The present invention relates an optical component positioning device in an optical recording device using a recording medium in the form of flat plate, and an optical recording device using that optical component positioning device.
Recently, the capacity of an optical disk as one of main information recording media has been increasing with increase in the amount of electronic information that accompanies the spread of the Internet, improvement of an image quality, and the like. The increase in the capacity has been achieved as a CD, a DVD, and a BD by reduction in the size of a converged spot by increasing numerical aperture of an objective lens and shortening of a waveform of a light beam (rays) and multilayered recording layers, for example. However, a new storage technique different from the conventional techniques is required for achieving further increase in the capacity.
A hologram memory is known as a promising next generation technology of optical storages. In general, in the hologram memory, the intensity of a signal light beam (rays) is two-dimensionally modulated by a spatial light modulator (SLM). The signal light beam is made to interfere with a reference light beam, so that a pattern of the interference is fixed in a disk-shaped recording medium (an optical disk) as distribution of refractive index. In this manner, information is recorded. In addition, a plurality of kinds of information can be simultaneously recorded to one recording portion by changing an angle of incidence of the reference light beam on the recording medium.
In reproduction of information in the hologram memory, when the reference light beam used in recording is radiated onto the recording medium at the same angle as that in recording, diffracted light is generated from the interference pattern fixed in the recording medium. The recorded information is reproduced by receiving the diffracted light with an optical detector. In this manner, the hologram memory allows a plurality of kinds of two-dimensional information to be recorded and reproduced to/from one recording portion, and therefore enables recording and reproduction of the information with high density at a high speed.
Patent Literatures 1 and 2 describe examples of a driving device that switches an optical component for recording and an optical component for reproduction or controls a position of a converged point of a light beam three-dimensionally for two different conditions of use, for example, for recording and for reproduction described above, in a manner appropriate to those conditions.
Patent Literature 1 describes an objective lens driving device and an optical head device for performing recording and reproduction for a plurality of different kinds of optical information recording media that are different in a substrate thickness, recording sensitivity, or the like with a single optical information recording/reproducing apparatus. To achieve this, the objective lens driving device and the optical head device are configured to make a light spot converged onto an information recording surface of each optical information recording medium most appropriate for that medium, and to accurately control a track shift and a focus shift. More specifically, Patent Literature 1 describes the objective lens driving device including a lens holder held to be movable around an axial line and be movable up and down along the axial line, a plurality of objective lenses provided in the lens holder at positions away from the axial line with approximately equal distances from the axial line, a driving device that moves the lens holder up and down along the axial line and around the axial line to drive a light spot on the optical information recording medium in a focus direction and in a direction crossing tracks, and means that determines the kind of the optical information recording medium, wherein, in the objective lens driving device, one of the objective lenses is selected in accordance with the type of the optical information recording medium and is moved into a light bundle to form the light spot, so that information is recorded or reproduced. Patent Literature 1 also describes the optical head device including that objective lens driving device.
Patent Literature 2 describes an optical head including a first lens that converges a collimated light beam from a light source unit, a second lens that converts the converged light beam to a collimated light beam again, and a third lens that converges the collimated light beam onto a recording surface of an optical disk. The optical head performs adjustment of a focus position of the light beam by moving the third lens in its optical axis direction, and performs tracking control of the light beam by moving one of the first lens and the second lens in a plane perpendicular to its optical axis to incline the optical axis of the light beam incident on the third lens. In the optical head, one of the first lens and the second lens is attached to a first movable member supported by a first plate spring pivotally movable only in a plane perpendicular to the optical axis of the one of the first and second lenses, and the third lens is attached to a second movable member supported by a second plate spring pivotally movable only in a plane perpendicular to the tracking direction. It is described that due to this configuration, a position of a converged point of a light beam transmitted through the lens is moved in a normal plane with respect to the optical axis of the light beam by moving the lens in the normal plane with respect to the optical axis, and is moved in the optical axis direction by moving the objective lens in the optical axis direction.
