JP4149234B2 - Hologram laser and optical pickup device having the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a hologram laser that is used as a light source for signal reading and writing of an optical recording medium and can handle reading and writing of signals using a plurality of light beams having different wavelengths, and an optical pickup device including the hologram laser.
[0002]
[Prior art]
As an optical recording medium, an optical disk called a CD family such as a compact disc (abbreviated CD) and a write-once compact disc (abbreviated CD-R) uses a semiconductor laser chip having an emission wavelength of 780 nm as a signal. Is read or written. On the other hand, an optical disc called a DVD family such as a digital versatile disc (abbreviated as DVD) and a write-once digital versatile disc (abbreviated as DVD-R) has an emission wavelength for improving information recording density. Signals are read or written using a semiconductor laser chip of 630 nm to 690 nm.
[0003]
When such CD family and DVD family optical disks are read or written by the same optical pickup device, as proposed in Japanese Patent Application No. 2001-394848 by the present applicant, a plurality of semiconductor laser chips having different emission wavelengths are used. It is provided in the apparatus.
[0004]
FIG. 13 is a simplified perspective view showing a configuration of a conventional hologram laser 1, and FIG. 14 is a system diagram showing a simplified configuration of an optical pickup device 2 including the hologram laser 1 shown in FIG.
[0005]
A conventional hologram laser 1 includes a first light source 4 that emits infrared light 3 having a wavelength of 780 nm, a second light source 6 that emits red light 5 having a wavelength of 650 nm, and zero-order diffracted light, + (plus ) A diffraction grating 7 that diffracts into first-order diffracted light and-(minus) first-order diffracted light, a light receiving element 9 that receives reflected light from the optical disk 8, and infrared light 3 and red light 5 reflected by the optical disk 8, A wavelength separation element having a hologram element 12 including first and second holograms 10 and 11 diffracted so that diffracted light is received by the light receiving element 9, and a wavelength separation surface 13 that transmits s-polarized light and reflects p-polarized light. 14 as a single component.
[0006]
The infrared light 3 emitted from the first light source 4 passes through the diffraction grating 7 and is diffracted into zero-order diffracted light, + 1st-order diffracted light, and −1st-order diffracted light. The diffracted light passes through the first hologram 10, enters the wavelength separation element 14, and passes through the wavelength separation surface 13. Light emitted from the hologram laser 1 in the direction of the optical disk 8 is converted into parallel light by the collimator lens 15, passes through the quarter-wave plate 16, is bent 90 degrees by the rising mirror 17, and is guided in the direction of the optical disk 8. Then, the light is condensed on the optical disk 8 by the objective lens 18. The infrared light 3 reflected by the optical disk 8 passes through the objective lens 18, is bent 90 degrees by the rising mirror 17, and passes through the quarter-wave plate 16 and the collimator lens 15. The light that has passed through the collimator lens 15 enters the wavelength separation element 14, passes through the wavelength separation surface 13, is diffracted by the first hologram 10, and + 1st order diffracted light is collected on the light receiving element 9.
[0007]
The red light 5 emitted from the second light source 6 passes through the diffraction grating 7 and the first hologram 10, enters the wavelength separation element 14, and passes through the wavelength separation surface 13. The light emitted from the hologram laser 1 in the direction of the optical disk 8 is converted into parallel light by the collimator lens 15, passes through the quarter-wave plate 16, is rotated by 45 degrees, and enters the rising mirror 17. The light incident on the rising mirror 17 is bent 90 degrees and guided in the direction of the optical disk 8, and is collected on the optical disk 8 by the objective lens 18. The light reflected from the optical disk 8 passes through the objective lens 18, is bent 90 degrees by the rising mirror 17, and enters the quarter-wave plate 16. The quarter wavelength plate 16 further rotates the polarization direction by 45 degrees, and the red light 5 rotated by a total of 90 degrees polarization direction passes through the collimating lens 15. The red light 5 rotates by 90 degrees and becomes p-polarized with respect to the wavelength separation surface 13, enters the wavelength separation element 14, and is reflected by the wavelength separation surface 13. The reflected light is further reflected in the direction of the second hologram 11 by the reflecting surface 19 of the wavelength separation element 14, diffracted by the second hologram 11, and −1st order diffracted light is collected on the light receiving element 9. Detection signals are obtained based on the respective light amounts of the infrared light 3 and the red light 5 received by the light receiving element 9.
[0008]
[Problems to be solved by the invention]
The conventional hologram laser 1 described above has the following problems. The infrared light 3 and red light 5 emitted from the first and second light sources 4 and 6 are transmitted through the first hologram 10 to generate + 1st order diffracted light and −1st order diffracted light in addition to the zeroth order diffracted light. Since the + 1st order diffracted light and the −1st order diffracted light do not reach the optical disc, the amount of light used for writing information is reduced by 20 to 50%, and there is a problem that the speed of writing information on the optical disc is reduced.
[0009]
The infrared light 3 emitted from the first light source 4 and reflected by the optical disk 8 is diffracted by the first hologram 10 and the + 1st order diffracted light is collected on the light receiving element 9. Next-order diffracted light and −1st-order diffracted light are generated. For this reason, there is a problem that the amount of light collected on the light receiving element 9 is reduced and the signal reading accuracy is lowered. In addition, since the generated zero-order diffracted light is incident on the first light source 4, a scoop phenomenon in which the oscillation of the laser light by the semiconductor laser chip becomes unstable due to the influence of the zero-order diffracted light and the output of the semiconductor laser chip fluctuates. There is a problem that occurs.
[0010]
An object of the present invention is to provide a hologram laser capable of reading and writing with respect to a plurality of types of optical recording media having different reading wavelengths and realizing a reduction in the size of the device, and an optical pickup device including the hologram laser.
[0011]
[Means for Solving the Problems]
  The present invention relates to a hologram laser that emits light toward an optical recording medium on which information is recorded or reproduced by light and receives reflected light from the optical recording medium.
  A first light source that emits light L1 having a first wavelength toward the optical recording medium;
  A second light source that emits light L2 of the second wavelength toward the optical recording medium;
  A wavelength separation element for separating the light L1 and the light L2 reflected by the optical recording medium;
  A first hologram for condensing the light L1 separated by the wavelength separation element;
  A second hologram for condensing the light L2 separated by the wavelength separation element;
  A light receiving element for receiving the light L1 collected by the first hologram and the light L2 collected by the second hologram;,
  A hologram element provided with the first hologram;
  The other hologram element provided with the second hologram;With
  The first hologram is a polarization hologram whose diffraction efficiency varies depending on the polarization direction of incident light.The
  The one hologram element and the other hologram element are between the first light source, the second light source, and the wavelength separation element, and are directed from the first light source and the second light source toward the optical recording medium. Provided in this order in the direction in which the light L1 and the light L2 are emitted,
  The first hologram is an extension of the optical axis of the optical path through which the reflected light of the light L1 emitted from the first light source and reflected by the optical recording medium passes from the optical recording medium through the wavelength separation element. Is located in one plane on the optical recording medium side of the one hologram element, which is a plane orthogonal to the optical axis of the light L1,
  The second hologram is positioned on an extension of the optical axis of the optical path through which the light L2 separated by the wavelength separation surface of the wavelength separation element and reflected by the reflection surface passes from the reflection surface to the wavelength separation element. As described above, the other hologram element, which is a plane orthogonal to the optical axis of the light L1, is arranged in one plane on the optical recording medium side.This is a holographic laser.
[0012]
  According to the present invention, the light L1 emitted from the first light source and the light L2 emitted from the second light source are reflected by the optical recording medium and separated by the wavelength separation element. The light L1 is condensed on the light receiving element by the first hologram, and the light L2 is condensed on the light receiving element by the second hologram. Since the first hologram is a polarization hologram having different diffraction efficiency depending on the polarization direction of incident light, for example, the diffraction efficiency is approximately 0% with respect to the polarization direction of light emitted from the light source toward the optical recording medium. By providing the polarization hologram, it is possible to suppress the loss of light quantity of the light collected on the optical recording medium, and it is possible to accurately read and write signals on the optical recording medium.
