JP2009295217A - Optical pickup device and optical disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a novel and improved optical pickup device and optical disk device, capable of reducing influence given to an objective lens caused by secondary resonance produced on a lens support member. <P>SOLUTION: The optical pickup device includes a lens support member 120 having a holding unit 121 for holding a plurality of objective lenses 160, 161, and a drive receiving unit 122 provided on only one side of the holding unit, for receiving drive force driving the holding unit. The center of the objective lens becomes a portion of one node among a plurality of vibration nodes caused by the secondary resonance being generated at the lens support member and propagating to the direction of connecting between the holding unit and the drive receiving unit. Further, the holding unit has a surplus portion disposed opposite to the drive receiving unit. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an optical pickup device and an optical disc device.

  An optical disc (drive) device writes data on a data recording surface of an optical disc such as a CD, DVD, or Blu-ray disc, or reads data recorded on the data recording surface. An optical pickup device is provided with an optical pickup device that irradiates an optical disc with laser light and receives reflected light from the optical disc.

  The optical pickup device includes an actuator that causes an objective lens to follow an optical disk that rotates at high speed. Examples of the actuator include a biaxial actuator that can drive the objective lens in the biaxial direction of the focus direction and the tracking direction, and a triaxial actuator that can drive the objective lens in the tilt direction in addition to the biaxial direction. . The actuator includes a lens holder that holds the lens, a magnet for driving the lens holder, an electromagnetic coil, and the like.

  For example, Patent Document 1 discloses an example of an optical pickup device.

Japanese Patent No. 3711722

  By the way, the actuator of the optical pickup device is vibrated when driven or by an external input. Therefore, in the design of the actuator, it is necessary to consider the resonance generated in the actuator. For example, in Patent Document 1, by forming a slit hole penetrating the holder portion between both side surfaces of the holder of the biaxial actuator and the objective lens, vibration due to secondary resonance generated on both side surfaces of the holder is detected by the objective lens. Is not transmitted to the holder on which is mounted.

  The actuator of Patent Document 1 has a configuration in which one objective lens is sandwiched between magnets and coils on both sides. On the other hand, there is a lens holder of an actuator in which an objective lens is disposed on one end side and a drive receiving portion having a coil is disposed on the other end side.

  Thus, the actuator has various shapes, and it is necessary to consider the resonance characteristics for each. Incidentally, an optical pickup device provided in an optical disk device has recently been required to be downsized. Therefore, there has been a problem that there has been a limit in the conventional methods for adjusting resonance characteristics, for example, the method of providing a slit or the selection of the material of the actuator.

  Therefore, the present invention has been made in view of the above problems, and an object of the present invention is a novel that can reduce the influence of secondary resonance generated in the lens support member on the objective lens. Another object of the present invention is to provide an improved optical pickup device and optical disc device.

  In order to solve the above problems, according to an aspect of the present invention, a holding unit that holds a plurality of objective lenses, and a drive receiving unit that is provided only on one side of the holding unit and receives a driving force that drives the holding unit And a center of the objective lens of one of the plurality of nodes of vibration caused by secondary resonance propagating in a direction connecting the holding portion and the drive receiving portion generated in the lens supporting member. An optical pickup device is provided in which a surplus portion is provided on the side opposite to the drive receiving portion.

  In order to solve the above problems, according to another aspect of the present invention, a holding unit that holds a plurality of objective lenses and a driving force that is provided only on one side of the holding unit and that drives the holding unit are received. And a lens support member having a drive receiving portion, wherein the center of the objective lens is one of a plurality of nodes of vibration caused by secondary resonance that propagates in a direction connecting the holding portion and the drive receiving portion generated in the lens support member. The objective lens is disposed on the drive receiving portion side in the holding portion, and the holding portion is formed by leaving a surplus portion having a predetermined length from one end of the holding portion to the end portion of the objective lens. An optical pickup device is provided.

  In order to solve the above problems, according to another aspect of the present invention, a holding unit that holds a plurality of objective lenses and a driving force that is provided only on one side of the holding unit and that drives the holding unit are received. And a lens support member having a drive receiving portion, wherein the center of the objective lens is one of a plurality of nodes of vibration caused by secondary resonance that propagates in a direction connecting the holding portion and the drive receiving portion generated in the lens support member. There is provided an optical pickup device that further includes a projecting portion that is provided at one node and the lens support member projects from the holding portion on the opposite side of the drive receiving portion with the holding portion interposed therebetween.

  At least two objective lenses among the plurality of objective lenses may be arranged in the holding portion in a direction substantially perpendicular to a direction connecting the holding portion and the drive receiving portion.

  The drive receiving portion has a first through-hole penetrating in the optical axis direction of light passing through the objective lens, through which the first magnet penetrates, the first coil is disposed on the inner surface facing the first magnet. And between the holding portion and the first through hole, the second magnet passes therethrough, the second coil is disposed on the inner surface facing the second magnet, and penetrates in the optical axis direction of light. The second through hole may be included.