In an optical recording device using a recording medium in the form of flat plate, for example, the hologram memory described above, a position or an angle of the recording medium with respect to a position of a reference light beam is changed while the recording medium in the form of flat plate is rotating, because of specific deflection, vibration, or the like of the recording medium. With this change of the position or the angle, a position or an angle of reproducing light (i.e., diffracted light) generated by the recording medium in reproduction is changed, so that a position of a converged point of the reproducing light converged on an optical component, for example, a spatial filter, arranged in an optical path between the recording medium and the optical detector is three-dimensionally changed. When the position of the converged point of the reproducing light is changed on the spatial filter, the reproducing light is blocked by the spatial filter, causing reduction in the light amount of the reproducing light converged on the optical detector and preventing a satisfactory level of a reproducing signal from being obtained. Therefore, there is a problem that the spatial filter has to be moved to the most appropriate position in synchronization with the position or the angle of the recording medium.
On the other hand, when recording is performed by the optical recording device using the recording medium in the form of flat disk such as the hologram memory described above, it is necessary to fix the position of the optical component such as the spatial filter to the center of the signal light beam irrespective of the position of the recording medium for removing unnecessary frequency components or the like contained in the signal light beam emitted from a light source. Further, there is a problem that the position of the spatial filter has to be fixed accurately, although it is difficult to continuously acquire position information of the spatial filter by using the signal light beam transmitted through the spatial filter and continuously perform feedback control of the position of the spatial filter because the signal light beam is radiated discretely and discontinuously for a short period of time in recording.
However, the configuration of the driving device for the optical head in Patent Literature 1 only enables driving of the position of the converged point of the light beam in a direction along one axis on the normal plane with respect to the optical axis by switching the optical components by means of an actuator driven along the one axis on the normal plane with respect to the optical axis, and driving of it in the normal direction by an actuator driven along the optical axis direction. In other words, the position of the converged point of the light beam can be driven only in two axial directions. Further, because the driving device uses the principle of electromagnetic driving, the positioning state is unstable and it is therefore difficult to fix the optical component during recording.
On the other hand, in the configuration of Patent Literature 2, the position of the converged point of the light beam can be three-dimensionally driven to an arbitrary position. However, when the lens is displaced from the center of the optical axis for driving the position of the converged point of the rays, distortion of the light beam is caused, thus degrading a recording/reproducing signal. Furthermore, because the driving device uses the principle of electromagnetic driving, the positioning state is unstable and it is therefore difficult to fix the optical component during recording. In addition, the configuration of Patent Literature 2 also has a problem that driving for switching the optical components between recording and reproduction cannot be performed.
The present invention has been made in view of the above-described problems, and aims to provide an optical component positioning device that can switch optical components such as spatial filters, between recording and reproduction, can move the optical component to the most appropriate position in synchronization with a position or an angle of a recording medium, and can accurately fix the position of the optical component such as the spatial filter when fixing is required, for example, during recording, and to provide an optical recording device using that optical component positioning device.
The present invention can be understood from a plurality of aspects. According to one aspect, a typical optical component positioning device of the present invention and an optical recording device using it are as follows. Further, the optical component positioning device of the present invention and the optical recording device using it according to another aspect will be more apparent by the following description of embodiments of the invention and the like.
The optical component positioning device of the present invention is an optical component positioning device that moves at least two optical components arranged in an optical path of a light beam emitted from a light source to position them at predetermined positions, and includes a first actuator on which the two optical components are mounted and which moves the two optical components together and is driven along one axis, a second actuator on which a first optical component of the two optical components is mounted and which moves the first optical component independently of another second optical component and is driven along two or more axes, and a control device which controls the first actuator and the second actuator.
The optical recording device of the present invention using the above optical component positioning device is an optical recording device including a rotary motor driving a recording medium mounted thereon to rotate and a head recording and reproducing a signal to/from the recording medium. The recoding/reproducing head has at least two optical components arranged in an optical path of a light beam emitted from a light source. The head also includes an optical component positioning device including a first actuator on which the two optical components are mounted and which moves the two optical components together and is driven along one axis, a second actuator on which a first optical component of the two optical components is mounted and which moves the first optical component independently of another second optical component and is driven along two or more axes, and a control device controlling the first actuator and the second actuator.