  Further, since the first hologram and the second hologram are arranged on different members, the relative positions of the first hologram and the second hologram and other members can be individually adjusted, so that the assembly adjustment can be performed. It becomes easy.
[0013]
  Moreover, the present invention provides the polarization hologram as the first hologram,
  Zero-order diffracted light for light with the first polarization directionThrough
  For light having a second polarization direction that is perpendicular to the first polarization direction, the diffraction efficiency of plus and minus (±) first-order diffracted light is equal to the diffraction efficiency of zero-order diffracted light, or ± first-order diffracted light The diffraction efficiency is higher than the diffraction efficiency of zero-order diffracted light.
[0014]
  According to the present invention, the polarization hologram as the first hologram is zero-order diffracted light for light having the first polarization direction.ThroughFor the light having the second polarization direction that is perpendicular to the first polarization direction, the diffraction efficiency of the ± 1st order diffracted light is equal to the diffraction efficiency of the zeroth order diffracted light, or the diffraction efficiency of the ± 1st order diffracted light is It is configured to be larger than the diffraction efficiency of zero-order diffracted light.
[0015]
By setting the polarization direction of the light emitted from the light source toward the optical recording medium to the first polarization direction, the light can be guided to the optical recording medium without reducing the amount of light emitted from the light source. Further, by setting the polarization direction of the light reflected by the optical recording medium and incident on the first hologram to the second polarization direction, the amount of ± first-order diffracted light detected by the light receiving element can be increased. High-accuracy signal reading is realized by increasing the response frequency of the light receiving element. Since the zero-order diffracted light quantity of the light reflected by the optical recording medium is reduced, the influence of the zero-order diffracted light on the light source can be easily reduced by adding, for example, a high frequency superposition circuit to the laser.
[0016]
According to the present invention, the reflected light of the light L1 emitted from the first light source and reflected by the optical recording medium is on the extension of the optical axis of the optical path through which the reflected light from the optical recording medium passes through the wavelength separation element. One hologram and the first light source are arranged.
[0017]
According to the present invention, the reflected light of the light L1 emitted from the first light source and reflected by the optical recording medium is on the extension of the optical axis of the optical path through which the reflected light from the optical recording medium passes through the wavelength separation element. A hologram and a first light source are arranged. The first hologram is a polarization hologram, and is set so that the diffraction efficiency of the zero-order diffracted light in the reflected light from the optical recording medium is equal to or smaller than the diffraction efficiency of the ± first-order diffracted light. Furthermore, the influence on the light source of the zero-order diffracted light with a low diffraction efficiency and a small amount of light can be easily eliminated by, for example, a high-frequency superposition circuit added to the laser, so the first hologram and the light source are arranged on the optical axis. can do. As a result, the distance between the first light source and the first hologram is minimized, and the hologram laser can be miniaturized.
[0018]
In the present invention, the diffraction directions of the first hologram and the second hologram are
It is characterized by being substantially parallel to the arrangement direction of the first hologram and the second hologram.
[0019]
According to the present invention, since the diffraction directions of the first hologram and the second hologram are substantially parallel to the arrangement direction of the first hologram and the second hologram, the first hologram, the second hologram, and the light receiving element are collinear. Can be arranged. This makes it possible to reduce the size of the hologram laser.
[0020]
In the present invention, the first hologram and the second hologram have a plurality of booth gratings,
The direction of at least one dividing line dividing each of the first hologram and the second hologram into the booth grating is parallel to the diffraction direction of the first and second holograms.
[0021]
According to the present invention, the first hologram and the second hologram have a plurality of booth gratings, and the directions of at least one dividing line that respectively divides the first hologram and the second hologram into the booth gratings are the first and second holograms. Therefore, the light receiving element that receives the diffracted light of each of the booth gratings can be arranged perpendicular to the diffraction direction. This makes it possible to reduce the size of the hologram laser.
[0022]
In the present invention, the lattice pitch of each of the booth gratings of the first hologram is substantially equal to each other,
The lattice pitch of each of the booth gratings of the second hologram is substantially equal to each other.
[0023]
According to the present invention, the lattice pitches of the respective booth gratings of the first hologram are substantially equal to each other, and the lattice pitches of the respective booth gratings of the second hologram are substantially equal to each other. As a result, the diffraction efficiency of each of the booth gratings of the first hologram matches and the diffraction efficiency of each of the booth gratings of the second hologram matches, so that the signal reading operation can be stabilized. In addition, the first hologram and the second hologram can be easily produced.
[0024]
Further, the present invention is characterized in that the lattice pitch of each of the booth gratings of the first hologram and the grating pitch of the booth gratings of the second hologram are substantially equal to each other.
[0025]
According to the present invention, the grating pitch of each of the booth gratings of the first hologram and the grating pitch of each of the booth gratings of the second hologram are substantially equal to each other. As a result, the diffraction efficiency of the first hologram and that of the second hologram match, so that the signal reading operation can be stabilized. In addition, the first hologram and the second hologram can be easily produced.
[0026]
In the invention, it is preferable that the first hologram and the second hologram are provided in one optical member.
[0027]
According to the present invention, since the first hologram and the second hologram are provided on one optical member, the hologram laser can be miniaturized.
[0028]
Further, the present invention is characterized in that the first hologram and the second hologram are provided on different optical members.
[0029]
According to the present invention, the first hologram and the second hologram are provided on different optical members. As a result, the relative positions of the first and second holograms and the other members can be individually adjusted, so that assembly adjustment is facilitated.
[0030]
In the present invention, the light receiving element comprises:
In the arrangement direction of the first hologram and the second hologram, it is arranged between the axis of the first hologram and the axis of the second hologram.
[0031]
According to the present invention, the light receiving element is disposed between the axis of the first hologram and the axis of the second hologram in the arrangement direction of the first hologram and the second hologram. Thus, for example, the + 1st order diffracted light of the light L1 from the first hologram and the −1st order diffracted light of the light L2 from the second hologram can be diffracted in directions close to each other and received on the same light receiving element. The folding angle can be reduced. A hologram having a small diffraction angle can increase the grating pitch of the diffraction grating, so that the first and second holograms can be easily manufactured.
[0032]
In the present invention, the light receiving element comprises:
In the arrangement direction of the first hologram and the second hologram, the light L1 emitted from the first light source or the intermediate point where the distance from the axis of the first hologram is equal to the distance from the axis of the second hologram The light L2 emitted from the second light source is disposed near the axis of the hologram on which the reflected light from the optical recording medium having the shorter wavelength is incident.
[0033]
According to the present invention, for example, the second wavelength light L2 collected by the second hologram has a shorter wavelength than the first wavelength light L1 collected by the first hologram, and the light receiving element is the first hologram. And the second hologram are arranged closer to the axis of the second hologram with respect to an intermediate point where the distance from the axis of the first hologram and the distance from the axis of the second hologram are equal. When the grating pitch of the hologram is the same, the diffraction angle is smaller for light having a shorter wavelength than for light having a longer wavelength, and therefore the first hologram is arranged closer to the axis of the second hologram with respect to the intermediate point. And the grating pitch of the second hologram can be made equal and larger. This makes it possible to easily produce the first and second holograms.
[0034]
In the present invention, the light receiving element comprises:
A plurality of light receiving regions for receiving light diffracted by the respective booth gratings of the first hologram and the second hologram;
The diffracted light of the light L1 including the RF signal, the diffracted light of the light L2, and the diffracted light of the light L2 including the tracking error signal are detected by a common light receiving region.
[0035]
According to the present invention, the light receiving element has a plurality of light receiving regions for receiving light diffracted by the respective booth gratings of the first hologram and the second hologram, and diffracted light and light of the light L1 including the RF signal. The L2 diffracted light and the light L2 diffracted light including the tracking error signal are detected by a common light receiving region. The tracking error signal is a phase difference signal, and an RF signal and a phase difference signal including a high frequency component are detected by a common light receiving region, so that the number of light receiving regions having a high response speed can be reduced.
[0036]
In the present invention, the plurality of light receiving regions may be
The first hologram and the second hologram are arranged perpendicular to the arrangement direction.
