71 are arranged in this order in the tilting coil winding frame portion. No. 67 is wound.

  As shown in FIG. 15, the tilting coil 70 is wound around each of the four tilting coil winding frame portions 67 in order. Thereafter, the focusing coil 71 is wound with the four tilting coil winding frames 67 around which the tilting coils 70 are wound as a single core.

  Thus, after the tilting coil 70 and the focusing coil 71 are wound around the lower member 65, the upper member 60 is fixed to the lower member 65.

  When the entire objective lens holder 53 is regarded as a focusing coil winding frame portion in a combined state, the plate-like portions 66 of the upper member 60 and the lower member 65 correspond to flanges. As described above, the four tilting coil winding frame portions 67 correspond to the winding cores.

  The central axis of the through hole 61 formed in the upper member 60 and the central axis of the through hole 67 formed in the lower member 65 coincide with each other. Further, the four first hook portions 64 formed on the upper member 60 and the four second hook portions 68 formed on the lower member 65 are opposed to each other to form a pair. Each pair of the first hook portion 64 and the second hook portion 68 constitutes four tracking coil winding frame portions for winding the tracking coil.

  Thereafter, as shown in FIG. 15, the tracking coil 72 is wound around the four tracking coil winding frames, and the objective lens 52 is attached as shown in FIG. 16.

  FIG. 16 shows a state where the yoke 55 and the magnet 56 are combined with the objective lens holder 53 to which the coils 70, 71 and 72 are wound and the suspension wire 54 is attached. The magnet 56 is a dipole magnetized magnet.

  The ends of the tilting coil 70, the focusing coil 71 and the tracking coil 72 are connected to connection terminals 81, 82 and 83. Here, the connection terminals 81 and 82 to which the ends of the focusing coil 71 and the tracking coil 72 are connected are further connected to the fixing part 63 formed on the upper member 60 as shown in FIG. One end of each suspension wire 54 fixed in a penetrating state is connected. On the other hand, a lead wire 84 is connected to the connection terminal to which the tilting coil 70 is connected, as shown in FIG.

  As shown in FIG. 16, after the lead wire 84 is fixed through the fixing portion 63, the lead wire 84 is bent downward and connected to the connecting member 83 for the tilting coil 70 provided on the lower member 65 of the objective lens holder 53. Connected.

  As can be easily understood from FIG. 16, a part of each of the tilting coil 70, the focusing coil 71, and the tracking coil 72 is disposed in the magnetic gap of the magnetic circuit created by the combination of the yoke 55 and the magnet 56. Yes. Thereby, the objective lens holder 53 moves and tilts according to the current flowing through each coil. That is, tilting control, focusing control, and tracking control can be performed by controlling the current flowing through each coil.

  Normally, the actuator is filled with a damper agent at the base portion of the suspension wire. With this method, an appropriate damper effect cannot be obtained unless a large amount of damper agent is used.

JP 2001-93177 A Japanese Patent Application No. 2003-111953

  Therefore, one technical problem of the present invention is that an effective damper effect can be obtained in a small amount by arranging the damper agent at an appropriate position in the actuator of the symmetrical type objective lens driving device provided with the suspension wire. Therefore, an object of the present invention is to provide an objective lens driving device that can contribute to cost reduction.

  According to the present invention, the objective lens holder (20) for holding the objective lens, and the suspension wire (one end fixed to the first fixing portion (11) on both sides of the objective lens holder (20)) 1) and the objective lens holder (20) are provided apart from each other in the first direction, and the second and third fixing parts (12, 12) supporting the two places on the other end side of the suspension wire (1). 13), the distance between the second and third fixing portions (12, 13) is the distance between the first and third fixing portions (11). 13) The objective lens, wherein the suspension wire (1) is flexibly supported by providing a damper agent in the second fixing part (12), and having a distance of 1/5 to 2/5 times the distance between them. A drive device (100) is obtained.

  According to the present invention, in the objective lens driving device (100), the objective lens holder (10) includes a yoke base (23) that supports the objective lens holder (20) and the damper base (10). ) Includes a tilting coil (16), a focusing coil (17) wound around the coil, and tracking coils (14) provided on both sides of the outer ends of each coil, respectively. A first magnet (22) provided on the yoke base (23) so as to sandwich each coil of the objective lens holder (10), and a pair of first magnets (22) on both sides, respectively. The objective lens drive device (100) is provided, which includes a pair of second magnets (21) disposed between the two magnets.