According to the present invention, it is possible to provide an optical component positioning device that can suppress degradation of a reproducing signal caused by deflection of a recording medium (an optical disk) or a shift of the recording medium caused by vibration during rotation of the recording medium in a direction of a rotation axis and in a direction within a normal plane with respect to the rotation axis, and to provide an optical recording device using that optical component positioning device. Thus, it is also possible to provide a high-density and high-speed hologram memory.
a) is a diagram explaining an operation example of a displacement correction mechanism 402 when a position of a recording medium is shifted in an embodiment of the present invention;
b) is a diagram explaining another operation example of the displacement correction mechanism 402 when the position of the recording medium is shifted in the embodiment of the present invention;
b) is a diagram showing a configuration of a two-axis actuator 404 of the displacement correction mechanism 402 in the embodiment of the present invention;
a) is a diagram explaining the configuration and an operation of the two-axis actuator 404 of the displacement correction mechanism 402 in the embodiment of the present invention;
c) is a diagram explaining another example of the relation between the driving force and the displacement in the two-axis actuator 404 of the displacement correction mechanism 402 in the embodiment of the present invention;
a) is a diagram explaining a configuration of an optical component switching mechanism of the displacement correction mechanism 402 and an operation thereof during recording in the embodiment of the present invention;
An optical recording device according to an embodiment of the present invention includes a rotary motor driving a recording medium mounted on the optical recording device to rotate, and a head recording and reproducing a signal to/from the recording medium, for example. The recording/reproducing head includes at least two optical components, and has an optical component positioning device that performs position control for the two optical components with a common one-axis actuator and performs position control for one of the two optical components with an actuator driven along two or more axes in such a manner that the one optical component moves independently of another optical component.
In the optical component positioning device and the optical recording device using the same according to the embodiment of the present invention, the common one-axis actuator switches the two optical components.
In the optical component positioning device and the optical recording device using the same according to the embodiment of the present invention, a position of the common one-axis actuator is fixed when no current is supplied thereto.
In the optical component positioning device and the optical recording device using the same according to the embodiment of the present invention, the recording medium mounted on the optical recording device is rotatable, and the one-axis actuator moves in such a manner that a position on the recording medium at which rays transmitted through the optical component positioning device are incident on the recording medium moves in a normal direction with respect to a rotation axis of the recording medium.
In the optical component positioning device and the optical recording device using the same according to the embodiment of the present invention, the optical components change intensity, polarization, and an angle of the rays transmitted therethrough.
The optical component positioning device and the optical recording device using the same according to the embodiment of the present invention has a function of detecting a position of the rays transmitted through the optical component.
Embodiments of the present invention are described in detail below, with reference to the drawings. The following description is intended to indicate the embodiments of the present invention, but is not intended to limit the present invention to the embodiments. The present invention can be changed or modified by those skilled in the art in various ways within the scope of the technical spirit disclosed in the present specification. Throughout the drawings for explaining the embodiments and specific examples, components having the same function are labeled with the same reference sign and the redundant description thereof may be omitted.
A light beam (rays) emitted from a light source 201 is transmitted through a collimate lens 202. At a shutter 203, a time period in which the light beam passes therethrough is limited. After passing through the shutter 203, the light beam is subjected to control of a ratio of P-polarized light and S-polarized light in a half-wave plate 204 and is thereafter incident on a polarized beam splitter 205. A signal light (for example, a P-polarized light) beam 301 transmitted through the polarized beam splitter 205 is enlarged in its diameter by a beam expander 206, is thereafter transmitted through a phase mask 207 and a relay lens 208, is reflected by a polarized beam splitter 209, and is incident on a spatial light modulator 210. The signal light beam 301 to which information is added by the spatial light modulator 210 is transmitted through the polarized beam splitter 209, is then transmitted through a relay lens 211, a spatial filter 212, and an objective lens 213, and is converged onto a recording medium 224.