[0037]
According to the present invention, the plurality of light receiving regions are arranged perpendicular to the arrangement direction of the first hologram and the second hologram. When the light L2 reflected by the optical recording medium is incident on the first hologram, it is received at a position outside the normal light receiving area, and when the light L1 reflected by the optical recording medium is incident on the second hologram, the light L2 is reflected from the normal light receiving area. Since the light is received at the deviated position, by arranging the plurality of light receiving regions in this way, it is possible to prevent unnecessary light incident on the regular light receiving region due to poor wavelength separation.
[0038]
In the present invention, the light receiving element comprises:
The longitudinal direction of each light receiving region is provided in parallel with the diffraction direction of the first hologram and the second hologram,
The length in the longitudinal direction is formed to be longer than the variation range of the incident position due to the wavelength variation of the first light source and the second light source.
[0039]
According to the present invention, the light receiving element is provided so that the longitudinal direction of each light receiving region is parallel to the diffraction directions of the first hologram and the second hologram, and the lengths in the longitudinal direction are the first light source and the second light source. By forming the light source so as to be longer than the fluctuation range of the incident position due to the wavelength fluctuation, the light L1 and the light L2 can be reliably received even when the wavelength fluctuation of the first light source and the second light source due to a temperature change or the like occurs. Can be obtained.
[0040]
In the present invention, the common light receiving region is
A parallelogram whose longitudinal direction is parallel to the diffraction direction of the booth grating of the first hologram intersects with a parallelogram whose longitudinal direction is parallel to the diffraction direction of the second hologram booth grating. The opposite corners of the set are included in the other parallelogram.
[0041]
According to the present invention, the common light receiving region includes a parallelogram whose longitudinal direction is parallel to the diffraction direction of the booth grating of the first hologram and a parallelogram whose longitudinal direction is parallel to the diffraction direction of the booth grating of the second hologram. In a crossed shape, a pair of opposing corners of one parallelogram is contained within the other parallelogram. As a result, while receiving two diffracted lights, the light receiving area can be reduced and the perimeter of the light receiving area can be shortened, so that the response speed of the light receiving area can be increased.
[0042]
In the present invention, the first light source and the second light source
A semiconductor laser chip,
The semiconductor laser chip as the first light source and the semiconductor laser chip as the second light source are mounted on one semiconductor substrate.
[0043]
According to the invention, the first light source and the second light source are semiconductor laser chips, and the semiconductor laser chip as the first light source and the semiconductor laser chip as the second light source are mounted on one semiconductor substrate. As a result, the distance between the optical axes of the light emitted from the two laser chips is reduced, so that the hologram laser can be miniaturized.
[0044]
In the present invention, the first light source and the second light source
One semiconductor laser chip is formed by integrating the semiconductor laser element that emits the light L1 and the semiconductor laser element that emits the light L2 on one submount.
[0045]
According to the present invention, the first light source and the second light source are one semiconductor laser chip in which a semiconductor laser element that emits light L1 and a semiconductor laser element that emits light L2 are integrated and formed on one submount. is there. Therefore, the position of the laser light emission point of the semiconductor laser element can be determined by a photomask or the like. As a result, the variation in the optical axis spacing of the light emitted from the two semiconductor laser elements becomes as small as several μm, so that the assembly accuracy of the hologram laser can be improved.
[0046]
The present invention is also characterized in that the arrangement direction of the first light source and the second light source is substantially parallel to the arrangement direction of the first hologram and the second hologram.
[0047]
According to the present invention, since the arrangement direction of the first light source and the second light source is substantially parallel to the arrangement direction of the first hologram and the second hologram, the problem of the arrangement space of the members is solved. Miniaturization of the laser can be realized.
[0048]
  In the present invention, the wavelength separation element isThe reflected light of the light L1 from the optical recording medium is incident light, and the light reflected by the wavelength separation surface is reflected light.The reflectance is 10% or less.
[0049]
According to the present invention, since the reflectance of the wavelength separation element with respect to the light L1 is 10% or less, the light L1 can be incident on the first hologram without being substantially reflected by the wavelength separation element. Thus, since the light quantity reduction of the light L1 by a wavelength separation element is suppressed, the signal of an optical recording medium can be detected accurately.
[0050]
In the present invention, the first light source, the second light source, the light receiving element, the wavelength separation element, the first hologram, the second hologram, and the wavelength separation element are integrated into a package having a substantially oval planar shape. It is characterized by.
[0051]
According to the present invention, the first light source, the second light source, the light receiving element, the wavelength separation element, the first hologram, and the second hologram are integrated into a package having a substantially elliptical planar shape. Therefore, since the light receiving element and the wavelength separation element can be shared by the light L1 and the light L2, it is possible to reduce the number of members and reduce the size of the hologram laser. Further, since the planar shape of the package is an oval, the optical pickup device can be made thinner than a circular package.
[0052]
In the present invention, the first light source and the second light source, the first hologram and the second hologram
It is characterized in that the planar shape is arranged in parallel with the longitudinal direction of the package in a package having a substantially oval shape.
[0053]
According to the present invention, the first light source, the second light source, the first hologram, and the second hologram are arranged in a package having a substantially oval planar shape in parallel with the longitudinal direction of the package. Thinning can be realized.
[0054]
Further, the present invention provides the hologram laser according to any one of the above,
An optical system for guiding light emitted from the hologram laser to the optical recording medium, and guiding reflected light from the optical recording medium to the hologram laser;
An optical pickup device provided in the optical system and including an optical member that rotates a polarization direction of the light L1 emitted from the hologram laser.
[0055]
According to the present invention, it is possible to read or write signals on a plurality of types of optical recording media having different reading wavelengths by using only a single optical pickup device, thereby realizing downsizing of the device and reduction in manufacturing cost. it can.
[0056]
Moreover, the present invention provides the hologram laser,
Provided so that the direction of the dividing line dividing the first hologram and the second hologram into the booth lattice is parallel to the track direction of the optical recording medium in a state where the light emitted from the hologram laser is irradiated onto the optical recording medium It is characterized by being able to.
[0057]
According to the present invention, the hologram laser is provided so that the direction of the dividing line dividing the first and second holograms into the booth lattice is parallel to the track direction of the optical recording medium. The tracking error signal can be detected with high accuracy.
[0058]
DETAILED DESCRIPTION OF THE INVENTION
  FIG. 1 illustrates the present invention.Premise shapeFIG. 2 is a schematic perspective view showing a simplified configuration of an optical pickup device 22 including the hologram laser 21 shown in FIG. 1, and FIG. It is a principal part enlarged view of the optical pick-up apparatus 22 shown in FIG. 1 to 3, a light receiving element 23 described later has a plurality of light receiving regions, but is shown as one light receiving region for convenience.
[0059]
The hologram laser 21 includes a first light source 25 that emits light L1 having a first wavelength toward the optical recording medium 24, a second light source 26 that emits light L2 having a second wavelength toward the optical recording medium 24, and light. The wavelength separation element 27 that separates the light L1 and the light L2 reflected by the recording medium 24, the first hologram 28 that condenses the light L1 separated by the wavelength separation element 27, and the light that is separated by the wavelength separation element 27 The second hologram 29 that condenses L2, the light L1 collected by the first hologram 28 and the light receiving element 23 that receives the light L2 collected by the second hologram 29, and the first light source 25 emit light. And a diffraction grating 30 that diffracts the light L1.
[0060]
The first and second light sources 25 and 26 are, for example, semiconductor laser chips. The first light source 25 emits light L1 that is infrared light having a wavelength of 780 nm, which is used when, for example, the CD 24a that is the optical recording medium 24 is used. The light L1 has a polarization direction parallel to the paper surface of FIG. The second light source 26 emits light L2, which is red light having a wavelength of 650 nm, which is used when, for example, the DVD 24b that is the optical recording medium 24 is used. The light L2 has a polarization direction parallel to the paper surface of FIG.