  In order to solve the above problems, according to another aspect of the present invention, a light emitting element that irradiates light toward an optical disk, and a plurality of objective lenses that allow light to pass through and collect the light onto the optical disk, A first magnet extending in the optical axis direction of the light passing through the objective lens, a second magnet extending in the optical axis direction of the light apart from the first magnet, and a plurality of objectives A holding portion that holds the lens, a first magnet that penetrates through, a first coil that faces the first magnet and is disposed on the inner surface, and a first through hole that penetrates in the optical axis direction of the light, and holding The second magnet is provided between the first through hole, the second magnet penetrates, the second coil is disposed on the inner surface so as to face the second magnet, and penetrates in the optical axis direction of the light. And a lens support member having a through-hole, and the center of the objective lens connects the holding portion and the drive receiving portion generated in the lens support member. Be one of the nodes of the portion of the plurality of nodes of vibration due to secondary resonance propagating in direction, the holding unit, the optical disk apparatus excess portion is provided on the side opposite to the driving force receiving portion is provided.

  Provided on the light incident side of the objective lens is a reflection member that reflects the light emitted from the light emitting element, and the light emitted from the light emitting element is reflected almost perpendicularly by the reflecting member and enters the objective lens. May be.

  The lens support member may be provided such that the direction connecting the first magnet and the second magnet is substantially perpendicular to the radial direction of the optical disc.

  At least two objective lenses among the plurality of objective lenses may be provided so as to be substantially parallel to the radial direction of the optical disc.

  According to the present invention, it is possible to reduce the influence of secondary resonance generated in the lens support member on the objective lens.

  Exemplary embodiments of the present invention will be described below in detail with reference to the accompanying drawings. In addition, in this specification and drawing, about the component which has the substantially same function structure, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol.

  First, an optical disk device 100 according to a first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing a configuration of an optical disc apparatus 100 according to the present embodiment.

  As shown in FIG. 1, the optical disc apparatus 100 includes an optical pickup 102, a spindle motor 104 that rotationally drives an optical disc (optical disc recording medium) 10, a feed motor 106, a drive control unit 108, a signal processing unit 110, The signal modulation / demodulation unit 112, the system controller 114, and the operation unit 116 are included.

  The optical pickup 102 is an example of an optical pickup device, and irradiates the optical disc 10 with laser light or receives light reflected by the optical disc 10. As will be described later with reference to FIG. 2 and the like, the optical pickup 102 includes objective lenses 160 and 161, a biaxial actuator 118 that drives the objective lenses 160 and 161, a light emitting element (for example, laser diodes 150 and 151), and a light receiving element (for example, And a photo detector 154).

  The objective lenses 160 and 161 of the optical pickup 102 are driven while tracking control and focus control are performed by a biaxial actuator 118. The objective lenses 160 and 161 collect the laser light emitted from the laser diodes 150 and 151 on the optical disc 10. The objective lenses 160 and 161 can focus laser light on the optical disk 10 as a light spot.

  The biaxial actuator 118 is a drive device that causes the objective lenses 160 and 161 to follow the optical disk 10 that rotates at high speed. The biaxial actuator 118 receives a drive signal from the drive control unit 108. The biaxial actuator 118 can drive the objective lenses 160 and 161 in the biaxial direction of the focus direction and the tracking direction. The biaxial actuator 118 adjusts the focus of the laser beam on the data recording surface of the optical disc 10. The driving of the objective lenses 160 and 161 is not limited to the biaxial actuator 118. A triaxial actuator may be used. At this time, the triaxial actuator not only performs focus control and tracking control of the objective lens, but also performs tilt control.

The laser diodes 150 and 151 receive a drive signal from the drive control unit 108 and emit laser light to the optical disc 10.
The photodetector 154 receives the reflected light of the laser light reflected by the optical disc 10. The photodetector 154 converts the received laser light into an electrical signal and outputs the signal to the signal processing unit 110.

The spindle motor 104 receives a drive signal from the drive control unit 108. The spindle motor 104 rotationally drives a disk table (not shown) on which the optical disk 10 is placed at a predetermined speed.
The feed motor 106 receives a drive signal from the drive control unit 108. The feed motor 106 moves the optical pickup 102 in the radial direction (radial direction) of the optical disc 10 via the feed mechanism. When the optical pickup 102 is moved to a predetermined position, recording and reproduction of predetermined data can be performed.

The drive control unit 108 receives a tracking error signal and a focus error signal from the system controller 114 and generates a drive signal related to driving of the biaxial actuator 118 of the optical pickup 102. The drive control unit 108 sends the generated drive signal to the biaxial actuator 118 of the optical pickup 102.
Further, the drive control unit 108 receives a control signal from the system controller 114 and generates drive signals related to driving of the laser diodes 150 and 151, the spindle motor 104, and the feed motor 106 of the optical pickup 102. The drive control unit 108 sends the generated drive signal to the laser diodes 150 and 151, the spindle motor 104, and the feed motor 106.

