JPH11232671A - Object lens driving device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a configuration of an object lens driving device, for optically reading information recorded on a disk to be rotated, which can satisfactorily follow displacement of a track in both a low-speed rotation and a high-speed rotation. SOLUTION: An object lens holding member 2 is held at a relay holding member 71 by four first metal wires 61, and the relay holding member 71 is held at a fixing section 72 by four second metal wires 62. Furthermore, two free vibration systems are formed; a first free vibration system is formed by a total mass of members such as the object lens holding member 2 or the like, which are movably supported by elastic deformation of the first metal wires 61, and a spring constant of the first metal wires 61; and a second free vibration system is formed by a total mass of members such as the object lens holding member 2, the relay member 71 and the like, which are movably supported by the second metal wires 62, and a spring constant of the second metal wires 62.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an objective lens for optically reading information recorded on a rotationally driven disk-shaped recording medium, and a focusing direction and an optical axis parallel to the optical axis of the objective lens. The present invention relates to an objective lens driving device that is driven in a tracking direction perpendicular to.

[0002]

2. Description of the Related Art One supporting means of an objective lens holding member in an objective lens driving device used for an information reproducing apparatus for optically reading information recorded on a rotationally driven disk-shaped recording medium is, for example, four support members. Each end is fixed to the objective lens holding member using a metal wire of,
There is a cantilever support method in which the other end is fixed to a fixing portion. In this cantilever support system, the primary resonance frequency of the objective lens driving device is determined by the mass of the movable body including the objective lens holding member and the spring constant of the metal wire.

In this primary resonance frequency band, since the drive sensitivity to the current applied to the objective lens driving device is significantly increased, the design is performed so that the primary resonance frequency band substantially matches the rotation frequency band of the recording medium. Thereby, the light spot generated by the objective lens fixed to the objective lens holding member secures an acceleration required for following the displacement of the information recording track in the focusing direction and the tracking direction due to the rotation of the recording medium. This facilitates the focusing and tracking servo performance required for reading the optical information of the information reproducing apparatus.

In recent years, in a CD-ROM reproducing apparatus, data transfer speeds such as 4 ×, 8 ×, and 16 × have been promoted with respect to the standard transfer speed of recording information conventionally used for music program reproduction and the like. CD-ROM
It has become the mainstream in the playback equipment market. Such high-speed data transfer is achieved by means for increasing the rotation speed of the disk as the information recording medium. At such a rotation speed, the light spot generated by the objective lens is moved to the information track of the disk. The acceleration sensitivity required to accurately follow the displacement of the optical pickup is required for the objective lens driving device of the optical pickup that reads information.

In order to satisfy this requirement, in a conventional objective lens driving device, its primary resonance frequency is increased in accordance with an increase in the rotational speed of the disk, and maximum displacement of the information recording track in the focusing direction and the tracking direction occurs. The design was made so that the maximum level of acceleration sensitivity could be obtained in the rotational frequency band of the disk.

[0006]

However, increasing the primary resonance frequency of the objective lens driving device in accordance with an increase in the rotational speed of the disk for the purpose of speeding up data transfer is close to the DC band. In the rotational frequency band of the disk, the acceleration sensitivity for the light spot generated by the objective lens to follow the displacement of the information recording track is reduced, and music reproduction and the like which are standard functions of the CD-ROM reproducing apparatus are performed. This is a factor that hinders the operation performance of the data applied at the standard transfer speed.

Therefore, in an optical information reading apparatus such as a CD-ROM reproducing apparatus in which the data transfer speed is increasing, the light spot accurately follows the displacement of the information recording track in at least two disk rotation frequency bands. The acceleration sensitivity required for the normal operation of the focusing servo and the tracking servo is required of the objective lens driving device.