[0061]
FIG. 4 is a cross-sectional view showing the configuration of the first and second light sources 25 and 26 in a simplified manner. As shown in FIG. 4A, the first semiconductor laser chip 25 that is the first light source 25 and the second semiconductor laser chip 26 that is the second light source 26 are, for example, silicon (chemical formula: Si), silicon carbide (chemical formula). : On a single semiconductor substrate 31 made of SiC) or the like. As a result, the optical axis interval of the light emitted from the first and second semiconductor laser chips 25 and 26 is reduced, so that the hologram laser 21 can be reduced in size. Further, the type of the first and second semiconductor laser chips 25 and 26 can be arbitrarily selected. For example, the first and second semiconductor laser chips 25 and 26 have a wavelength of 780 nm formed by a semiconductor laser element having a high output (30 mW or more) for signal reading and signal writing. One semiconductor laser chip 25 and a second semiconductor laser chip 26 having a wavelength of 650 nm, which is composed of a semiconductor laser element having a low output (about 7 mW) exclusively for signal reading, can be mounted on one semiconductor substrate 31. .
[0062]
As shown in FIGS. 4B to 4D, the first and second light sources 25 and 26 include a first semiconductor laser element 32 that emits light L1 and a second semiconductor laser element 33 that emits light L2. It may be configured as one semiconductor laser chip formed integrally on one submount 34. In such a configuration, since the positions of the laser emission points of the first and second semiconductor laser elements 32 and 33 can be determined by a photomask or the like, the light emitted from the two semiconductor laser elements 32 and 33 The variation in the shaft spacing is as small as several μm. As a result, the assembly accuracy of the hologram laser 21 can be improved.
[0063]
1 to 3, the light receiving element 23 is, for example, a photodiode, receives reflected light from the optical recording medium 24, converts it into a current corresponding to the light intensity, and obtains a detection signal of the reflected light. The first and second light sources 25 and 26 and the light receiving element 23 are provided in a package 37 including a first member 35 and a second member 36 having a substantially oval planar shape. The first and second light sources 25 and 26 and the light receiving element 23 are provided in a heat sink (not shown), and the heat sink is attached to a first member 35 made of metal such as steel. The first and second light sources 25 and 26 are arranged on a first member 35 having a substantially oval shape in parallel with the longitudinal direction of the first member 35. Also, at this time, the first light source 25 has an optical axis 44 of an optical path through which the reflected light of the light L1 emitted from the first light source 25 and reflected by the optical recording medium 24 passes from the optical recording medium 24 through the wavelength separation element 27. Arranged on the extension of The first and second light sources 25 and 26 and the light receiving element 23 are electrically connected to a lead pin (not shown) by a gold wire, and the lead pin is electrically connected to a lead frame 38. A second member 36 made of a metal such as steel is joined to the first member 35 so as to cover the first and second light sources 25 and 26 and the light receiving element 23.
[0064]
The wavelength separation element 27 includes, for example, a wavelength separation surface 39 formed of a wavelength selection filter that separates light according to a difference in wavelength, and a reflection surface 40 that reflects light reflected by the wavelength separation surface 39 toward the second hologram 29. Have. For example, the wavelength separation surface 39 has a characteristic of transmitting most of the reflected light from the optical recording medium 24 with the light L1 having a wavelength of 780 nm and reflecting the reflected light from the optical recording medium 24 with the light L2 having a wavelength of 650 nm. . Since the wavelength separation surface 39 is set so that the reflectance of the reflected light L1 from the optical recording medium is 10% or less, most of the light L1 incident on the wavelength separation element 27 is transmitted through the wavelength separation element 27. The light enters the first hologram 28. This suppresses a decrease in the light amount of the light L1 due to the wavelength separation element 27, so that the signal of the optical recording medium can be detected with high accuracy.
[0065]
The first and second holograms 28 and 29 and the diffraction grating 30 are provided in the first hologram element 41. The first hologram element 41 is made of a rectangular parallelepiped transparent material. The diffraction grating 30 is a plane orthogonal to the optical axis 80 of the light L1 and is formed on the optical axis 80 of the light L1 within one plane 42 on the first light source 25 side. The first hologram 28 and the second hologram 29 are planes orthogonal to the optical axis 80 of the light L1 and are arranged in one plane 43 on the optical recording medium 24 side. The first hologram 28 is an extension of the optical axis 44 of the optical path through which the reflected light of the light L1 emitted from the first light source 25 and reflected by the optical recording medium 24 passes through the wavelength separation element 27 from the optical recording medium 24. Placed on top. Further, the second hologram 29 has an optical axis 45 of the optical path 45 through which the light L2 separated by the wavelength separation surface 39 of the wavelength separation element 27 and reflected by the reflection surface 40 passes from the reflection surface 40 through the wavelength separation element 27. Located on the extension. As described above, since the first and second holograms 28 and 29 are provided on the same optical member, the size of the hologram laser 21 can be reduced.
[0066]
The diffraction grating 30 has, for example, a diffraction characteristic optimized for the light L1 which is light with a CD reading wavelength of 780 nm. The light L1 emitted from the first light source 25 is converted into zero-order diffracted light, + 1st-order diffracted light, and − Diffracted into first-order diffracted light. The three light beams are used to detect the tracking error signal of the optical recording medium 24. The diffraction grating 30 may have a diffraction characteristic optimized for both the light L1 and the light L2, depending on the type of tracking error signal to be detected.
[0067]
The second hologram 29 diffracts the light L <b> 2 separated by the wavelength separation element 27 into −1st order diffracted light, zeroth order diffracted light, and + 1st order diffracted light, and condenses the −1st order diffracted light onto the light receiving element 23. Note that zero-order diffracted light and + 1st-order diffracted light are not used.
[0068]
The first hologram 28 is a polarization hologram 28, and the diffraction efficiency of zero-order diffracted light is approximately 100% with respect to light having the first polarization direction, and the first hologram 28 is perpendicular to the first polarization direction. For light having two polarization directions, the diffraction efficiency of ± 1st order diffracted light is equal to the diffraction efficiency of zeroth order diffracted light, or the diffraction efficiency of ± 1st order diffracted light is larger than that of zeroth order diffracted light. The Therefore, the light having the first polarization direction is transmitted without being diffracted by the first hologram 28, and the light having the second polarization direction is transmitted through the light having the first polarization direction so that the amount of zero-order diffracted light by the first hologram 28 is ± 1st order diffracted light. Is diffracted to be equal to or smaller than. A polarization hologram has a different refractive index from incident light depending on the polarization direction. Such properties are given by selecting the material used to make the polarization hologram. In the first hologram 28, a diffraction grating is formed on the surface that emits diffracted light in the direction of the light receiving element 23, and the emitted diffracted light is diffracted into zero-order diffracted light, + 1st-order diffracted light, and −1st-order diffracted light.
[0069]
The first hologram 28 has a polarization direction parallel to the plane of FIG. 1 which is the polarization direction of the light L1 and the light L2 emitted from the first and second light sources 25 and 26 toward the optical recording medium 24. The first hologram 28 is obtained by setting the polarization direction perpendicular to the paper surface of FIG. 1, which is the polarization direction of the light L1 reflected by the optical recording medium 24 and incident on the first hologram 28, as the second polarization direction. The polarization direction by an optical member that transmits the light L1 and the light L2 emitted from the first and second light sources 25 and 26 toward the optical recording medium 24, reflects from the optical recording medium 24, and rotates the polarization direction of the light L1 described later. Diffracts the rotated light L 1 and guides the + 1st order diffracted light onto the light receiving element 23. Thus, the reflected light of the light L1 diffracted by the first hologram 28 has a zero-order diffracted light amount equal to or smaller than the ± first-order diffracted light amount. Thus, it is possible to eliminate the influence of the zero-order diffracted light on the first light source 25, thereby improving the stability of the oscillation output of the first light source 25.