  The signal processing unit 110 receives an output signal based on the reflected light of the laser light from the optical pickup 102. The signal processing unit 110 performs signal processing such as converting the received signal from an analog signal to a digital signal and amplifying the signal. The signal processing unit 110 sends a signal generated by signal processing to the signal modulation / demodulation unit 112 and the drive control unit 108.

  The signal modulation / demodulation unit 112 receives a signal from the signal processing unit 110 and performs signal demodulation processing during data reproduction. Further, the signal modulation / demodulation unit 112 performs signal modulation processing based on a signal received from the outside during data recording, and sends the processed signal to the signal processing unit 110.

The system controller 114 performs input / output of signals with the operation unit 116. Further, the output signal output from the signal modulation / demodulation unit 112 is input to the system controller 114. The system controller 114 generates a tracking error signal and a focus error signal based on the output signal output from the signal modulation / demodulation unit 112. The system controller 114 sends the generated tracking error signal and focus error signal to the drive control unit 108.
Further, the system controller 114 generates control signals for controlling the laser diodes 150 and 151, the spindle motor 104, and the feed motor 106 based on the output signal output from the signal modulation / demodulation unit 112. The system controller 114 sends the generated control signal to the drive control unit 108.

  Hereinafter, the operation of the optical disc apparatus 100 having the above configuration will be described. At the time of data recording, digital data input from an external computer (not shown) through an interface is modulated by an error correction code (ECC) added by the signal modulation / demodulation unit 112. Based on the modulated digital data, pulses are generated by a drive control unit 108 that controls laser light, and the optical disk 10 is irradiated with laser light via the optical pickup 102, whereby digital data is recorded. Further, servo control is appropriately performed by the drive control unit 108.

  On the other hand, at the time of data reproduction, when the optical disc 10 is irradiated with laser light, the return reflected light is detected by the photodetector 154 of the optical pickup 102. The reflected light detected by the photodetector 154 is amplified, waveform equalized, and the like calculated by the signal processing unit 110, the reproduced signal is reproduced, and a bit string in which the reproduced signal is binarized is generated. The generated bit string is subjected to signal demodulation and error correction by the signal modulation / demodulation unit 112. The demodulated signal is separated into video data and audio data by video / audio processing in the system controller 114, and is subjected to D / A conversion and analog output. During the data reproduction, the drive control unit 108 performs servo control as appropriate.

  Next, the configuration of the optical pickup 102 according to the present embodiment will be described with reference to FIGS. FIG. 2 is a plan view showing the optical pickup 102 according to this embodiment. FIG. 3 is a side view showing the optical pickup 102 according to the present embodiment. FIG. 4 is a perspective view showing the optical pickup 102 according to the present embodiment.

  2 to 4, the optical pickup 102 includes, for example, a biaxial actuator 118, optical components (for example, laser diodes 150 and 151, a prism 152, a return optical element 153, a photodetector 154, a collimator, and the like. Lens 155, reflection mirror 156, objective lenses 160, 161, etc.).

  The optical pickup 102 is configured by arranging two systems of optical components in parallel with respect to one biaxial actuator 118. Thereby, for example, laser beams having different wavelengths can be irradiated, and two standards such as a DVD and a Blu-ray disc can be recorded and reproduced by one optical disc apparatus 100.

  In FIGS. 2 to 4, the arrangement configuration of the two systems of optical components is shown to be symmetric, but the present invention is not limited to such an example. Other arrangement configurations may be used as long as the optical pickup 102 can read data from the optical disc 10 and write data on the optical disc 10 in two systems.

  The laser diodes 150 and 151 irradiate laser light in the direction of the reflection mirror 156 via the prism 152 and the collimator lens 155. Laser light emitted from the laser diode 151 is focused on the optical disc 10 through the objective lenses 160 and 161. The laser diode 151 irradiates laser light having a shorter wavelength than the laser diode 150, for example. For example, the laser diode 150 irradiates a laser beam corresponding to an optical disc such as a DVD, and the laser diode 151 irradiates a laser beam corresponding to a high-density recording optical disc such as a Blu-ray disc. The laser diodes 150 and 151 may irradiate laser light having the same wavelength.

The prism 152 transmits the laser light emitted from the laser diodes 150 and 151 and guides the laser light to the collimator lens 155. The prism 152 reflects the reflected light reflected by the optical disc 10 by, for example, about 90 °, and guides the reflected light to the return optical element 153.
The return optical element 153 is, for example, a condensing lens, and condenses the reflected light on the photodetector 154. The photodetector 154 receives the reflected light and converts the received light into an electrical signal.

The collimator lens 155 changes the laser light from the laser diodes 150 and 151 from divergent light to parallel light.
The reflection mirror 156 is an example of a reflection member, and an inclined surface is formed on the laser diode 150 or the laser diode 151 side. Most of the laser light emitted from the laser diodes 150 and 151 is reflected by 90 ° and guided toward the optical disk 10. The reflection mirror 156 is disposed below the objective lenses 160 and 161.