  According to the present invention, in the objective lens driving device (100), the yoke base (23) includes the four first yokes (25) disposed in the respective coils, and the first An objective lens driving device (100) is provided, comprising plate-shaped yokes (23a, 23b) respectively disposed at both ends in the first direction of the magnet (22).

  According to the present invention, in the objective lens driving device (100), one end (2a) of the lead wire (2) bent in an L shape is connected to the tip of the tilting coil (16). The one end portion (1a) penetrates the wall portion from the space provided in the vicinity of the objective lens (20), and the other end is a fixed groove provided in the substantially central portion of the damper base (10). The objective lens driving device (100) is obtained, which is protruded rearward after being fixed through (8a, 8b).

  Note that the reference numerals in the parentheses are given only for easy understanding of the present invention, and do not limit the present invention.

  According to the present invention, in the actuator of the symmetrical type objective lens driving device provided with the suspension wire, the damper agent is disposed at an appropriate position, thereby suppressing the unnecessary resonance and the gain distortion, and an effective damper effect in a small amount. Therefore, an objective lens driving device that can contribute to cost reduction can be provided.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  1 is a perspective view of an objective lens driving device according to an embodiment of the present invention, FIG. 2 is a front view of the objective lens driving device of FIG. 1, and FIG. 3 is a rear view of the objective lens driving device of FIG. Is the reverse of FIG. 4 is a top view of the objective lens driving device of FIG. 1, FIG. 5 is a right side view of the objective lens driving device of FIG. 1, FIG. 6 is a left side view of the objective lens driving device of FIG. It is a bottom view of 1 objective lens drive device.

  As shown in FIGS. 1 to 7, the objective lens driving device 100 supports the damper base 10, the objective lens 30, the objective lens holder 20, and the objective lens holder 20 so as to be swingable with respect to the damper base 10. Four suspension wires 1, 1, 1, 1 and two lead wires 2, 2, a yoke base 23 on which a damper base 10 and an objective lens holder 20 are mounted, and magnets 21, 22 fixed to the yoke base 23, have.

  The objective lens driving device 100 is mounted on an optical base of an optical disk driver (not shown) and constitutes an optical pickup. The optical base is attached to the guide bar so as to be movable along the radial direction (tracking direction (hereinafter referred to as Tr direction)) of the optical disc introduced into the optical disc apparatus. In addition, a laser diode, a photodetector, and a predetermined optical system are attached to the optical base. Laser light from the laser diode is irradiated onto the optical disc through the objective lens 30, and the reflected light is guided to the photodetector. It is configured to be.

  Fixing portions 12 and 13 are formed on both sides of the tangential direction (hereinafter referred to as the Tg direction), which is the first direction of the damper base 10, respectively. Further, near the center of the damper base 10 in the Tg direction, the fixing portions 5 are formed on both sides of the center, and the fixing portions 12 and 5 are bent in an S shape so that the fixing grooves 9 are opened from each other. Furthermore, it extends in the Tg direction and penetrates to the outside. A suspension wire is supported and fixed to each fixing portion.

  The objective lens holder 20 includes a hollow coil member 18 having a tilting coil 16 and a focusing coil 17 wound around the tilting coil 16, and a tracking coil 14. These tilting coil 16, focusing coil and the like. 17 and the tracking coil 14 by appropriately controlling the current, the objective lens holder 20 has a first perpendicular to the first direction based on the relationship between the yokes 23a, 23b, 25 and the magnetic fields generated by the magnets 21, 22. The third direction tilts in the Tr direction, which is the direction 2 (rotates about the axis parallel to the Tg direction as a rotation axis), and moves along the Tr direction, or a third direction perpendicular to the first and second directions. It moves along the focusing direction (hereinafter referred to as the F direction).