[0070]
As described above, the first hologram 28 has an optical path through which the reflected light of the light L1 emitted from the first light source 25 and reflected by the optical recording medium 24 passes from the optical recording medium 24 to the wavelength separation element 27. The first light source 25 is also disposed on the extension of the optical axis 44. The first hologram 28 can reduce the diffraction efficiency of the zero-order diffracted light of the reflected light L1 and reduce the influence of the zero-order diffracted light on the output stability of the first light source 25. A first light source 25 can be disposed on the extension of the optical axis 44. Further, the light L1 and the light L2 emitted from the first and second light sources 25 and 26 have the first polarization direction parallel to the paper surface of FIG. This reduces the loss of signal and does not affect signal writing. As a result, the distance between the first light source 25 and the first hologram 28 becomes the shortest, and the hologram laser 21 can be downsized.
[0071]
Further, the first hologram 28 which is the polarization hologram 28 is provided for the light L1 and the light L2 having different wavelengths emitted from the first and second light sources 25 and 26 toward the optical recording medium 24. Thus, a polarization hologram with optimized diffraction efficiency or a polarization hologram with optimized diffraction efficiency for both lights can be used. When using a polarization hologram with the diffraction efficiency optimized for light of one wavelength, the amount of light reaching the optical recording medium 24 may be slightly reduced if light of the other wavelength is transmitted. For this reason, by optimizing the diffraction efficiency of the polarization hologram for the wavelength that requires signal writing to the optical recording medium 24, loss of light amount is suppressed and the light amount necessary for signal writing is maintained. Can do.
[0072]
The first hologram element 41 and the wavelength separation element 27 including the diffraction grating 30 and the first and second holograms 28 and 29 are light L1 and light from the first and second light sources 25 and 26 toward the optical recording medium 24. The second member 36 is provided in this order in the direction in which L2 is emitted. Therefore, the first and second light sources 25 and 26, the light receiving element 23, the wavelength separation element 27, and the first and second holograms 28 and 29 are integrated into the package 37. As a result, the light receiving element 23 and the wavelength separation element 27 can be shared by the light L1 and the light L2, so that the number of members can be reduced and the hologram laser 21 can be downsized.
[0073]
The first hologram element 41 is provided so that the first and second holograms 28 and 29 are arranged in parallel with the longitudinal direction of the package 37 in the same manner as the first and second light sources 25 and 26 described above. When the first and second light sources 25 and 26 are connected, a space is required in the direction in which the first and second light sources 25 and 26 are arranged. With this arrangement, the hologram laser 21 can be thinned. Can be realized. In addition, since the arrangement direction of the first and second light sources 25 and 26 and the arrangement direction of the first and second holograms 28 and 29 are substantially parallel to each other and arranged in the package 37 in parallel with the longitudinal direction of the package 37, The problem of the member space connection is solved, and the size of the hologram laser 21 can be reduced.
[0074]
Light L1 and light L2 emitted from the first and second light sources 25 and 26 pass through a glass window (not shown) provided in the second member 36 and enter the first hologram element 41. It is desirable that the space between the first hologram element 41 and a glass window (not shown) be sealed with dry air or the like to prevent dew condensation, or vented to the outside. Although the first hologram element 41 can be used instead of the glass window, the first hologram element 41, the second member 36 is provided with a glass window separately from the first hologram element 41, Before the wavelength separation element 27 is provided on the second member 36, the positions of the first and second light sources 25 and 26, the light receiving element 23, etc. can be confirmed, so that the operation procedure for producing the hologram laser 21 can be reduced. Time can be reduced.
[0075]
FIG. 5 is a perspective view showing a state where the first light source 25 is operating in the hologram laser 21 shown in FIG. 1, and FIG. 6 is a state where the second light source 26 is operating in the hologram laser 21 shown in FIG. FIG. 7 is a diagram showing an optical relationship between the first and second holograms 28 and 29 and the light receiving element 23. In order to facilitate understanding in FIG. 5, the diffracted light by the first hologram 28 shows zero-order diffracted light as a representative example among the diffracted light by each of the booth gratings.
[0076]
The first hologram 28 is divided into two semicircular first and second booth gratings 47 and 48, and the diffraction directions of the booth gratings 47 and 48 are set to be different from each other. The second hologram 29 is divided into three semicircular third booth gratings 49 and two quarter-circle fourth and fifth booth gratings 50 and 51, and each of the booth gratings 49, 50 and 51 is divided into three quarters. The diffraction directions are set to be different from each other. In FIG. 7, the black semicircle indicates the light spot of the light L <b> 1 diffracted by the first hologram 28, and the white semicircle and the quarter circle indicate the light spot of the light L <b> 2 diffracted by the second hologram 29. Indicates. The diffraction direction of each of the booth gratings 47 and 48 of the first hologram 28 indicated by an arrow represents the diffraction direction of the zero-order diffracted light among the diffracted lights by the respective booth gratings 47 and 48 as a representative example.
[0077]
As the performance of the booth grating, the diffraction efficiency of zero-order diffracted light and ± first-order diffracted light and the ratio of each diffraction efficiency are important. The lattice pitches of the booth gratings 47 and 48 of the first hologram 28 are substantially equal to each other, and the lattice pitches of the booth gratings 49, 50 and 51 of the second hologram 29 are preferably substantially equal to each other. As a result, the diffraction efficiencies of the respective booth gratings coincide with each other, and in particular, the ratio of the diffraction efficiencies can be made constant. As a result, the reading operation is stabilized, and the first and second holograms 28 and 29 can be easily manufactured. Further, by making the grating pitch of each of the booth gratings 47 and 48 of the first hologram 28 substantially equal to the grating pitch of each of the booth gratings 49, 50 and 51 of the second hologram 29, the first and second holograms 28, The diffraction efficiencies of 29 coincide with each other, the reading operation is stabilized, and the first and second holograms 28 and 29 can be easily manufactured.
[0078]
Since the diffraction directions of the first and second holograms 28 and 29 are substantially parallel to the arrangement direction of the first and second holograms 28 and 29, the first and second holograms 28 and 29 and the light receiving element 23 are aligned with each other. Can be placed on the line. As a result, the size of the hologram laser 21 can be reduced.
[0079]
The direction of the dividing lines 52 and 53 that divide the first and second holograms 28 and 29 into the booth gratings is parallel to the diffraction direction of the first and second holograms 28 and 29. The light receiving element 23 for receiving light can be arranged perpendicular to the diffraction direction. As a result, the size of the hologram laser 21 can be reduced.
[0080]
The light receiving element 23 is disposed between the axis 54 of the first hologram 28 and the axis 55 of the second hologram 29 in the arrangement direction of the first hologram 28 and the second hologram 29, and more preferably the first hologram 28. The axis 55 of the second hologram 29 on which the light L2, which is light of the short wavelength of the light L1 and the light L2, is incident on an intermediate point where the distance from the axis 54 of the second hologram 29 is equal to the distance from the axis 55 of the second hologram 29. Arranged closer.
[0081]
By arranging between the axis 54 of the first hologram 28 and the axis 55 of the second hologram 29, the + 1st order diffracted light of the light L1 and the -1st order diffracted light of the light L2 are received on the same light receiving element 23. And the diffraction angle can be reduced. A hologram having a small diffraction angle can have a large grating pitch. In addition, when the grating pitch of the hologram is the same, the diffraction angle of the short wavelength light is smaller than that of the long wavelength light, so the second hologram in which the light L2 having a short wavelength is incident on the intermediate point. By arranging the light receiving element 23 close to the axis 55 of 29, the grating pitch of the first hologram 28 and the grating pitch of the second hologram 29 are substantially equal to each other and set to the largest grating pitch that can be taken in common. Thus, the first and second holograms 28 and 29 can be easily manufactured. Further, the grating pitches of the booth gratings 47 and 48 of the first hologram 28 are made substantially equal to each other, and the grating pitches of the booth gratings 49, 50 and 51 of the second hologram 29 are made to be substantially equal to each other, whereby the diffraction pitch described above is obtained. The first and second holograms 28 and 29 having the above can be easily manufactured. Since the diffraction efficiencies of the first and second holograms 28 and 29 are equal, the signal reading operation can be stabilized.