  The objective lens 160 is a condensing lens corresponding to the laser light emitted from the laser diode 150, and the objective lens 161 is a condensing lens corresponding to the laser light emitted from the laser diode 151. For example, when the laser diode 151 emits laser light having a shorter wavelength than the laser diode 150, the diameter of the objective lens 161 is shorter than that of the objective lens 160.

  The objective lenses 160 and 161 are provided on one end side of the lens holder 120, and drive coils 125 and 126 are provided on the other end side of the lens holder 120. Therefore, the position where the reflection mirror 156 can be installed can be closer to the objective lenses 160 and 161 than when the drive coils are provided on both sides of the objective lens. As a result, the distance between the installation positions of the laser diodes 150 and 151 and the installation positions of the objective lenses 160 and 161 can be shortened, so that the thickness of the optical pickup 102 can be reduced.

  The objective lenses 120 and 121 are disposed on the lens holding portion 121 in a direction substantially perpendicular to the direction connecting the lens holding portion 121 and the drive receiving portion 122. The objective lenses 120 and 121 are provided so as to be substantially parallel to the radial direction of the optical disc.

  The optical components of the optical pickup 102 are not limited to the optical components described above, and may include other components. The optical component may have another configuration as long as it can irradiate the optical disc 10 with laser light and receive reflected light from the optical disc 10.

  Next, the biaxial actuator 118 will be described. As shown in FIGS. 2 to 4, the biaxial actuator 118 includes, for example, a lens holder 120 that holds the objective lenses 160 and 161 and the drive coils 125 and 126, a magnet 132, and a suspension 142 that suspends the lens holder 120. The suspension fixing member 140 for fixing and supporting the suspension 142 is included.

  The lens holder 120 is an example of a lens support member, and holds the objective lenses 160 and 161 on the upper surface on one end side. The lens holder 120 is provided with two through holes (not shown), and the objective lenses 160 and 161 are provided on the two through holes, respectively. As a result, the laser light emitted from the laser diodes 150 and 151 passes through the objective lenses 160 and 161 through the through holes and is irradiated onto the optical disc 10.

  The lens holder 120 is provided with through holes 123 and 124 (see FIG. 6) through which the magnet 132 passes, on the other end side opposite to the objective lenses 160 and 161. Drive coils 125 and 126 are installed on the inner surfaces of the through holes 123 and 124. The lens holder 120 is suspended by the suspension 142 via the connecting portion 127. The connecting portion 127 is provided on the side surface of the lens holder 120. The lens holder 120 of the present embodiment is provided such that the direction connecting the two magnets 132 is substantially perpendicular to the radial direction of the optical disc 10.

  The suspension 142 is a wire, for example, and is an elastic member. The suspension 142 has one end connected to the connecting portion 127 and the other end connected to the suspension fixing member 140. The suspension 142 elastically suspends the lens holder 120 via the connecting portion 127. The suspensions 142 are provided in pairs with the lens holder 120 interposed therebetween, and for example, as shown in FIGS. 3 and 4, two suspensions 142 are provided in the vertical direction on one side.

  The suspension 142 exhibits elastic performance as an elastic member. The suspension 142 bends with the suspension fixing member 140 side as a fixed end and the lens holder 120 side as a free end. By making the length of the suspension 142 longer than a predetermined value, the moving direction of the lens holder 120 can be made linear.

  The suspension fixing member 140 is disposed on the opposite side of the objective lenses 160 and 161 with the magnet 132 interposed therebetween. Suspension 142 is connected to both ends of suspension fixing member 140. The suspension fixing member 140 is connected and fixed to, for example, the base plate of the optical pickup 102, and stably supports the suspension 142.

Next, the magnet 132 and the lens holder 120 of the biaxial actuator 118 will be described in detail.
FIG. 5 is a perspective view showing the magnet 132 and the magnet fixing portion 130 according to the present embodiment. FIG. 6 is a top view showing the lens holder 120 according to the present embodiment, and shows the side on which the objective lenses 160 and 161 are placed in the lens holder 120. FIG. 7 is a side view showing the lens holder 120 according to the present embodiment. FIG. 8 is a bottom view showing the lens holder 120 according to the present embodiment, and shows the opposite surface of the lens holder 120 shown in FIG. FIG. 9 is a perspective view showing the lens holder 120 according to the present embodiment, and is a view of the lens holder 120 as seen from the upper surface shown in FIG. FIG. 10 is a perspective view showing the lens holder 120 according to the present embodiment, and is a view of the lens holder 120 as seen from the lower surface shown in FIG.

  The lens holder 120 includes two regions: a lens holding part 121 that holds two objective lenses 160 and 161 and a drive receiving part 122 provided with two through holes 123 and 124.

  First, the magnet 132 and the drive coils 125 and 126 will be described. The magnet 132 and the drive coils 125 and 126 are provided facing each other, and drive the lens holder 120 in the focus direction or the tracking direction. The two magnets 132 are provided such that the direction connecting the two magnets 132 is substantially perpendicular to the radial direction of the optical disc 10.

The magnet 132 is an example of a first magnet and a second magnet. In the present embodiment, two magnets 132 are provided as shown in FIG. As shown in FIGS. 2 to 4, the two magnets 132 are inserted into the through holes 123 and 124 (see FIG. 6) of the lens holder 120, respectively.
The magnet 132 is fixed to the yoke 131 on the surface opposite to the surface facing the drive coils 125 and 126. In the present embodiment, the two magnets 132 and the yoke 131 that fixes the magnets 132 constitute one unit as the magnet fixing portion 130. The magnet fixing unit 130 is connected and fixed to the base plate of the optical pickup 102, for example.
The magnet 132 has a configuration that is normally applied to a biaxial actuator in which the magnet and the drive coil face each other, and detailed description of the magnetization of each magnet 132, the direction of the lines of magnetic force, and the like is omitted.

  Two through holes 123 and 124 are formed in the drive receiving portion 122. The two through holes 123 and 124 are formed in parallel in the direction connecting the drive receiving portion 122 and the lens holding portion 121. The through holes 123 and 124 penetrate the objective lenses 160 and 161 in the optical axis direction of the laser light. The drive receiving portion 122 is provided with drive coils 125 and 126, and receives a driving force for driving the lens holding portion 121 generated by driving the drive coils 125 and 126 and the action of the magnet 132. The through hole 123 is an example of a first through hole, and the through hole 124 is an example of a second through hole.

  The drive coil 125 is a focusing drive coil, and when the drive coil 125 is driven, the focusing direction of the objective lenses 160 and 161 (the optical axis direction of the laser light passing through the objective lenses 160 and 161) is controlled. The drive coil 125 is disposed on the inner surface of the through hole 123 formed in the lens holder 120. The drive coil 125 is wound along the four inner surfaces of the through-hole 123, and one of the two magnets 132 is inserted into the center of the drive coil 125. The drive coil 125 is an example of a first coil.

  The drive coil 126 is a tracking drive coil, and when the drive coil 126 is driven, the objective lenses 160 and 161 are controlled in the tracking direction (radial direction of the optical disc 10). The drive coils 126 are arranged one by one in the tracking direction on one of the inner surfaces of the through holes 124 formed in the lens holder 120. The drive coils 125 and 126 have a configuration normally applied to a biaxial actuator. Each of the drive coils 125 and 126 is formed by winding a metal wire such as a copper wire. The drive coil 126 is an example of a second coil.

  The operation of the biaxial actuator 118 according to this embodiment is as follows. That is, the biaxial actuator 118 inputs the focus drive signal to the drive coils 125 and 126, thereby moving the lens holder 120 in the focus control direction (focusing direction, that is, the traveling direction of laser light in the objective lenses 160 and 161). To drive. Further, the biaxial actuator 118 drives the lens holder 120 in the tracking direction when a tracking drive signal is input to the drive coil 125.

Next, the lens holding part 121 of the lens holder 120 will be described in detail.
The lens holder 120 is provided with a lens holding portion adjacent to one end side of the drive receiving portion 122, for example, the through hole 124. The lens holding unit 121 is an example of a holding unit, and holds the objective lenses 160 and 161. The lens holding part 121 is a plate-like member, for example. As shown in FIGS. 6 and 9, a concave portion 128 is formed around the objective lenses 160 and 161 on the upper surface of the lens holding portion 121. An adhesive or the like for fixing the objective lenses 160 and 161 to the lens holder 120 is disposed in the recess 128. In the lens holding part 121, the objective lenses 160 and 161 are juxtaposed in the radial direction of the optical disc 10.

  In the lens holder 120, the objective lenses 160 and 161 are installed so that the surplus portion 121 </ b> A is provided on the opposite side of the drive receiving portion 122 across the objective lenses 160 and 161. The surplus portion 121A may have the same plate thickness as the lens holding portion or a different thickness. The lens holding part 121 is formed leaving a surplus portion 121 </ b> A so as to have a predetermined length from one end of the lens holder 120 to the end parts of the objective lenses 160 and 161.

  That is, in the lens holder 120, the objective lenses 160 and 161 are arranged on the plane of the lens holding portion 121 so as to be biased toward the drive receiving portion 122 compared to the diameter of the objective lenses 160 and 161. In other words, in the lens holder 120, a part of the member of the lens holding portion 121 is provided extending from the end of the objective lenses 160 and 161 toward the one end of the lens holder 120.