  As best shown in FIG. 7, the yoke base 23 includes four plate-like yokes (hereinafter referred to as first yokes) 25, 25, 25 provided on both sides of the central portion in the Tg direction. , 25 and a trapezoidal yoke connecting the tip ends of plate-like yokes (hereinafter referred to as second yokes) 23b, 23b provided upright at one end in the Tg direction, and the width direction provided near the other end Are provided with two yokes 23a, 23a (hereinafter also referred to as second yokes) provided on both sides.

  Furthermore, the first magnet 22 on the same side in the length direction is in contact with the second yokes 23a and 23b, and the first magnet 22 adjacent in the Tr direction (width direction) is in contact with the yoke base 23. Are provided with first magnets 22 and 22 so as to have opposite polarities. Moreover, the 2nd magnets 21 and 21 are provided also in the center both sides so that it may have the polarity mutually opposite in a length direction.

  The objective lens holder 20 has a thick square plate shape, and has a mounting hole 32 provided with a mounting portion 31 on the upper surface side for mounting the objective lens 30 in the center and a coil member 18 for mounting the coil member 18 symmetrically at the four corners. A coil mounting hole 28 and holes 29 through which the permanent magnets 21 and 21 pass are provided on both sides. The coil member 18 is penetrated by plate-shaped first yokes 25, 25, 25, 25 provided on the yoke base 23, respectively.

  In the objective lens holder 20, the tilting coil 16 and the focusing coil 17 are wound around a winding frame or a winding member (not shown) in this order, and are wound around the winding frame, or A hollow coil member 16 from which the winding member is extracted is formed. As described above, the tilting coil 16 is wound around each of four tilting coil winding frames (not shown) in order. Thereafter, the focusing coil 7 is wound around the four tilting coils around which the tilting coils 16 are wound, and is wound around the winding frame, or the tubular shape is removed from the winding frame. The four coil members 16 in the state are formed and inserted into the four coil mounting holes 28, respectively.

  The objective lens holder 20 is further formed with a connection terminal 11 as a first fixing portion for fixing the lead wire 54, arranged vertically at both ends in the Tr direction (in the F direction). Further, on both sides of the lens holder 20 in the Tg direction, two pairs of a first hook portion and a second hook portion (not shown) for winding the tracking coil 14 are provided in the vicinity of the end portion along the tangential direction. A total of four pairs are provided side by side in the vertical direction. The tracking coil 14 is wound around each of the upper and lower pairs of the first hook portion and the second hook portion, so that a total of four tracking coils are formed.

  Thereafter, the objective lens 30 is attached to the objective lens mounting portion 31.

  The end portions of the focusing coil 17 and the tracking coil 14 are connected to four connection terminals 11, 11, 11, 11 which are first fixing portions provided on the upper and lower sides of the objective lens holder 20 in the Tg direction. . Here, the connection terminals 11 and 11 to which the end portions of the focusing coil 17 and the tracking coil 14 are connected further pass through the second and third fixing portions 12 and 13 of the damper base 10 from the other end side, and the objectives. One end of the suspension wire 1 fixed in a state of passing through the connection terminal 11 is connected to the connection terminal 11 which is a fixing portion formed in the lens holder 20.

  On the other hand, the tip of the tilting coil 16 is connected to the tip of the one end 2a bent in an L shape of the lead wire 2 having an inclined surface in the middle.

  One end 2a of the lead wire 2 is bent upward in an L shape, and the tip of the lead wire 2 penetrates through the wall 5 into the space 35 of the objective lens holder 20, and is formed in this space 35. The other end of the tamper base 10 provided with grooves 8a and 8b is pulled out through the fixing portion 36 and fixed through the fixing portion 5 of the damper base 10 and the fixing groove 7 bent in an S shape. It protrudes rearward through the fixing hole 8.

  On the other hand, the tip 16a of the tilting coil 16 reaches the space through a groove (not shown). The tip 2a of the lead wire 2 and the tip 16a of the coil 16 are fixed by soldering. The lead wire 2 uses a coil wire or a twisted wire (Litz wire).

  It should be noted that damper members 4 and 3 are filled in the portions of the fixing portions 5 and 12 that accommodate the suspension wire 1 or the lead wire 2, respectively. The arrangement and operation of the tracking coil 14, the tilting coil 16, the focusing coil 17, the first and second magnets 22 and 21, and the first and second yokes 25 and 23a are as follows.