[0082]
The light receiving element 23 has a plurality of light receiving regions that receive light diffracted by the respective booth gratings 47, 48, 49, 50, and 51 of the first and second holograms 28 and 29, and each of the light receiving regions S1 to S10. Is selectively used to generate a focus error signal (abbreviated as FES), an RF signal, and a tracking error signal (abbreviated as TES) when reading CD24a and DVD24b. Here, the RF signal is an information signal including a high frequency modulation component including information recorded on the optical recording medium 24 by pits.
[0083]
The + 1st order diffracted light diffracted by the first hologram 28 and the −1st order diffracted light diffracted by the second hologram 29 are received by the same light receiving element 23. On the other hand, when the separation of the reflected light of the light L1 and the reflected light of the light L2 by the wavelength separation element 27 is not complete, a part of the reflected light of the light L1 enters the second hologram 29 or one of the reflected light of the light L2 May enter the first hologram 28. Although a part of the incident light L1 and light L2 is diffracted and condensed in the direction of the light receiving element 23, the focal positions of the diffracted light L1 and light L2 move in parallel to the diffraction direction from the original focal position. To do. For example, when the light L1 reflected by the optical recording medium 24 enters the second hologram 29, the wavelength of the light L1 is longer than the wavelength of the light L2, so that the diffraction angle becomes large and deviates from the normal light receiving region. When the light L2 received at a position near the first hologram 28 and reflected from the optical recording medium 24 enters the first hologram 28, the diffraction angle is small because the wavelength of the light L2 is shorter than the wavelength of the light L1. Thus, the light is received at a position near the first hologram 28 outside the normal light receiving region. For this reason, by arranging the respective light receiving regions in a direction perpendicular to the arrangement direction of the first and second holograms 29, it is possible to prevent unnecessary light incident on the regular light receiving regions due to poor wavelength separation. .
[0084]
Further, since the first hologram 28 is the polarization hologram 28, the amount of light that is diffracted by the light L2 incident on the first hologram 28 is small. Therefore, by setting the light transmission and / or reflection function of the wavelength separation element 27 with respect to the light L1 optimally, it is possible to suppress the light L1 and the light L2 from being received out of the normal light receiving region.
[0085]
The light receiving element 23 is provided so that the longitudinal direction of each light receiving region is parallel to the diffraction directions of the first hologram 28 and the second hologram 29. The length in the longitudinal direction is formed to be longer than the focal position variation range due to the wavelength variation of the first light source 25 and the second light source 26. This makes it possible to reliably receive the light L1 and the light L2 and obtain a desired signal even when the wavelength variation of the first light source 25 and the second light source 26 occurs due to a temperature change or the like. If the longitudinal direction is too long, the capacitance increases and the response speed of the light receiving region decreases, so the capacitance is formed to a length that does not affect the response speed.
[0086]
Each of the light receiving regions S1 to S10 detects a light receiving region for detecting the diffracted light of the light L1 including the RF signal, the diffracted light of the light L2, and the diffracted light of the light L2 including the TES, and the diffracted light of the light L1 including the TES. It is divided into a light receiving area and a light receiving area for canceling stray light to the FES generated when reading the DVD 24b which is a double-layer disc.
[0087]
Light receiving regions S2, S5, S6, S7, S8 for receiving diffracted light by the first and second booth gratings 47, 48 of the first hologram 28 and the third to fifth booth gratings 49, 50, 51 of the second hologram 29. , S10 detects the RF signal of the CD 24a and the RF signal of the DVD 24b, and detects the phase difference (Differential Phase Detection: DPD) signal that is the TES of the DVD 24b based on the detection outputs of the light receiving areas S2 and S10. Is done. Further, based on the detection outputs of the light receiving areas S5, S6, S7, and S8, the FES at the time of reading the CD 24a and the DVD 24b is detected by, for example, the knife edge method, the spot size method, or the like. As described above, a high response speed can be achieved by sharing a light receiving area for detecting a signal that includes a high frequency component such as an RF signal and a DPD signal and that needs to read a reproduction signal of the optical recording medium 24 at a high speed. The number of light receiving areas required can be reduced.
[0088]
In addition, since the diffracted light by the first booth grating 47 of the first hologram 28 and the diffracted light by the fifth booth grating 51 of the second hologram 29 are incident on the light receiving region S2, the light receiving region S2 is long in the diffraction direction of each diffracted light. Two parallelograms having parallel directions intersect each other, and one set of opposite corners of one parallelogram is included in the other parallelogram. As a result, while receiving two diffracted lights, the light receiving area can be reduced and the perimeter of the light receiving area can be shortened, so that the response speed of the light receiving area can be increased.
[0089]
Further, based on the detection output of the light receiving regions S1, S3, S4, and S9 that receive the diffracted light by the first and second booth gratings 47 and 48 of the first hologram 28, the TES of the CD 24a is detected by, for example, the three beam method. . The light receiving areas S1, S3, S4 and S9 are not required to have a fast response speed. The light receiving areas S5 and S8 are light receiving areas for canceling stray light to the FES generated when reading the DVD 24b, which is a double-layer disc. Light is not incident during signal reproduction, and a high response speed is not required. .
[0090]
In the light receiving areas S1 to S10, the light receiving areas S1 and S4, which are the light receiving areas for detecting the same signal to reduce the number of output terminals of the hologram laser 21, the light receiving areas S3 and S9, and the light receiving areas S5 and S7. The light receiving area S6 and the light receiving area S8 may be internally connected.
[0091]
  The hologram laser 21 having the above configuration is provided.Other shapesThe optical pickup device 22 is an optical system 56 for guiding the light emitted from the hologram laser 21 to the optical recording medium 24 and guiding the reflected light from the optical recording medium 24 to the hologram laser 21, and the optical system 56. And an optical member 57 that rotates the polarization direction of the light L1 emitted from the hologram laser 21.
[0092]
In the hologram laser 21, the planar shape of the package 37 is substantially oval, so that the optical pickup device 22 can be made thinner than the circular package 37. The package 37 is arranged around the optical axis 80 of the light L1 in order to adjust the irradiation position of the zero-order diffracted light, the + 1st-order diffracted light, and the −1st-order diffracted light diffracted by the diffraction grating 30 to the optimum position. It is mounted on the optical pickup device 22 so that the angular displacement can be adjusted. In the hologram laser 21, the division line 64 that divides the second hologram 29 into the fourth and fifth booth gratings 50 and 51 in the state where the optical recording medium 24 is irradiated with the light emitted from the hologram laser 21 is optically recorded. The package 37 is provided by adjusting the angular displacement around the optical axis 80 of the light L1 so as to be parallel to the track direction of the medium 24. This makes it possible to accurately detect the DPD signal that is the TES of the DVD 24b.
[0093]
The optical system 56 includes a collimating lens 65, an objective lens 66, and an optical member 57 that rotates the polarization direction of the light L1 emitted from the hologram laser 21. The collimator lens 65 makes the light L1 and the light L2 emitted from the hologram laser 21 substantially parallel and collects the reflected light of the light L1 and the light L2 from the optical recording medium 24 toward the hologram laser 21. The objective lens 66 condenses the light L1 and the light L2 on the recording surface of the optical recording medium 24. The CD 24a and the DVD 24b, which are two types of optical recording media 24 used for signal recording or reproduction, have different thicknesses from the surface to the signal recording surface, so that the objective lens corresponds to each optical recording medium 24. It can be switched to. As the objective lens, a bifocal objective lens may be used so as to be compatible with two different types of optical recording media 24.
[0094]
The optical member 57 that rotates the polarization direction of the light L1 emitted from the hologram laser 21 is, for example, a quarter-wave plate 57, and is disposed between the collimating lens 65 and the objective lens 66. The quarter-wave plate 57 rotates the polarization direction by 45 degrees only with respect to the light L1.
[0095]
Next, the signal reading operation of the optical recording medium 24 will be described. Since the hologram laser 21 includes the first and second light sources 25 and 26, one of the first and second light sources 25 and 26 is automatically selected according to the type of the optical recording medium 24 to be used. When the CD 24a is used for the optical recording medium 24, the first light source 25 is selected and the light L1 is emitted. The light L1 emitted from the first light source 25 is diffracted by the diffraction grating 30 into zero-order diffracted light, + 1st-order diffracted light, and −1st-order diffracted light. The light L1 has a polarization direction parallel to the paper surface of FIG. The light L1 that has passed through the first hologram 28 passes through the wavelength separation element 27 and is converted into parallel light by the collimator lens 65, and then enters the quarter-wave plate 57 to rotate the polarization direction by 45 degrees. The light L1 whose polarization direction has been rotated is collected on the CD 24a by the objective lens 66.