The predetermined length of the surplus portion 121 </ b> A is determined by the secondary resonance vibration that propagates in the direction connecting the lens holding portion 121 and the drive receiving portion 122 generated in the lens holder 120. That is, the objective lenses 160 and 161 are arranged on the lens holding portion 121 so that the portion of the secondary resonance vibration generated in the lens holder 120 is the center of the objective lenses 160 and 161.
As a result, when secondary resonance occurs in the lens holder 120, the center of the objective lenses 160 and 161 coincides with the portion of the vibration node caused by the secondary resonance, so that movement of the objective lenses 160 and 161 due to vibration is reduced. Can do.

  A protrusion 121B may be further provided at one end of the surplus portion 121A. By providing the protrusion 121 </ b> B, the position of a vibration node due to secondary resonance can be adjusted, and the balance of the lens holder 120 can be adjusted.

  With reference to FIG. 11, the secondary resonance occurring in the lens holder 120 will be described. FIG. 11 is a side view showing a conventional lens holder 20 and a schematic diagram showing vibration due to secondary resonance. In FIG. 11, drive coils 25 and 26 and an objective lens 60 are provided in a conventional lens holder 20. Moreover, the part corresponding to the surplus part 121A of the lens holder 120 of this embodiment is shown with the virtual line (two-dot chain line) at the one end side of the conventional lens holder 20 of FIG.

  When vibration due to secondary resonance occurs in the conventional lens holder 20, normally, the portion of the vibration due to secondary resonance does not coincide with the center of the objective lenses 60 and 61, as shown in the schematic diagram of vibration in the upper stage. . Therefore, when secondary resonance occurs in the lens holder 20, an amplitude is generated at the center of the objective lenses 60 and 61.

  In this embodiment, the objective lens is moved to the vibration node due to the secondary resonance. However, when the objective lens is moved to the node portion, the entire length of the entire lens holder cannot be shortened. This is because if the entire length of the entire lens holder is shortened, the position of the node also moves as shown in the schematic diagram of vibration shown in the middle part of FIG.

  Therefore, it is only necessary that the centers of the objective lenses 60 and 61 can be moved while keeping the entire length of the conventional lens holder 20 as it is. However, even if it is attempted to move the centers of the objective lenses 60 and 61 while keeping the entire length of the conventional lens holder 20, it is impossible to make the node portions coincide with the centers of the objective lenses 60 and 61. Since one end side of the lens holding portion where the objective lenses 60 and 61 are held is provided with a through hole in which the magnet penetrates and the drive coil 26 is provided, the distance that the objective lenses 60 and 61 can move is provided. Because there is a limit.

  For example, consider the case of the lens holder 20 that holds the objective lenses 60 and 61 having a diameter of about 3 mm. At this time, according to the simulation result, in the conventional lens holder 20, if the objective lenses 60 and 61 can be moved by about 0.8 to 0.9 mm, the node portion is made to coincide with the center of the objective lenses 60 and 61. be able to. However, since a bonding margin of about 0.3 mm is required between the through hole and the objective lenses 60 and 61, the result is that only about 0.5 mm can be moved. For this reason, the node portion cannot coincide with the centers of the objective lenses 60 and 61.

  Therefore, in the present embodiment, as shown in the schematic diagram of vibration shown in the lower part of FIG. FIG. 12 shows a comparison of the total length of the conventional lens holder 20 and the lens holder 120 of the present embodiment and the position of the objective lens. FIG. 12 is a top view showing a conventional lens holder and a lens holder according to the present embodiment.

  The conventional lens holder 20 has substantially the same configuration as the lens holder 120 of this embodiment except for the surplus portion 121A. The lens holder 20 includes two regions, a lens holding unit 21 and a drive receiving unit 22. The lens holding unit 21 holds the objective lenses 60 and 61. The drive receiving portion 22 has through holes 23 and 24, a drive coil 25 is provided in the through hole 23, and a drive coil 26 is provided in the through hole 24.

  As shown in FIG. 12, when the drive coil 25 provided in the conventional lens holder 20 and the drive coil 125 provided in the lens holder 120 of the present embodiment are matched, the total length of the lens holder 120 is the conventional lens. It can be seen that it is elongated compared to the holder 20. Further, the centers of the objective lenses 160 and 161 are closer to the drive receiving portion 122 than the conventional objective lenses 60 and 61. As a result, in the lens holder 120 of this embodiment, when vibration due to secondary resonance occurs in the lens holder 120, the vibration node can coincide with the centers of the objective lenses 160 and 161.

  Consider the case of the lens holder 120 holding the objective lenses 160 and 161 having a diameter of about 3 mm. At this time, according to the simulation result, the length of the surplus portion 121A from the end portions of the objective lenses 160 and 161 to the one end portion of the lens holder 120 is set to 1.8 mm, so that the vibration node is the objective lenses 160 and 161. Could be matched with the center of.