A reference light (for example, an S-polarized light) beam 302 reflected by the polarized beam splitter 205 is subjected to control in a polarized direction conversion element 214 to have a polarized direction in accordance with recording or reproduction, is then reflected by a mirror 215 and a mirror 216, and is radiated onto a galvano mirror 217. A reflection angle of the reference light beam 302 is controlled by the galvano mirror 217, and thereafter the reference light beam 302 is transmitted through a lens 218 and a lens 219 and is then incident on the recording medium 224. An angle of incidence of the reference light beam 302 on the recording medium 224 is adjusted by controlling the angle of the reference light beam 302 by the galvano mirror 217.
When the signal light beam 301 and the reference light beam 302 are superimposed in the recording medium 224, an interference pattern formed by the signal light beam 301 and the reference light beam 302 is recorded within the recording medium 224, by which information is recorded. When the angle of the reference light beam 302 incident on the recording medium 224 is changed by the galvano mirror 217, recording depending on the angle of incidence can be achieved. Therefore, recording in angular multiplexing can be achieved.
When the information recorded in the recording medium 224 is reproduced, a light beam emitted from the light source 201 is adjusted in the aforementioned half-wave plate 204 to have one of the P-polarized light and the S-polarized light that is used as the reference light in such a manner that the whole amount of the light beam forms a reference light (for example, an S-polarized light) beam 302 that is to be reflected by the polarized beam splitter 205. The reference light beam 302 is incident on the recording medium 224 by passing through the components in the same order as that for the aforementioned reference light beam 302, is transmitted through the recording medium 224, and is then reflected by a galvano mirror 220. When the reference light beam 302 reflected by the galvano mirror 220 is incident on the recording medium 224 again, reproduction light diffracted by the interference pattern recorded in the recording medium 224 is generated. The reproduction light is transmitted through the objective lens 213, the relay lens 211, and the spatial filter 212, and is then reflected by the polarized beam splitter 209 to be incident on an optical detector 221 in which a recorded signal is reproduced. The galvano mirror 217 and the galvano mirror 220 are moved in conjunction with each other, so that the reference light beam 302 can be incident on the recording medium 224 at a plurality of angles of incidence that are the same as those during recording. Therefore, information recorded in a multiplexing manner can be reproduced.
The recording medium 224 is fixed to a rotary motor 222 via a rotation shaft 223, and the rotary motor 222 is fixed onto a stage 226. Thus, a position in the recording medium 224 at which recording/reproduction is performed can be set in an arbitrary manner by controlling a rotation angle with the rotary motor 222 and positions in X-, Y-, and Z-axis directions with the stage 226 through control with a control device (controller) 227 of the optical recording device.
The control device (hereinafter, referred to as the controller) 227 performs various types of control of the optical head 401. For example, the controller 227 controls emission of the light beam from the light source, the angles of the galvano mirrors 217 and 220, and the position of the spatial filter 212 in accordance with a signal of detected light in the optical detector 221.
Next, an operation of a displacement correction mechanism 402 is described when the position of the recording medium 224 is shifted or the recording medium 224 is inclined.
In
a) is a diagram explaining an operation of the displacement correction mechanism 402 in reproduction of information recorded in the recording medium 224 in this embodiment, in a case where the recording medium 224 is shifted toward a direction of one axis (+X′-axis direction) on a normal plane with respect to the optical axis of the signal light beam 301 used in recording. The position shown with dotted line is the original position of the recording medium 224.
c) is a diagram explaining an operation of the displacement correction mechanism 402 in a case where the recording medium 224 is inclined (in +θγ′ direction) with respect to the optical axis of the signal light beam 301 used in recording in this embodiment. The position shown with dotted line is the original position of the recording medium 224.
As shown in
As shown in
Finally, when the recording medium 224 is inclined (in +θγ′ direction) with respect to the optical axis of the signal light beam 301 used in recording as shown in
Next, a specific operation of the displacement correction mechanism 402 controlling the position of the spatial filter 212 is described.