[0096]
The light L1 reflected from the CD 24a passes through the objective lens 66, and the polarization direction is further rotated 45 degrees by the quarter-wave plate 57 to become a polarization direction perpendicular to the paper surface of FIG. It is condensed in the direction of 21. The light incident on the wavelength separation element 27 again passes through the wavelength separation surface 39 and enters the first hologram 28 to be diffracted.
[0097]
When the DVD 24b is used as the optical recording medium 24, the second light source 26 is selected and the light L2 is emitted. Light L2 emitted from the second light source 26 and having a polarization direction parallel to the paper surface of FIG. 1 passes through the diffraction grating 30, the first hologram 28, and the wavelength separation element 27, and is collimated by the collimator lens 65. The parallel light L2 passes through the quarter-wave plate 57 and is condensed on the DVD 24b by the objective lens 66.
[0098]
The light L2 reflected from the DVD 24b passes through the objective lens 66 and the quarter-wave plate 57 and is condensed in the direction of the hologram laser 21 by the collimator lens 65. The light incident on the wavelength separation element 27 again is reflected by the wavelength separation surface 39 and the reflection surface 40, enters the second hologram 29, and is diffracted.
[0099]
The light incident on the first and second holograms 28 and 29 is diffracted by the respective booth gratings 47, 48, 49, 50 and 51 and received by the plurality of light receiving regions S1 to S10. The detection output of each light receiving area is selectively used to generate FES, RF signal, and TES when reading CD24a and DVD24b to obtain a desired signal.
[0100]
The configuration of the first hologram and the light receiving element provided in the hologram laser 21 may be as follows. FIG. 8 is a diagram showing an optical relationship between the first and second holograms 58 and 29 and the light receiving element 59. The first hologram 58 is divided into three semicircular sixth booth gratings 60 and two quarter-circular seventh and eighth booth gratings 61 and 62. The light receiving element 59 has a plurality of light receiving regions D1 to D10 that receive light diffracted by the respective booth gratings 60, 61, 62, 49, 50, and 51 of the first hologram 58 and the second hologram 29, respectively. The light receiving areas D1 to D10 are selectively used to generate FES, RF signals, and TES when reading the CD 24a and reading the DVD 24b.
[0101]
Receives diffracted light from the sixth, seventh and eighth booth gratings 60, 61 and 62 of the first hologram 58 and diffracted light from the third, fourth and fifth booth gratings 49, 50 and 51 of the second hologram 29. Based on the detection outputs of the light receiving regions D2, D4, D5, D6, D7, and D9, the RF signals of the CD 24a and the DVD 24b are detected. Further, for example, a DPD signal that is a TES of the DVD 24b is detected based on detection outputs of the light receiving areas D2 and D9. Further, based on the detection outputs of the light receiving regions D4, D5, D6, and D7, the FES at the time of reading the CD 24a and the DVD 24b is detected by, for example, the knife edge method.
[0102]
The light receiving regions D2 and D9 have a shape in which two parallelograms whose longitudinal directions are parallel to the diffraction direction of each diffracted light intersect, and a pair of opposite corners of one parallelogram is the inner side of the other parallelogram. include.
[0103]
Light receiving regions D1, D3, D8, and D10 that receive the diffracted light by the seventh and eighth booth gratings 61 and 62 of the first hologram 58 and the diffracted light by the fourth and fifth booth gratings 50 and 51 of the second hologram 29. Detects the light L1 including the TES of the CD 24a. Based on the detection outputs of the light receiving areas D1, D3, D8, D10 and the light receiving areas D2, D9, the TES of the CD 24a is detected by, for example, a differential push pull (abbreviated as DPP) method. The light receiving areas D4 and D7 are light receiving areas for canceling stray light when reading a dual-layer disc of the DVD 24b.
[0104]
The light receiving region D1 and the light receiving region D3, the light receiving region D4 and the light receiving region D6, the light receiving region D5 and the light receiving region D7, and the light receiving region D8 and the light receiving region D10 can be internally connected.
[0105]
The hologram laser 21 generates seventh and eighth booths that generate diffracted light including TES in the first hologram 58 and the second hologram 29 in a state where the optical recording medium 24 is irradiated with light emitted from the hologram laser 21. The dividing lines 63 and 64 dividing the gratings 61 and 62 and the fourth and fifth booth gratings 50 and 51 are provided so as to be parallel to the track direction of the optical recording medium 24. As a result, the DPD signal and TES of the optical recording medium 24 can be detected with high accuracy.
[0106]
  Fig. 9, Other shapesIt is a systematic diagram which simplifies and shows the structure of the other optical pick-up apparatus 67 which is a state. Another optical pickup device 67 includes the hologram laser 21 and an optical system 68, and the optical system 68 further includes a rising mirror 69. Since the light emitted from the hologram laser 21 is bent 90 degrees in the direction of the optical recording medium 24 by the rising mirror 69, the thickness of the other optical pickup device 67 can be reduced. Even when the hologram laser 21 is provided in the other optical pickup device 67 having such a configuration, the dividing lines 63 of the first and second holograms 58 and 29 are considered in consideration of the bending of the light by the rising mirror 69 as a straight line. It is desirable to provide the hologram laser 21 so that the direction 64 is parallel to the track direction of the optical recording medium 24.
[0107]
  Less thanupperAccording to the embodiment, it is possible to suppress the light amount loss of the light condensed on the optical recording medium 24, and it is possible to read and write information with high accuracy. In addition, it is possible to read and write signals with respect to a plurality of types of optical recording media 24 having different reading wavelengths by using only a single optical pickup device 22, and it is possible to reduce the size of the device and reduce the manufacturing cost.
[0108]
  FIG. 10 shows the present invention.The fruitFIG. 11 is a simplified perspective view showing a configuration of a hologram laser 70 according to the embodiment, and FIG. 11 is a schematic sectional view showing a simplified configuration of an optical pickup device 71 including the hologram laser 70 shown in FIG. 12 is an enlarged view of a main part of the optical pickup device 71 shown in FIG. The hologram laser 70 of the present embodiment isThe above is the premise of the present inventionThe same reference numerals are assigned to the corresponding parts, and description thereof is omitted. It should be noted that the first hologram 28 and the second hologram 29 are respectively provided on the second hologram element 72 and the third hologram element 73 which are different optical members. Although the light receiving element 23 has a plurality of light receiving regions, it is shown here as one light receiving region for convenience.
[0109]
The second hologram element 72 and the third hologram element 73 are located between the first and second light sources 25 and 26 and the wavelength separation element 27 and are directed from the first and second light sources 25 and 26 toward the optical recording medium 24. The second member 36 is provided in this order in the direction in which the light L1 and the light L2 are emitted. The first hologram 28 is an extension of the optical axis 44 of the optical path through which the reflected light of the light L1 emitted from the first light source 25 and reflected by the optical recording medium 24 passes through the wavelength separation element 27 from the optical recording medium 24. The second hologram element 72, which is a plane orthogonal to the optical axis 80 of the light L <b> 1, is disposed in one plane 74 on the optical recording medium 24 side so as to be positioned above. The first light source 25 is disposed on the optical axis 80. The second hologram 29 is an extension of the optical axis 45 of the optical path through which the light L2 separated by the wavelength separation surface 39 of the wavelength separation element 27 and reflected by the reflection surface 40 passes from the reflection surface 40 through the wavelength separation element 27. The third hologram element 73, which is a plane orthogonal to the optical axis 80 of the light L <b> 1, is disposed on one plane 75 on the optical recording medium 24 side so as to be positioned above.