[0008]

The objective lens driving apparatus of the present invention uses two sets of four metal wires as a set of four metal wires as support means for the objective lens holding member. Wherein the objective lens holding member is held by a relay holding member, and the relay holding member is held at a fixed portion by four second metal wires.
A first free vibration system based on a total mass of members such as the objective lens holding member movably supported by elastic deformation of the first metal wire and a spring constant of the four first metal wires; The second metal wire holds the relay holding member to the fixed portion, and the total mass of the objective lens holding member and the relay member and the like, which are movably supported by elastic deformation of the second metal wire, and The two free vibration systems of the second metal wire and the second free vibration system based on the spring constant of the second metal wire are configured, and the mass of these components and the spring constant of the metal wire are optimized to optimize the first free vibration. A resonance phenomenon inherent to the second free vibration system in a band lower than the resonance frequency provided by the free vibration system.

According to this structure, the action on the objective lens holding member of the objective lens driving device is performed in the respective bands of the resonance frequency provided by the first free vibration system and the resonance frequency provided by the second free vibration system. The acceleration sensitivity increases, and the resonance frequency inherent in the first free vibration system is substantially matched with the high-speed rotation frequency of the disk for the purpose of high-speed data transfer, thereby causing the light spot to displace the information recording track. And the follow-up performance of the light spot in the rotation frequency band of the disc at the standard data transfer speed due to the resonance generated in the second free vibration system is improved. It becomes possible to do.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings, taking an objective lens driving device of an optical pickup used in a CD-ROM reproducing device as an example. 1 and 2, a focusing coil 3 for generating a driving force in a focusing direction parallel to the optical axis of the objective lens 1 and a focusing coil 3 and an objective lens are provided around an objective lens holding member 2 for holding the objective lens 1. A tracking coil 4 that generates a driving force in a tracking direction perpendicular to the optical axis is wound around the printed circuit board 5 on both sides of the objective lens holding member 2, and the focusing coil 3 and the The tracking coil 4
Both terminals are connected to one end of the four first metal wires 61, thereby establishing electrical continuity, and the other end of the metal wire 61 is fixed to the relay support block 71 in advance. The printed circuit board 81 is connected and fixed while being electrically connected.

That is, the objective lens holding member 2 is
The first metal wire 61 of the book is movably supported by the relay support block 71 by elastic deformation. Further, the printed circuit board 81 fixed to the relay support block 71
When one end of each of the four second metal wires 62 is connected and fixed, electrical continuity with the first metal wire 61 is established, and the other end of the second metal wire 62 is The printed circuit board 82 fixed to the fixed support block 72 is connected and fixed while being electrically connected to the printed circuit board 82. The fixed support block 72 is fixed to a fixed portion such as a device base.

That is, the relay support block 71
The four second metal wires 62 parallel to the first metal wire 61 are movably supported by the fixed portion by elastic deformation. 10 is a magnetic yoke 9 fixed to the fixed part
A magnet 10 fixed to the focusing coil 3 and the tracking coil 4 so as to face each other with a predetermined gap.
The first metal wire 61 and the second metal wire 62
A predetermined drive current through the focusing coil 3
In addition, the tracking coil 4 forms a magnetic field for generating a driving force by Lorentz force. Thereby, the displacement of the objective lens holding member 2 with respect to the focusing direction parallel to the optical axis of the objective lens 1 and the tracking direction perpendicular to the optical axis is obtained in accordance with the current supply to the focusing coil 3 and the tracking coil 4. , A focusing servo and a tracking servo operation are performed.

FIG. 3 shows an acceleration frequency characteristic observed in a conventionally used objective lens driving device. According to this, a remarkable increase in the acceleration gain is observed in the primary resonance frequency band, and this frequency band is substantially matched with the rotational frequency band of the disk, so that the optical spot follows the displacement of the information recording track in the objective lens driving device. It is possible to increase the sensitivity. Further, when the rotational frequency of the disk is increased for the purpose of speeding up data transfer, the tracking sensitivity in the necessary frequency band can be reduced by adopting a means for increasing the primary resonance frequency of the objective lens driving device as shown in FIG. It is possible to increase. However, since the acceleration gain in a frequency band close to the DC band decreases in inverse proportion to the square of the frequency increase with the increase in the primary resonance frequency, it is applied to music reproduction or the like using a CD-ROM reproducing device. The disk 22
In the low-speed rotation frequency band, the light spot 21 may be a factor that lowers the sensitivity of following the displacement of the information recording track 23.