  As can be easily understood from FIGS. 1 to 7, the magnetic gap of the magnetic circuit created by the combination of the first and second yokes 23a, 23b, 25 and the first and second magnets 21, 22 in the tangential direction. Inside, a part of each of the tilting coil 16, the focusing coil 17, and the tracking coil 14 is disposed. The first magnet 22 is a magnet that applies driving force to the focusing coil 17 and the tracking coil 14. The second magnet 21 is a magnet that supplements the driving force of the focusing coil 17 and the tilt coil 16.

  That is, with respect to the focusing coil 17, both the left and right coils in the Tg direction receive a driving force in the same vertical direction. Similarly, the tracking coil 14 receives the driving force in the same direction in the Tr direction in both the left and right coils in the Tg direction. The tilting coil 16 receives a force such that the pair of left and right coils in the Tg direction are in opposite directions on the right and left. At that time, since the direction of the magnetic field lines is bent by the second magnet 21 toward the outer side and the inner side in the track direction of the yoke, the driving force in the same direction is also applied to the outer and inner coils in the Tr direction. The acceleration sensitivity in the tilt direction can be increased because the lead wire 1 is supported on the inner side in the Tr direction. Similarly, the acceleration sensitivity of the focus coil 17 can be increased by the arrangement of the second magnet 21.

  Next, the unnecessary resonance preventing action of the suspension wire at the damper agent application position will be described.

  8, FIG. 9, and FIG. 10 are diagrams respectively showing the relationship between the frequency, gain, and phase at the damper agent application positions 1/10, 1/2, and 1/3 in FIG.

  As shown in FIG. 4, the position of the fixed end position A (connection terminal 11) on the objective lens holder side and the innermost position C (on the damper base side) with respect to the suspension wire 1 of the third fixing portion 13 of the damper base 10 are provided. The frequency characteristics were examined with reference to the innermost position of the damper agent 3 of the second fixed portion 12 when the length between the fixed end portion position) and the fixed end portion position was X.

  As shown in FIG. 8, when the damper agent application position is at a position X / 10 with respect to the distance X between the fixed ends of the suspension wire, an unnecessary resonance indicated by A occurs in the vicinity of 200 MHz with respect to the gain. With respect to, phase disturbance due to unnecessary resonance indicated by B occurs in the vicinity of the same 200 MHz. Therefore, it can be seen that there is no damper effect.

  As shown in FIG. 9, it can be seen that the damper effect is strong when the damper agent application position is X / 2 with respect to the distance X between the fixed ends of the suspension wires.

  Specifically, regarding the gain, the unnecessary resonance effect that occurred near 200 MHz does not occur due to the damper effect, but the gain fluctuation indicated by C occurs, and the phase is indicated by D near the same 60 MHz. It can be seen that the phase delay due to gain gain is extremely large and servo control is difficult.

  As shown in FIG. 10, when the damper agent application position is at a position X / 3 with respect to the distance X between the fixed ends of the suspension wire, the unnecessary resonance generated in the vicinity of 200 MHz also appears moderately with respect to the gain. It does not occur due to the effect of the damper effect, and further, there is no gain fluctuation with respect to the frequency, and there is no influence on the phase such as phase disturbance or phase delay, and the servo control can be performed.

  Therefore, by placing the damper agent application position at a position that is 1/5 to 2/5 of the wire length from the position where the damper base side wire is fixed, the best effect can be obtained by applying a small amount of expensive damper agent. It can be seen that The reason why the damper agent application position has a range from 1/5 to 2/5 is that the damper effect varies depending on the viscosity difference depending on the type of the damper agent.

  As described above, in the embodiment of the present invention, by setting the suspension wire application position to a length of 1/5 to 2/5, unnecessary resonance and gain distortion can be prevented. In addition, it is possible to provide an objective lens driving device that is easy to servo control and inexpensive.

  In the embodiment of the present invention, an optical desk drive such as an optical pickup device such as a CD-ROM, CD ± RW, DVD-ROM, DVD ± R / RW, DVD-RAM, Blu-ray, AOD, etc. The objective lens driving device is not limited.

  Further, according to the embodiment of the present invention, it is applicable not only to the half-height slim ultra-slim type but also to symmetric type and asymmetric type objective lens driving devices mounted on all drives. is there.