  FIG. 13 shows the frequency characteristics of the conventional lens holder 20 and the frequency characteristics of the lens holder 120 of the present embodiment. As shown in FIG. 13A, in the lens holder 20, an amplitude (resonance peak) occurs around 10 kHz. The resonance peak of the lens holder 20 adversely affects the servo of the optical pickup. For this reason, a material that increases the resonance frequency or lowers the peak is selected. A material with high rigidity is selected to increase the resonance frequency, and a material with good damping is selected to reduce the peak. The index is determined by how much gain margin is taken from 1 kHz. A larger gain margin is advantageous because a higher servo cut-off can be obtained.

  The lens holder tends to be miniaturized, and if the condition that two objective lenses are held is satisfied, the gain margin cannot be increased only by selecting the material of the lens holder. Therefore, in this embodiment, in this case, paying attention to the shape of the lens holder 120 including the lens holding portion 121 and the drive receiving portion 122 that hold the objective lens, the vibration due to the secondary resonance generated in the lens holder 120 is the objective lens 160. , 161 so as not to affect the shape. Specifically, the surplus portion 121A is provided in the lens holding portion 121 so that the centers of the objective lenses 160 and 161 coincide with the portions of the vibration nodes. As a result, resonance occurred in the lens holder 120, but the resonance peak around 10 kHz could be eliminated as shown in FIG. The next resonance peak could be set to a higher frequency.

  By the way, it can be said that the length of the surplus portion 121A in the above example of 1.8 mm is longer than the length of the objective lenses 160 and 161 having a diameter of about 3 mm. In general, in designing and manufacturing a lens holder, the length from the end of the objective lens to one end of the lens holder may be about 0.5 to 1.0 mm in consideration of an adhesive margin or the like. In addition, when the objective lens can be brought closer to the drive receiving portion side of the lens holder, the surplus portion generated by the approach is scraped, and the overall length of the lens holder is generally shortened. If the overall length of the lens holder can be shortened, the distance between adjacent optical components such as a collimator lens and the lens holder can be shortened, and the entire optical pickup can be made compact in accordance with the recent trend toward miniaturization of optical disk devices. It is because it can be made.

  On the other hand, in the present embodiment, contrary to the shortening of shortening the total length of the lens holder, the total length of the lens holder 120 is increased and an extra portion 121A is provided on one end side of the lens holding portion 121 that holds the objective lenses 160 and 161. Is provided. As a result, the portion of the vibration node caused by the secondary resonance generated in the lens holder can coincide with the center of the objective lenses 160 and 161. And since the influence of the amplitude which arises in the objective lenses 160 and 161 can be reduced, the servo control of the optical pickup is improved, and the optical disc 10 can be irradiated with high precision with laser light.

  The surplus portion 121A of the lens holding portion 121 described above may also be referred to as a protruding portion provided to protrude from the minimum necessary space (the lens holding portion 121) on which the objective lenses 160 and 161 are placed. it can. At this time, in the lens holder 120 shown in FIGS. 6 to 10, the width of the lens holder 120 on the imaginary line connecting the centers of the objective lenses 160 and 161 is the same as the width of the protruding portion. On the other hand, the protruding portion may be different from the width of the lens holder 120 on the imaginary line connecting the centers of the objective lenses 160 and 161, and the protruding portion may be shorter or longer.

  The preferred embodiments of the present invention have been described in detail above with reference to the accompanying drawings, but the present invention is not limited to such examples. It is obvious that a person having ordinary knowledge in the technical field to which the present invention pertains can come up with various changes or modifications within the scope of the technical idea described in the claims. Of course, it is understood that these also belong to the technical scope of the present invention.

  For example, in the above embodiment, the end portion of the surplus portion 121A of the lens holder 120 is flat except for the portion where the protrusion 121B is provided. However, the present invention is not limited to such an example. For example, as shown in FIG. 14, a step portion may be provided at the end of the lens holder 220. FIG. 14 is a perspective view showing a modification of the lens holder according to the first embodiment of the present invention. That is, the length of the surplus portion 221B from the end of the objective lens 160 to one end of the lens holder 220 is different from the length of the surplus portion 121A from the end of the objective lens 161 to one end of the lens holder 220. Thereby, even when the objective lens 160 and the objective lens 161 held by the lens holder 220 have different diameters, the vibration node of the secondary resonance generated in the lens holder 220 and the center of the objective lenses 160 and 161 are matched. Can do.