Therefore, in this embodiment, as described above, two sets of four metal wires are used as support means for the objective lens holding member 2, and one set of first metal wires 61 One end is fixed to the objective lens holding member 2 and the other end is fixed to the relay support member 71, and depends on the total mass of the members supported by the first metal wire 61 and the spring constant of the first metal wire 61. A first free vibration system is formed, and another set of second metal wires 62 has one end fixed to the relay support member 71 and the other end fixed to a fixing portion. A second free vibration system is constituted by the total mass of the members supported by the second metal wire and the spring constant of the second metal wire 62. Then, by optimizing the mass of each component and the spring constant of the metal wires 61 and 62, as shown in FIG. 5, a primary resonance frequency band unique to the first free vibration system, The objective lens holding member 2 in both low primary resonance frequency bands unique to the second free vibration system.
Is to increase the acceleration gain acting on.

[0015]

As described above, the present invention constitutes two sets of free vibration systems using two sets of four metal wires as a set of support means for the objective lens holding member. The acceleration acting on the objective lens holding member is increased in the high-speed rotation frequency band of the disk by substantially matching the resonance frequency unique to the vibration system with the high-speed rotation frequency band of the disk for the purpose of high-speed data transfer, and By causing a resonance phenomenon unique to the second free vibration system in a frequency band lower than a resonance frequency unique to the first free vibration system, the present invention is applied to music reproduction or the like using a CD-ROM reproducing device. The acceleration in the low-speed rotation frequency band of the disk is made larger than the acceleration obtained only by the first free vibration system, and the disk is used for high-speed data transfer. An objective lens driving device capable of increasing the sensitivity to follow the displacement of the information recording track of the light spot in both the high-speed rotation frequency band of the disk and the low-speed rotation frequency band of the disk applied to music reproduction and the like. Things.

[Brief description of the drawings]

FIG. 1 is a plan view of an objective lens driving device according to an embodiment of the present invention.

FIG. 2 is a perspective view of the objective lens driving device according to the embodiment;

FIG. 3 is a diagram showing an example of an acceleration frequency characteristic of a conventional objective lens driving device.

FIG. 4 is a diagram showing an example of an acceleration frequency characteristic of an objective lens driving device corresponding to an increase in data transfer speed due to an increase in a primary resonance frequency.

FIG. 5 is a diagram showing an example of an acceleration frequency characteristic of the objective lens driving device according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Objective lens 2 Objective lens holding member 3 Focusing coil 4 Tracking coil 10 Magnet 61 First metal wire 62 First metal wire 71 Relay member 72 Fixing member

Claims (1)

[Claims] An objective lens is held, and a focusing coil for generating a driving force in a focusing direction parallel to an optical axis of the objective lens on an outer peripheral portion thereof, and a tracking coil perpendicular to the optical axis of the objective lens. An objective lens holding member around which a tracking coil for generating a force is wound; four first metal wires having one end fixed to the objective lens holding member and the other end fixed to a relay holding member; Current is supplied to the focusing coil and the tracking coil via four second metal wires, one end of which is fixed to the holding member and the other end of which is fixed to the fixing portion, and the first metal wire and the second metal wire. And a magnetic circuit member disposed on the fixed portion so as to form a magnetic field for generating a driving force by Lorentz force by supplying An objective lens holding member is movably supported by the relay holding member by elastic deformation of the first metal wire, and the relay holding member is movably supported by the fixing portion by elastic deformation of the second metal wire. An objective lens driving device, characterized in that: