JP2010055713A - Recording and reproducing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To stabilize reproduction of multilayer recording, with respect to a recording and reproducing device. <P>SOLUTION: The recording and reproducing device includes: a rotary drive means (motor) rotation-driving a recording medium 1 being multi-layers recordable; lenses 6, 7 for recording and reproducing arranged oppositely to the recording medium 1 rotation-driven by this rotation-drive means; a lens 5 for address detection provided as a body separated from the lenses 6, 7 for recording and reproducing; a light source 9 for recording and reproducing for supplying light for recording and reproducing to the lenses 6, 7 for recording and reproducing; and a light source 9 for address for supplying light for address to the lens 5 for address detection, wherein out of the lenses 6, 7 for recording and reproducing, a focal diameter by the lens 7 for recording and reproducing of a recording light side is made larger than a focal diameter by the lens 6 for recording and reproducing of a reference light side. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a recording / reproducing apparatus that performs recording and reproduction on a recording medium capable of multilayer recording.

  In recent years, recording media capable of multilayer recording have been proposed in order to increase the recording capacity.

  A recording / reproducing apparatus that performs multilayer recording on the recording medium has the following configuration.

That is, the conventional recording / reproducing apparatus has a rotation driving means for rotating a recording medium capable of multi-layer recording, a lens disposed opposite to the recording medium rotated by the rotation driving means, and recording / reproducing light to the lens. The recording / reproducing light source to be supplied and the address light source for supplying the address light to the lens are provided. As a document describing a technique related to a conventional recording / reproducing apparatus, for example, there is Patent Document 1 below.
JP 2002-150567 A

  In the conventional recording / reproducing apparatus, multilayer recording is not stable.

  That is, in order to perform multi-layer recording on a recording medium, the recording first and second lenses are opposed to each other, the reference light is irradiated into the recording medium from one lens, and the other lens Recording is performed by irradiating the recording medium with recording light and forming interference fringes at the intersections of the two.

  However, since the first and second lenses are opposed to each other with the recording medium sandwiched as described above, it is extremely difficult to maintain the proper positional relationship between the two, and as a result, interference occurs in the recording medium. Stripes cannot be formed properly, and multilayer recording may become unstable.

  Therefore, the present invention aims to stabilize multilayer recording.

  In order to achieve this object, the present invention comprises a rotation driving means for rotationally driving a recording medium capable of multilayer recording, a recording / reproducing lens disposed opposite to the recording medium rotated by the rotation driving means, An address detection lens provided opposite to the recording / reproducing lens, opposite to the recording medium, a recording / reproducing light source for supplying recording / reproducing light to the recording / reproducing lens, and an address detecting lens An address light source for supplying address light, and the recording / reproducing lens is composed of a first recording / reproducing lens and a second recording / reproducing lens facing each other via a recording medium. Of the recording / reproducing lens and the second recording / reproducing lens, the focal diameter of the recording light side lens is made larger than the focal diameter of the reference light side lens. It is intended to achieve the initial objectives.

  As described above, the present invention provides a rotational drive means for rotationally driving a recording medium capable of multi-layer recording, a recording / reproducing lens disposed opposite to the recording medium rotationally driven by the rotational drive means, and disposed opposed to the recording medium. In addition, an address detection lens provided separately from the recording / reproducing lens, a recording / reproducing light source for supplying recording / reproducing light to the recording / reproducing lens, and an address light to the address detecting lens A recording / reproducing lens comprising a first recording / reproducing lens and a second recording / reproducing lens facing each other via a recording medium, the first recording / reproducing lens, Of the second recording / reproducing lens, the focal diameter of the recording light side lens is larger than the focal diameter of the reference light side lens, which stabilizes multilayer recording. It can be.

  That is, in the present invention, the recording / reproducing lens is composed of the first recording / reproducing lens and the second recording / reproducing lens which are opposed to each other with the recording medium interposed therebetween. Of the two recording / reproducing lenses, the focal diameter of the recording light side lens is made larger than the focal diameter of the reference light side lens.

  For this reason, even if the relative positions of the first recording / reproducing lens and the second recording / reproducing lens are slightly deviated, an intersection portion of the recording light and the reference light is formed in the recording medium. Is reliably formed, and as a result, multilayer recording can be stabilized.

  Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

(Embodiment)
FIG. 1 shows a recording / reproducing apparatus according to an embodiment of the present invention. In FIG. 1, reference numeral 1 denotes a multi-layer recordable recording medium formed of, for example, a photopolymer. It has a disk shape as shown in (a), and a through hole (2 in FIG. 3 (a)) is provided at the center.

  Then, the rotational drive shaft 4 of the motor 3 is inserted into the through hole 2, and although not shown, chucking is performed in this state, whereby the recording medium 1 passes through the rotational drive shaft 4 and the motor 3 Thus, it is driven to rotate.

  That is, the motor 3 and the rotational drive shaft 4 constitute a rotational drive means.

  Returning to FIG. 1 again, the description will be continued. As shown in FIG. 1, an address detection lens 5 and a recording / playback lens 6 are provided on one surface side (for example, the lower surface side) of the recording medium 1. Opposing to the one surface side of the media 1, they are arranged side by side.

  A recording / reproducing lens 7 is arranged on the other surface side (for example, the upper surface side) of the recording medium 1 so as to face the recording / reproducing lens 6 with the recording medium 1 interposed therebetween.

  Next, the address detection lens 5, the recording / reproducing lens 6, and the recording / reproducing lens 7 will be described with reference to FIG.

  First, as shown in FIG. 2, the recording medium 1 is capable of multi-layer recording in the thickness direction, and as shown in FIG. 2, at the intersection of light by the recording and reproducing lenses 6 and 7. The interference of light creates so-called interference fringes, which constitute part of the digital signal. Of the recording / reproducing lenses 6, 7, the recording / reproducing lens 6 is a lens that irradiates reference light into the recording medium 1, and the recording / reproducing lens 7 receives light reflected by the retroreflector 26 described below in the recording medium 1. It is a lens that irradiates as recording light.

  The greatest feature of this embodiment is that the focal diameter of the recording / reproducing lens 7 on the recording light side is larger than the focal diameter of the recording / reproducing lens 6 on the reference light side. The operation will be described in detail with reference to FIG.

  Now, as the interference fringes are intermittently formed on one plane (inside the inner layer) of the recording medium 1 on which the interference fringes are formed as described above, video and audio are recorded as digital signals.

  As apparent from FIG. 2, the intersection of the lights by the recording and reproducing lenses 6 and 7 is moved to a plurality of recording surfaces in the thickness direction of the recording medium 1. Since video and audio are recorded as digital signals, which can be formed in a plurality of layers in the thickness direction of the recording medium 1, the recording capacity of the recording medium 1 can be extremely large.

  For example, if the information of the surveillance camera is recorded on the recording medium 1, it is possible to record security information for one year with this recording medium 1, and this also makes the recording capacity extremely high. It will be understood that it is big.

  The address detection lens 5 is provided to perform the recording using the recording / reproducing lenses 6 and 7 and the subsequent reproduction.

  That is, as shown in FIG. 2, the address detection lens 5 reads an address 8 provided on the lower surface side of the recording medium 1, and the read / write lens 8 is used to read the recording / reproducing lens 6 described above. 7 is used for multilayer recording and subsequent reproduction.

  Next, the light source and the like for performing recording using the recording and reproducing lenses 6 and 7 and subsequent reproduction and reading an address using the address detecting lens 5 will be described with reference back to FIG.

  In the present embodiment, the recording on the recording medium 1 and the subsequent reproduction and the reading of the address 8 using the address detection lens 5 are performed by one light source 9.

  That is, in the present embodiment, a laser that emits blue light having a wavelength of 405 nm is used as the light source 9.

  First, the blue light from the light source 9 is then subjected to the enlargement and rounding correction by the relay lens 10, then passes through the beam splitter 11, and then converted into parallel light by the collimator lens 12. Be changed. This parallel light is then converted into light having two mutually orthogonal polarization components (P-polarized light and S-polarized light) in the half-wave plate 13.

  Of the converted light, the P-polarized light passes through the beam splitter 14, then passes through the quarter-wave plate 15, the beam splitter 16, and the quarter-wave plate 17 one after another. The light passes through the detection lens 5 and is condensed to an address 8.

  Then, the reflected light irradiated to the address 8 of the recording medium 1 and then reflected at the address 8 is detected as address information. This reflected light is detected by the address detection lens 5 and then 1. After passing through the quarter-wave plate 17, the light enters the beam splitter 16, and is then reflected by the beam splitter 16 by 90 degrees, and then the reflected light passes through the hologram 18 and is then collected by the astigmatism lens 19. Then, the condensed light reaches the address detecting element 20.

  Then, the address information is detected based on the information that has reached the address detection element 20, and based on this address information, the above-described recording / reproducing lenses 6 and 7 perform multilayer recording and subsequent reproduction.

  Here, the beam splitter 16 that reflects the reflected light from the recording medium 1 toward the address detection element 20 will be described in more detail.

  The beam splitter 16 separates light according to the rotation direction of circularly polarized light out of the polarization components of light. Particularly in this embodiment, the counterclockwise circularly polarized light passes through the beam splitter 16, and the clockwise circularly polarized light is reflected by the beam splitter 16.

  That is, the P-polarized light emitted from the light source 9 and passed through the beam splitter 14 passes through the quarter-wave plate 15 to become counterclockwise circularly polarized light and passes through the beam splitter 16.

  The counterclockwise circularly polarized light that has passed through the beam splitter 16 passes through the quarter-wave plate 17 and becomes S-polarized light, passes through the address detection lens 5, and is condensed to become address light. Irradiated to address 8 of media 1 and then reflected from this address 8.

  The S-polarized light reflected by the recording medium 1 passes through the address detecting lens 5 and then passes through the quarter-wave plate 17 to become clockwise circularly polarized light. The reflected light from the recording medium 1 that has become clockwise circularly polarized light enters the beam splitter 16, is then reflected by 90 degrees at the beam splitter 16, and travels toward the address detection element 20.

  As described above, in this embodiment, by using the beam splitter 16 that separates the light according to the rotation direction of the circularly polarized light, the P-polarized light that is linearly polarized light emitted from the light source 9 and separated by the beam splitter 14 is converted to 1 / 4 wavelength plate 15 is passed through as circularly polarized light, and ¼ wavelength plate 17 is passed through twice, and when passing through ¼ wavelength plate 15, the direction of travel is as circularly polarized light that is reverse to that when passing through ¼ wavelength plate 15. Can be changed.

  In other words, by using the beam splitter 16 that separates the light according to the rotation direction of the circularly polarized light together with the quarter wavelength plates 15 and 17, it is possible to change the traveling direction of the linearly polarized light having a single wavelength. Become.

  In the present embodiment, as described above, based on the address information detected by the address detection element 20 and the focus information of the address detection lens 5 with respect to the address 8 of the recording medium 1, the recording and reproduction lenses 6 and 7 are used. Multi-layer recording and subsequent reproduction are performed.

  Specifically, the S-polarized light of the light passing through the half-wave plate 13 is reflected by the beam splitter 14 at a right angle to the left side of FIG. The light passes through the quarter-wave plate 22 and the spherical aberration correction element 23 one after another, and then is condensed in the recording medium 1 by the recording / reproducing lens 6, and then spreads from its focal point before recording / reproducing. It is converted into parallel light again by the lens 7 for use.

  The parallel light converted by the recording / reproducing lens 7 then passes through the spherical aberration correction element 24 and the shutter 25, and then proceeds to the retroreflector 26, and then is reflected by the retroreflector 26, and then the shutter 25, The light passes through the spherical aberration correcting element 24 and is then collected by the recording / reproducing lens 7 and is focused in the recording medium 1 as shown in FIGS.

  At this time, since the focal point by the recording / reproducing lens 6 is already formed on the set recording surface in the recording medium 1, the focal point by the recording / reproducing lens 7 interferes, and as a result, As described above, interference fringes are formed in the recording medium 1.

  Next, drive systems for the address detection lens 5, the recording / reproducing lens 6, and the recording / reproducing lens 7 will be described.

  That is, the address detection lens 5 needs to adjust the focal length with the recording medium 1 in order to appropriately read the address 8 of the recording medium 1, and the recording / reproducing lenses 6 and 7 are set. It is necessary that the focal points of the recording surfaces are correctly formed on the recording surface, and these recording / reproducing lenses 6 and 7 need to perform multilayer recording in the thickness direction of the recording medium 1, Drive control is important.