1 is a block diagram showing a configuration of an optical disc device according to a first embodiment of the present invention. It is a top view which shows the optical pick-up concerning the embodiment. It is a side view which shows the optical pick-up concerning the embodiment. It is a perspective view which shows the optical pick-up which concerns on the same embodiment. It is a perspective view which shows the magnet and magnet fixing | fixed part which concern on the same embodiment. It is a top view which shows the lens holder which concerns on the embodiment, and shows the side by which the objective lens was mounted in the lens holder. It is a side view which shows the lens holder which concerns on the same embodiment. It is a bottom view which shows the lens holder which concerns on the same embodiment, and shows the surface opposite to the lens holder shown in FIG. It is the perspective view which shows the lens holder which concerns on the same embodiment, and is the figure which looked at the lens holder from the upper surface shown in FIG. FIG. 9 is a perspective view illustrating the lens holder according to the embodiment, and is a view of the lens holder as viewed from the lower surface illustrated in FIG. 8. It is the side view which shows the conventional lens holder, and the schematic diagram which shows the vibration by secondary resonance. It is a top view which shows the lens holder which concerns on the conventional lens holder and the 1st Embodiment of this invention. It is a graph which shows the frequency characteristic of the conventional lens holder, and the frequency characteristic of the lens holder of this embodiment. It is a perspective view which shows the modification of the lens holder which concerns on the 1st Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Optical disk 100 Optical disk apparatus 102 Optical pick-up 104 Spindle motor 106 Feed motor 108 Drive control part 110 Signal processing part 112 Signal modulation / demodulation part 114 System controller 116 Operation part 118 Two-axis actuator 120 Lens holder 121 Lens holding part 121A Surplus part 121B Protrusion part 122 Drive receiving portion 123, 124 Through hole 125, 126 Drive coil 132 Magnet 140 Suspension fixing member 142 Suspension 150, 151 Laser diode 152 Prism 153 Return optical element 154 Photo detector 155 Collimator lens 156 Reflection mirror 160, 161 Objective lens

Claims (9)

A holding unit for holding a plurality of objective lenses;
A lens support member that is provided only on one side of the holding portion and has a driving receiving portion that receives a driving force for driving the holding portion;
The center of the objective lens becomes a part of one of a plurality of nodes of vibration caused by secondary resonance propagating in a direction connecting the holding portion and the drive receiving portion generated in the lens support member,
The optical pickup device, wherein the holding portion is provided with an excess portion on the opposite side to the drive receiving portion. A holding unit for holding a plurality of objective lenses;
A lens support member that is provided only on one side of the holding portion and has a driving receiving portion that receives a driving force for driving the holding portion;
The center of the objective lens becomes a part of one of a plurality of nodes of vibration caused by secondary resonance propagating in a direction connecting the holding portion and the drive receiving portion generated in the lens support member,
The objective lens is disposed on the drive receiving portion side in the holding portion,
The optical pickup device, wherein the holding portion is formed leaving an excess portion having a predetermined length from one end of the holding portion to an end portion of the objective lens. A holding unit for holding a plurality of objective lenses;
A lens support member that is provided only on one side of the holding portion and has a driving receiving portion that receives a driving force for driving the holding portion;
The center of the objective lens becomes a part of one of a plurality of nodes of vibration caused by secondary resonance propagating in a direction connecting the holding portion and the drive receiving portion generated in the lens support member,
The optical pickup apparatus, wherein the lens support member further includes a projecting portion provided to project from the holding portion on a side opposite to the drive receiving portion with the holding portion interposed therebetween.   The at least two objective lenses among the plurality of objective lenses are arranged in the holding portion in a direction substantially perpendicular to a direction connecting the holding portion and the drive receiving portion. The optical pickup device described in 1. The drive receiving portion is
A first through hole penetrating in the optical axis direction of the light passing through the objective lens, the first magnet penetrating through the first coil facing the first magnet,
Provided between the holding portion and the first through-hole, the second magnet penetrates, the second coil is disposed on the inner surface facing the second magnet, and the optical axis direction of the light A second through hole penetrating into
The optical pick-up apparatus in any one of Claims 1-4 which has these. A light emitting element that emits light toward the optical disc;
A plurality of objective lenses capable of condensing the light on the optical disc through which the light passes;
A first magnet extending in the optical axis direction of the light passing through the objective lens;
A second magnet that is spaced apart from the first magnet and extends in the optical axis direction of the light;
A holding portion that holds the plurality of objective lenses, the first magnet penetrates, a first coil is disposed on the inner surface facing the first magnet, and the first magnet penetrates in the optical axis direction of the light. 1 is provided between the through hole, the holding portion and the first through hole, the second magnet passes therethrough, and the second coil is disposed on the inner surface so as to face the second magnet. A lens support member having a second through hole penetrating in the optical axis direction of the light,
The center of the objective lens becomes a part of one of a plurality of nodes of vibration caused by secondary resonance propagating in a direction connecting the holding portion and the drive receiving portion generated in the lens support member,
An optical disc apparatus, wherein the holding portion is provided with an excess portion on the opposite side to the drive receiving portion. A reflection member that is provided on the light incident side of the objective lens and reflects the light emitted from the light emitting element;
The optical disc apparatus according to claim 6, wherein the light emitted from the light emitting element is reflected substantially vertically by the reflecting member and is incident on the objective lens.   The optical disk according to claim 6, wherein the lens support member is provided so that a direction connecting the first magnet and the second magnet is substantially perpendicular to a radial direction of the optical disk. apparatus. 9. The optical disc apparatus according to claim 6, wherein at least two of the plurality of objective lenses are provided so as to be substantially parallel to a radial direction of the optical disc.

Images