  The objective lens driving device according to the present invention can be applied to an optical pickup of an optical disk drive.

It is a perspective view of the objective lens drive device by an embodiment of the invention. It is a front view of the objective lens drive device of FIG. It is a rear view of the objective lens drive device of FIG. 1, and the vertical relationship is reverse to FIG. It is a top view of the objective lens drive device of FIG. It is a right view of the objective lens drive device of FIG. It is a left view of the objective lens drive device of FIG. It is a bottom view of the objective lens drive device of FIG. It is a figure which shows the relationship between the frequency in the damper agent application position 1/10 of FIG. 4, a gain, and a phase. It is a figure which shows the relationship between the frequency in the damper agent application position 1/2 of FIG. 4, a gain, and a phase. It is a figure which shows the relationship between the frequency in the damper agent application position 1/3 of FIG. 4, a gain, and a phase. It is a perspective view of the objective lens drive device by a prior art. It is a perspective view which shows the state which removed the top cover of the objective lens drive device of FIG. It is a perspective view which shows the upper side member of the objective lens holder used for the objective lens drive device of FIG. It is a perspective view of the lower member of the objective lens holder used for the objective lens drive device of FIG. It is a perspective view which shows the state which provided the tracking coil combining the upper side member of FIG. 13, and the lower side member of FIG. FIG. 16 is a perspective view showing a state in which an objective lens is mounted on the objective lens holder in the state shown in FIG. 15 and a magnetic circuit including a yoke and a magnet is combined.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Suspension wire 2 Lead wire 2a One end part 3, 4 Damper member 5 Fixed part 7 Fixed groove 8a, 8b Groove 10 Damper base 11 Connection terminal (1st fixed part)
12 Second fixing portion 13 Third fixing portion 14 Tracking coil 16 Tilting coil 16a Tip 17 Focusing coil 18 Coil member 20 Objective lens holder 21 Second magnet 22 First magnet 23 Yoke base 23a, 23b First Yoke 25 Second yoke 28 Coil mounting hole 29 Hole 30 Objective lens 31 Objective lens mounting part 32 Mounting hole 35 Space 36 Fixed part 51 Base 52 Objective lens 53 Objective lens holder 54 Suspension wire 55 Yoke 56 Magnet 57 Metal top cover 60 Upper member 63 Fixed portion 64 First hook portion 65 Lower member 66 Plate-like portion 67 Tilting coil winding frame portion 68 Second hook portion 69 Through hole 70 Tilting coil 71 Focusing coil 72 Tracking coil 81, 8 2,83 connection terminal 100 objective lens driving device

Claims (4)

An objective lens holder for holding the objective lens, a suspension wire having one end fixed to the first fixing portion on each side of the objective lens holder, and a distance from the objective lens holder in the first direction. An objective lens driving device including a damper base having second and third fixing portions that support two portions on the other end side of the suspension wire;
The distance between the second and third fixing parts is set to 1/5 to 2/5 times the distance between the first and third fixing parts, and a damper agent is provided in the second fixing part. An objective lens driving device characterized by flexibly supporting a suspension wire.   The objective lens driving device according to claim 1, further comprising a yoke base that supports the objective lens holder and the damper base, wherein the objective lens holder includes a tilting coil, a focusing coil wound around the periphery thereof, A first magnet provided at four locations on each side of the outer ends of each of the coils; and a first magnet provided on the yoke base so as to sandwich the coils of the objective lens holder; An objective lens driving device comprising: a pair of second magnets disposed between a pair of first magnets on each of the both sides.   3. The objective lens driving device according to claim 2, wherein the yoke base includes four first yokes disposed in each of the coils and both ends of the first magnet on the outer side in the first direction. An objective lens driving device comprising: a plate-shaped second yoke arranged. 3. The objective lens driving device according to claim 2, wherein one end portion of the lead wire bent in an L shape is connected to a tip of the tilting coil, and the one end portion is a space provided in the vicinity of the objective lens. An objective lens driving device characterized in that it penetrates a wall portion from the inside, and the other end protrudes rearward after being fixed through a fixing groove provided in a substantially central portion of the damper base. .

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