As shown in
a) is a diagram explaining a configuration of the displacement correction mechanism 402.
The displacement correction mechanism 402 has two spatial filters 212a and 212b. The spatial filter 212a is fixed to a one-axis (X′-axis) driving holder 103, and the spatial filter 212b is fixed to a two-axis (Y′-axis and Z′-axis) driving holder 107.
First, an operation of the two-axis actuator 404 is described below.
a) is a diagram for explaining the operation of the actuator 404 driven along two axes formed by an electromagnetically driven actuator, in which main components of the actuator 404 driven along two axes (hereinafter, referred to as a two-axis actuator) are seen toward −Z-axis direction.
b) and 4(c) are diagrams for explaining driving forces generated in the two-axis actuator 404 in the optical axis direction (Z′-axis direction) and the one axial direction (Y′-axis direction) on the normal plane with respect to the optical axis, respectively, in which the two-axis actuator 404 is seen toward +X-axis direction in a cross section S2 in
In the two-axis actuator 404, two types of coils 111 and 112 fixed to the two-axis driving holder 107 are arranged in a magnetic field formed by magnets 110 and yokes 109 provided outside the holder 107, as shown in
As shown in
On the other hand, two pairs of coils 112 for the normal direction of the optical axis are arranged in gaps between the magnets 110 and the yokes 109, and are fixed on two surfaces of the two-axis driving holder 107 in an axial direction of the wires 108. As shown in
The two-axis actuator 404 controls the position in Y′-axis direction and that in Z′-axis direction of the spatial filter 212b with the currents applied to the coils 111 and 112 in accordance with the above operation principle.
Next, an operation of the actuator driven along one axis (hereinafter, the one-axis actuator) 403 is described below.
The one-axis actuator 403 that can be driven at a relatively low speed is formed mainly by a stepping motor 100, a lead screw 101, a nut 102, and two guide rails 104 and 105, as shown in
When the stepping motor 100 rotates around X′-axis, the nut 102 fixed to the one-axis driving holder 103 and the one-axis driving holder 103 are displaced in X′-axis direction that is an axial direction of the two guide rails 104 and 105. Because the stepping motor 100 has such characteristics that a rotation angle of the lead screw 101 is maintained while no current is supplied to the stepping motor 100, the position of the one-axis driving holder 103 is fixed.
Based on the above operation principle, the one-axis actuator 403 controls the positions in X′-axis direction of the spatial filter 212a and the spatial filter 212b that are mounted on the one-axis driving holder 103 by the number of pulses of a voltage applied to the stepping motor 100. Further, the one-axis actuator 403 is used not only for minute position control for the spatial filter 212a and the spatial filter 212b but also for switching of the spatial filter 212a and the spatial filter 212b during recording and reproduction.
As shown in
During reproduction, as shown in
The two-axis actuator 404 and the one-axis actuator 403 in this embodiment are described as being electromagnetically driven and being driven by a motor, respectively. However, an actuator such as an ultrasonic motor, can be used as the one-axis actuator 403, so long as it can provide the same effects.
In this embodiment, a case is described where the displacement correction mechanism 402 is used in the hologram memory device. However, the displacement correction mechanism 402 can be applied to another optical device such as an optical inspection device.
The present invention is not limited to the above-described embodiment, and includes various modifications. For example, the above-described embodiment describes the present invention in detail for providing easy-to-understand explanation, but is not necessarily intended to limit the present invention to a device including all the described components. Further, a portion of the configuration of one embodiment can be replaced with the structure of another embodiment, and a configuration of another embodiment can be added to a configuration of one embodiment. Furthermore, addition of another configuration can be added to a portion of the configuration of each embodiment, and deletion or replacement of the portion of the configuration of each embodiment is also possible.
Although the control mechanism and the components and a combination thereof are shown that can be necessary for explanation, all the control mechanism, the components, and a combination in a product are not necessarily shown. It can be considered that all or most of the configurations are mutually related and connected.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/064257 | 5/22/2013 | WO | 00 |