  First, as can be understood from FIGS. 2 and 3B, the recording / reproducing lens 6 and the address detecting lens 5 are unitized by being housed in a frame 27. 3A, the recording medium 1 is moved in the radial direction as shown in FIG. 3A by being driven by the screw shaft 28 shown in FIG. 3A and driving the screw shaft 28 by the motor 29 shown in FIG. . The quarter wavelength plate 17 is held on the frame 27 at a constant distance from the address detection lens 5, and the spherical aberration correction element 23 is kept at a constant distance from the recording / reproducing lens 6. Is held. For this reason, in the present embodiment, the position information of the address detecting lens 5 and the position information of the recording / reproducing lens 6 with respect to the recording medium 1 are obtained by using the quarter wavelength plate 17 and the spherical aberration correcting element 23. ing.

  In this embodiment, the address detection lens 5 and the recording / reproducing lens 6 are arranged in the frame 27 side by side upstream and downstream of the track-like address of the recording medium 1, but the address detection lens. 5 and the recording / reproducing lens 6 may be arranged in the frame 27 side by side in the radial direction of the recording medium 1.

  As described above, in the present embodiment, the frame 27, the screw shaft 28, and the motor 29 constitute the frame driving means for moving the frame 27 in the radial direction of the recording medium 1, so that the address can be obtained only by moving the frame 27. The detection lens 5 and the recording / reproducing lens 6 can be moved together. Therefore, the operation is fast, and the relationship between the address detection lens 5 and the recording / reproducing lens 6 can be easily kept constant.

  This also leads to a reduction in the amount of adjustment when adjusting the recording / reproducing lens 6 based on the address information. As a result, the operation becomes faster and the stability is improved.

  Further, in the present embodiment, the address detection lens 5 is arranged on the upstream side of the recording medium 1 relative to the recording / reproducing lens 6 in the frame 27.

  In this state, electromagnetic coils 30 for adjusting the distances between the address detection lens 5, the recording / reproducing lens 6 and the recording medium 1 are provided at the four corners of the frame 27.

  That is, the electromagnetic coil 30 is a lens distance adjusting means for adjusting the distance between the address detecting lens 5 and the recording / reproducing lens 6 with respect to the recording medium 1.

  At this time, since the address detection lens 5 and the recording / reproducing lens 6 are unitized in the frame 27, the adjustment of the address detecting lens 5 and the recording / reproducing lens 6 with respect to the recording medium 1 can be performed in a short time. It can be done stably.

  Further, in order to finely adjust the individual distances of the address detecting lens 5 and the recording / reproducing lens 6 with respect to the recording medium 1, electromagnetic coils are respectively provided at the four corners of the address detecting lens 5 and the recording / reproducing lens 6. 31 and 32 are provided.

  That is, these electromagnetic coils 31 and 32 are also lens distance adjusting means for adjusting the distance between the address detecting lens 5 and the recording / reproducing lens 6 with respect to the recording medium 1.

  Note that the arrangement of the address detecting lens 5 and the recording / reproducing lens 6 in a balanced manner on the left and right sides in the frame 27 also allows the frame 27 to move smoothly and increases the stability against vibration.

  On the other hand, the recording / reproducing lens 7 disposed above the recording medium 1 is driven in the radial direction of the recording medium 1 by driving the screw shaft 33 with a motor 34, as can be understood from FIGS. The screw shaft 33 and the motor 34 constitute driving means for moving the recording / reproducing lens 7 in the radial direction of the recording medium 1.

  Further, in order to adjust the distance of the recording / reproducing lens 7 with respect to the recording medium 1, an electromagnetic coil 35 is provided, and this electromagnetic coil 35 constitutes a lens distance adjusting means.

  Further, the recording / reproducing lens 6 and the address detecting lens 5 in the frame 27 are provided with lens position correcting means for adjusting the position in the frame 27, respectively.

  Specifically, as shown in FIG. 3B, the recording / reproducing lens 6 and the address detecting lens 5 are provided in the frame 27. As described in FIG. A portion of the frame 27 surrounding the outer periphery of the recording / reproducing lens 6 and the address detecting lens 5 is a square frame (rectangular frame). Capacitor electrodes are respectively provided on the four orthogonal inner peripheral surfaces of the square frame. (Not shown) is arranged.

  In addition, the outer shape of the recording / reproducing lens 6 and the address detecting lens 5 arranged at predetermined intervals in the square frame of the frame 27 is also a square shape. Capacitor electrodes (not shown) are also arranged on the four square outer peripheral surfaces of the lens 5.

  That is, four capacitors are formed on the outer peripheral surfaces of the recording / reproducing lens 6 and the address detecting lens 5.

  Therefore, if the capacitances of the capacitors on the outer peripheral four surfaces of the recording / reproducing lens 6 and the address detecting lens 5 are detected, the positional relationship between the recording / reproducing lens 6 and the address detecting lens 5 within the square frame of the frame 27 is detected. Can be determined.

  Based on this discrimination information, an electromagnetic coil (not shown) is energized to correct the positional relationship between the recording / reproducing lens 6 and the address detecting lens 5 within the square frame of the frame 27. That is, the lens position correcting means is constituted by the capacitor electrode (not shown) and the electromagnetic coil (not shown) in this portion.

  In the above configuration, first, when the address 8 is detected by the address detection lens 5, the address detection lens 5 is attached to the electromagnetic coil 30 so that the focus on the address detection element 20 is most appropriate as described above. , 31, where a correct address 8 is read by performing so-called servo control. Thus, the reference position by the address detection lens 5 is set.

  Next, control for causing the focal points of the recording / reproducing lenses 6 and 7 to interfere with each other will be described.

  The light after forming the interference fringes in the recording medium 1 passes through the recording / reproducing lens 6, then the spherical aberration correction element 23, the quarter wavelength plate 22, then the mirror 21 and the beam splitter 14, and then 1 The light is detected by the light receiving element 38 after passing through the / 4 wavelength plate 36 and the astigmatism lens 37.

  Then, based on the detection data in the light receiving element 38, the recording / reproducing lenses 6 and 7 are servo-controlled using the electromagnetic coils 31 and 35, so that the target depth of the recording medium 1 is obtained as described above. Control is performed so that an appropriate interference fringe is formed in this layer.

  In the present embodiment, as described above, in addition to the recording medium 1 capable of multi-layer recording, compatibility for performing writing and reading to a so-called CD or DVD is also provided.

  Specifically, as shown in FIG. 1, a light source 39 capable of emitting infrared light for CD and red light for DVD is provided in a direction orthogonal to the relay lens 10 of the beam splitter 11.

  This compatibility will be briefly described. First, when recording or reproducing a CD, as described above, the light source 39 emits infrared light. Further, when recording or reproducing a DVD, as described above, the light source 39 emits red light. Of course, at this time, a CD or DVD is mounted on the rotational drive shaft 4 of FIG.

  At these times, the light emitted from the light source 39 then travels to the beam splitter 11 via the diffraction grating 40.

  Here, the diffraction grating 40 is for splitting the infrared light for CD emitted from the light source 39 and the red light for DVD into three lights, respectively. By separating the light emitted from the light source 39, the servo control of the recording / reproducing lens 6 can be performed with high accuracy, and the recording / reproducing quality can be improved (these CDs and DVDs). The recording / reproducing of the data will be described in detail later).

  Hereinafter, recording / reproduction on the recording medium 1 and recording / reproduction on a CD or DVD instead of the recording medium 1 will be described.

  First, recording / reproduction on the recording medium 1 capable of multilayer recording will be described with reference to FIGS. Also in this case, the position information of the recording / reproducing lens 6 is based on the position information of the address detecting lens 5, and the recording / reproducing lens 6 is always based on the position information of the address detecting lens 5. , 7 focus control is performed.

  In this case, the number of layers of the recording medium 1 to be recorded or the number of layers to be read is set. FIG. 4 shows this setting.

  In FIG. 4, the P-polarized light of the light that has entered the beam splitter 14 from the light source 9 goes straight as described above, becomes circularly polarized light by the quarter-wave plate 15, passes through the beam splitter 16, and then becomes ¼. After being changed to S-polarized light by the wave plate 17, it goes to the address detection lens 5 as described above.

  At this time, a part of the light is reflected by the surface of the quarter-wave plate 17, and the reflected light passes through the beam splitter 16 as shown in FIG. The polarized light is reflected by the beam splitter 14 and then reaches the light receiving element 38 via the quarter wavelength plate 36 and the astigmatism lens 37.

  On the other hand, the S-polarized light traveling from the half-wave plate 13 to the beam splitter 14 is reflected in the direction of the mirror 21 as shown in FIG. 4, and then becomes circularly-polarized light by the quarter-wave plate 22, and then is spherical as described above. It proceeds to the recording / reproducing lens 6 via the aberration correction element 23.

  At this time, part of the light is also reflected by the surface of the spherical aberration correction element 23, and this reflected light becomes P-polarized light by the quarter-wave plate 22, which is reflected by the mirror 21, and the beam splitters 14, 1/4. The light reaches the light receiving element 38 through the wave plate 36 and the astigmatism lens 37.

  Here, the reflected light from the quarter-wave plate 17 reaching the light receiving element 38 and the reflected light from the spherical aberration correcting element 23 are respectively on the optical axis connecting the center of the astigmatism lens 37 and the light receiving element 38. On the other hand, it is in a slightly inclined state.

  For this reason, the arrival position of these two reflected lights to the light receiving element 38 is shifted, but two lights are irradiated on substantially the same portion, and as a result, interference between the two lights occurs, In the element 38, when the relative position between the recording / reproducing lens 6 and the address detecting lens 5 is changed, light and dark stripes that change with time are formed.

  As described above, the number of layers in the recording medium 1 to be recorded or the number of layers to be read depends on how the distance between the recording / reproducing lens 6 and the recording medium 1 is set. It is important that the position of the recording / reproducing lens 6 can be set by counting the number of times of light intensity based on the change of the interference fringes that changes with time in the light receiving element 38 ( In this case, the position of the address detection lens 5 constitutes a reference point).

  Of course, the recording / reproducing lens 6 and the address detecting lens 5 are integrated by using the frame 27 as described above. Even when the recording / reproducing lens 6 is moved, the address detecting lens is used. 5 must read address 8 correctly.

  Therefore, the focus correction for reading the address 8 using the address detection lens 5 is performed using the electromagnetic coil 31 as described above.

  Now, after setting the number of layers of the recording medium 1 as described above, recording is performed in that layer in the state shown in FIG.

  In FIG. 5, address detection using the address detection lens 5 is not described in order to avoid complication of the drawing, but as is apparent from the above description, this address detection is performed for recording and reproduction. Address detection is performed using light having the same wavelength as the light source, specifically, light from the light source 9.

  Therefore, as shown in FIG. 5, the recording performed in the multilayer recording on the recording medium 1 is very dense in each layer, so that the capacity can be increased accordingly.

  For example, if the information supplied to the light source 9 is for security, specifically, video from a surveillance camera, one year of security information is recorded on one recording medium 1. Can do. This can greatly contribute to the recent demands for improving security.

  In other words, security countermeasures using such a surveillance camera is a major hindrance to having to frequently change recording media, but it is possible to perform precise information recording as in this embodiment. Then, as described above, the security information for one year can be recorded on one recording medium 1, so that the complexity is eliminated and the contribution to the spread is greatly made.

  In this embodiment, address detection and recording / reproduction are shared by a single light source. However, address detection and recording / reproduction can be performed by separate light sources.

  However, even when address detection and recording / reproduction are performed using separate light sources, the wavelength of the address light source is the same as or shorter than the wavelength of the recording / reproduction light source. It is preferable to keep it.

  In other words, in order to perform precise information recording / reproduction, it is impossible to perform such precise information recording / reproduction unless there is address information that is the same or more precise than that. Is preferably the same as the wavelength of the recording / reproducing light source or shorter than the wavelength of the recording / reproducing light source.

  FIG. 6 is a diagram illustrating reading of information recorded in a multilayer on the recording medium 1. At this time, reflected light from the recording / reproducing lens 7 is prevented from returning to the light receiving element 38.

  Specifically, at the time of this reproduction, the shutter 25 provided in front of the retro reflector 26 is closed so that the reflected light does not return through the recording / reproducing lens 7, and thereby noise components are mixed in the reproduction data. It was set as the structure which suppresses this.

  In addition to the method of closing the shutter 25, the recording / reproducing lens 7 disposed above the recording medium 1 can be recorded / reproduced by driving the screw shaft 33 described with reference to FIGS. It is also possible to prevent the reflected light from returning through the recording / reproducing lens 7 by moving the lens 6 to a position not facing the recording lens 6.

  That is, if the recording / reproducing lens 6 and the recording / reproducing lens 7 are displaced in the radial direction of the recording medium 1, the reflected light can be prevented from returning through the recording / reproducing lens 7 without providing the shutter 25. This makes it possible to prevent noise components from being mixed into the reproduction data.

  Now that the overall configuration and operation of the present embodiment have been understood from the above description, the most significant features of the present embodiment will be described.

  As described above, the greatest feature of the present embodiment is that the focal diameter of the recording / reproducing lens 7 on the recording light side is larger than the focal diameter of the recording / reproducing lens 6 on the reference light side.

  Specifically, as shown in FIG. 10, the recording / reproducing lens 7 has a smaller diameter than that of the recording / reproducing lens 6, so that the focal point by the recording / reproducing lens 7 on the recording light side as shown on the right side of FIG. The diameter 7a was made larger than the focal diameter 6a of the recording / reproducing lens 6 on the reference light side (the NA of the recording / reproducing lens 7 was made smaller than the NA of the recording / reproducing lens 6).

  For this reason, at the focal points of the recording / reproducing lenses 6 and 7, intersections are formed in a wider range, so that stable interference fringes can be formed here.

  In the first place, since the recording / reproducing lenses 6 and 7 are opposed to each other with the recording medium 1 interposed therebetween, that is, are separate from each other, it is extremely difficult to always match the focal points of both, and in the present embodiment, as described above. The focal diameter 7a of the recording / reproducing lens 7 on the recording light side is made larger than the focal diameter 6a of the recording / reproducing lens 6 on the reference light side. As a result, the focal points of these recording / reproducing lenses 6 and 7 are stable. Thus, an intersection point is formed so that a stable interference fringe can be formed.

  Here, the reason why the focal diameter 7a by the recording / reproducing lens 7 on the recording light side is made larger than the focal diameter 6a by the recording / reproducing lens 6 on the reference light side will be described in more detail. As described above, the address detection lens 5 is unitized and the position thereof can be easily managed. On the other hand, the recording / reproducing lens 7 is a separate body that is opposed to the recording medium 1, so that the focal diameter 7a on this side. This is because the larger the value is, the easier it is to always match the focal points of the recording / reproducing lenses 6 and 7, as shown in FIG.

  As a result, the focus of the recording / reproducing lenses 6 and 7 can be stably formed in the target recording layer in the recording medium 1 to form a stable interference fringe. It can be done.

  As another configuration in which the focal diameter 7a by the recording / reproducing lens 7 on the recording light side is larger than the focal diameter 6a by the recording / reproducing lens 6 on the reference light side, the outer circumference of the lens of the recording / reproducing lens 7, Alternatively, for example, a light opaque portion may be formed in the vicinity of the outer periphery of the spherical aberration correction element 24, for example.

  That is, even in this case, since the effective diameter of the recording / reproducing lens 7 can be reduced, the same effect as the embodiment shown in FIG. 10 can be obtained.

  FIG. 7 shows a state in which the CD 41 is mounted on the rotary drive shaft 4 instead of the recording medium 1, and recording or reproduction can be performed in this state.

  At this time, since the amount of information contained in the CD 41 is not so large, infrared light is emitted from the light source 39, and this is provided near the upper surface in the thickness direction of the CD 41 through the path of the arrow shown in FIG. The data 42 is written on the recorded surface, or the data 42 on the recorded surface is read.

  That is, since the CD 41, the DVD shown in FIG. 8, and the BD (Blu-ray Disc) shown in FIG. 9 also have address information in the data 42, address confirmation and writing or reading to the address can be performed simultaneously. Is. The read data at the time of reproduction is supplied to the light receiving element 38.

  FIG. 8 shows recording / reproduction on the DVD 43, which is different from the CD 41 in FIG. 7 in that red light is emitted from the light source 39 and data is recorded on the recording surface provided near the intermediate surface in the thickness direction of the DVD 43. 44 or writing the data 44 on the recording surface near the intermediate surface. Note that the writing of the data 44 to the DVD 43 and the detection of reading of the data 44 by the light receiving element 38 have the same path as the CD 41.

  FIG. 9 shows recording / reproduction of data 46 to / from the BD 45.

  At this time, the blue light emitted from the light source 9 is recorded on the recording surface provided near the lower surface in the thickness direction of the BD 45 through the address detection lens 5 as shown in FIG. .

  The recorded data 46 is read out through the address detecting lens 5 and detected through the address detecting element 20.

  In other words, in the present embodiment, the information can be recorded and read out on the recording medium 1 capable of multi-layer recording, but the recording medium can be recorded and reproduced on the CD 41, the DVD 43, and the BD 45.

  As described above, the recording / reproducing apparatus of the present invention performs extremely dense and large-capacity information recording and can reproduce the information, and has high operational stability. It will be widely used in various fields where a large capacity of recording is required. In addition, if the recording and reproduction can be performed precisely and with a large capacity, there is no need to replace the recording medium, and it becomes extremely convenient.

1 is a block diagram of a recording / reproducing apparatus according to an embodiment of the present invention. Enlarged view of the main part (A) Enlarged perspective view of the main part (b) Enlarged plan view of the main part Block diagram for explaining the operation Block diagram for explaining the operation Block diagram for explaining the operation Block diagram for explaining the operation Block diagram for explaining the operation Block diagram for explaining the operation Block diagram for explaining the operation

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Recording medium 2 Through-hole 3 Motor 4 Rotation drive shaft 5 Address detection lens 6 Recording / reproducing lens 6a Focal diameter 7 Recording / reproducing lens 7a Focal diameter 8 Address 9 Light source 10 Relay lens 11 Beam splitter 12 Collimator lens 13 1/2 Wave plate 14 Beam splitter 15 1/4 wave plate 16 Beam splitter 17 1/4 wave plate 18 Hologram 19 Astigmatism lens 20 Address detection element 21 Mirror 22 1/4 wave plate 23 Spherical aberration correction element 24 Spherical aberration correction element 25 Shutter 26 Retro-reflector 27 Frame 28 Screw shaft 29 Motor 30 Electromagnetic coil 31 Electromagnetic coil 32 Electromagnetic coil 33 Screw shaft 34 Motor 35 Electromagnetic coil 36 1/4 wavelength plate 37 Astigmatism lens 38 Light receiving element 39 Source 40 diffraction grating 41 CD
42 Data 43 DVD
44 data 45 BD
46 data

Claims (14)

Rotation drive means for rotating a recording medium capable of multilayer recording;
A recording / reproducing lens disposed opposite to the recording medium rotated by the rotation driving means;
An address detection lens provided opposite to the recording medium and provided separately from the recording / reproducing lens,
A recording / reproducing light source for supplying recording / reproducing light to the recording / reproducing lens;
An address light source for supplying address light to the address detection lens;
The recording / reproducing lens includes a first recording / reproducing lens and a second recording / reproducing lens that are opposed to each other with the recording medium interposed therebetween. A recording / reproducing apparatus in which a focal diameter of a recording light side lens is larger than a focal diameter of a reference light side lens. The recording / reproducing apparatus according to claim 1, wherein the recording light side lens is smaller than the reference light side lens. The recording / reproducing apparatus according to claim 1, wherein a light-impermeable portion is formed on an outer periphery of a lens on the recording light side or in the vicinity thereof. The recording / reproducing apparatus according to claim 1, wherein the first recording / reproducing lens and the address detecting lens are provided in the frame. 5. The recording / reproducing apparatus according to claim 4, wherein the frame is provided with frame driving means for moving the frame in a radial direction of the recording medium. 6. The first recording / reproducing lens, the second recording / reproducing lens, and the address detection lens are provided with lens distance adjusting means for adjusting the distance of each lens to the recording medium. The recording / reproducing apparatus as described in one. 7. The recording / reproducing apparatus according to claim 4, wherein the first recording / reproducing lens and the address detecting lens in the frame are each provided with lens position correcting means for adjusting the position in the frame. 8. The recording / reproducing apparatus according to claim 7, wherein the lens position correcting means is configured to correct the lens position in the frame by changing the capacitance of a capacitor formed between the lens and the frame. 9. The outer periphery of the first recording / reproducing lens and the address detection lens in the frame is provided with a rectangular frame surrounding the outer periphery of each lens, and capacitor electrodes are arranged on four orthogonal surfaces of each rectangular frame. The recording / reproducing apparatus as described. 10. The recording / reproducing apparatus according to claim 4, wherein the address detecting lens and the first recording / reproducing lens are arranged in a frame side by side upstream and downstream of the track-like address of the recording medium. 10. The recording / reproducing apparatus according to claim 4, wherein the address detecting lens and the first recording / reproducing lens are arranged in a frame side by side in a radial direction of the recording medium. A light receiving element comprising a first recording / reproducing lens and a second recording / reproducing lens and optically detecting a defocus between the first recording / reproducing lens and the second recording / reproducing lens is optically provided. The recording / reproducing apparatus according to claim 1, which is connected. The recording / reproducing apparatus according to claim 1, wherein the recording / reproducing light source and the address light source are shared. The recording / reproducing apparatus according to claim 1, wherein security information is supplied to the recording / reproducing light source.

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