[0110]
The second hologram 29 may be provided in one plane 76 on the first light source 25 side of the wavelength separation element 27 which is a plane orthogonal to the optical axis 80 of the light L1. With such a configuration, even if the position of the wavelength separation element 27 is adjusted, the positional relationship between the wavelength separation element 27 and the second hologram 29 does not change. The package may be a lead frame 77 molded with resin.
[0111]
  RealAccording to the embodiment, since the first hologram 28 and the second hologram 29 are arranged on different members, the relative positions of the first hologram 28 and the second hologram 29 and other members are individually adjusted. As a result, assembly adjustment is facilitated.
[0112]
【The invention's effect】
As described above, according to the present invention, by providing a polarization hologram in a hologram laser, signals for a plurality of types of optical recording media having different reading wavelengths can be obtained using the first wavelength light L1 and the second wavelength light L2. Reading or writing can be performed with high accuracy.
[0113]
Further, by sharing and arranging the optical members, it is possible to reduce the number of members, reduce the size and thickness of the hologram laser and the optical pickup device, and reduce the manufacturing cost.
[0114]
Further, according to the present invention, simplification of the light receiving element and faster response can be realized by devising the arrangement and shape of the light receiving region in the light receiving element.
[Brief description of the drawings]
FIG. 1 of the present inventionPremise shapeIt is a perspective view which simplifies and shows the structure of the hologram laser 21 which is a state.
2 is a schematic cross-sectional view showing a simplified configuration of an optical pickup device 22 including the hologram laser 21 shown in FIG.
FIG. 3 is an enlarged view of a main part of the optical pickup device 22 shown in FIG.
FIG. 4 is a cross-sectional view showing the configuration of first and second light sources 25 and 26 in a simplified manner.
5 is a perspective view showing a state where a first light source 25 is operating in the hologram laser 21 shown in FIG. 1. FIG.
6 is a perspective view showing a state in which a second light source 26 is operating in the hologram laser 21 shown in FIG. 1. FIG.
7 is a view showing an optical relationship between the first and second holograms 28 and 29 and the light receiving element 23. FIG.
8 is a diagram showing an optical relationship between the first and second holograms 58 and 29 and the light receiving element 59. FIG.
FIG. 9Other shapesIt is a systematic diagram which simplifies and shows the structure of the other optical pick-up apparatus 67 which is a state.
FIG. 10 shows the present invention.The fruitIt is a perspective view which simplifies and shows the structure of the hologram laser 70 which is embodiment.
11 is a schematic cross-sectional view showing a simplified configuration of an optical pickup device 71 including the hologram laser 70 shown in FIG.
12 is an enlarged view of a main part of the optical pickup device 71 shown in FIG.
13 is a perspective view showing a simplified configuration of a conventional hologram laser 1. FIG.
14 is a system diagram showing a simplified configuration of an optical pickup device 2 including the hologram laser 1 shown in FIG.
[Explanation of symbols]
21, 70 Hologram laser
22, 67, 71 Optical pickup device
23, 59 Light receiving element
24 Optical recording media
25 First light source
26 Second light source
27 Wavelength separation element
28,58 1st hologram
29 Second hologram
30 diffraction grating
37 packages
38,77 Lead frame
39 Wavelength separation surface
40 Reflective surface
41 First hologram element
56 Optical system
72 Second hologram element
73 Third hologram element

Claims (23)

In a hologram laser that emits light toward an optical recording medium on which information is recorded or reproduced by light and receives reflected light from the optical recording medium,
A first light source that emits light L1 having a first wavelength toward the optical recording medium;
A second light source that emits light L2 of the second wavelength toward the optical recording medium;
A wavelength separation element for separating the light L1 and the light L2 reflected by the optical recording medium;
A first hologram for condensing the light L1 separated by the wavelength separation element;
A second hologram for condensing the light L2 separated by the wavelength separation element;
A light receiving element that receives the light L1 collected by the first hologram and the light L2 collected by the second hologram ;
A hologram element provided with the first hologram;
The other hologram element provided with the second hologram ,
Said first hologram, Ri polarization hologram der the diffraction efficiency varies depending on polarization directions of incident light,
The one hologram element and the other hologram element are between the first light source, the second light source, and the wavelength separation element, and are directed from the first light source and the second light source toward the optical recording medium. Provided in this order in the direction in which the light L1 and the light L2 are emitted,
The first hologram is an extension of the optical axis of the optical path through which the reflected light of the light L1 emitted from the first light source and reflected by the optical recording medium passes from the optical recording medium through the wavelength separation element. Is located in one plane on the optical recording medium side of the one hologram element, which is a plane orthogonal to the optical axis of the light L1,
The second hologram is positioned on an extension of the optical axis of the optical path through which the light L2 separated by the wavelength separation surface of the wavelength separation element and reflected by the reflection surface passes from the reflection surface to the wavelength separation element. As described above , the hologram laser is arranged in one plane on the optical recording medium side of the other hologram element, which is a plane orthogonal to the optical axis of the light L1 . The polarization hologram as the first hologram is
For light having the first polarization direction, zero-order diffracted light is transmitted,
For light having a second polarization direction that is perpendicular to the first polarization direction, the diffraction efficiency of plus and minus (±) first-order diffracted light is equal to the diffraction efficiency of zero-order diffracted light, or ± first-order diffracted light The hologram laser according to claim 1, wherein the diffraction efficiency of is higher than that of zero-order diffracted light. Reflected light of the light L1 emitted from the first light source and reflected by the optical recording medium is on the extension of the optical axis of the optical path that passes from the optical recording medium through the wavelength separation element, and the first hologram and the first light 3. The hologram laser according to claim 1, wherein one light source is arranged. The diffraction directions of the first hologram and the second hologram are:
The hologram laser according to claim 1, wherein the hologram laser is substantially parallel to an arrangement direction of the first hologram and the second hologram. The first hologram and the second hologram have a plurality of booth lattices,
5. The direction of at least one dividing line for dividing the first hologram and the second hologram into the booth gratings is parallel to the diffraction directions of the first and second holograms, respectively. Hologram laser. The lattice pitch of each booth lattice of the first hologram is substantially equal to each other,
6. The hologram laser according to claim 5, wherein the lattice pitches of the respective booth gratings of the second hologram are substantially equal to each other. 7. The hologram laser according to claim 6, wherein the lattice pitch of each of the booth gratings of the first hologram and the grating pitch of each of the booth gratings of the second hologram are substantially equal to each other. The hologram laser according to claim 1, wherein the first hologram and the second hologram are provided on one optical member. The hologram laser according to claim 1, wherein the first hologram and the second hologram are provided on different optical members. The light receiving element is
The hologram laser according to any one of claims 1 to 9, wherein the hologram laser is disposed between an axis of the first hologram and an axis of the second hologram in the arrangement direction of the first hologram and the second hologram. The light receiving element is
In the arrangement direction of the first hologram and the second hologram, the light L1 emitted from the first light source or the intermediate point where the distance from the axis of the first hologram is equal to the distance from the axis of the second hologram 11. The light L2 emitted from the second light source is disposed near the axis of the hologram on which the reflected light from the optical recording medium having a shorter wavelength is incident. Hologram laser. The light receiving element is
A plurality of light receiving regions for receiving light diffracted by the respective booth gratings of the first hologram and the second hologram;
12. The diffracted light of the light L1 including the RF signal, the diffracted light of the light L2, and the diffracted light of the light L2 including the tracking error signal are detected by a common light receiving region. The hologram laser described. The plurality of light receiving areas are:
13. The hologram laser according to claim 12, wherein the hologram laser is arranged perpendicular to the arrangement direction of the first hologram and the second hologram. The light receiving element is
The longitudinal direction of each light receiving region is provided in parallel with the diffraction direction of the first hologram and the second hologram,
The hologram laser according to claim 12 or 13, wherein the length in the longitudinal direction is formed to be longer than a fluctuation range of an incident position due to a wavelength fluctuation of the first light source and the second light source. The common light receiving region is
A parallelogram whose longitudinal direction is parallel to the diffraction direction of the booth grating of the first hologram intersects with a parallelogram whose longitudinal direction is parallel to the diffraction direction of the booth grating of the second hologram. The hologram laser according to any one of claims 12 to 14, wherein one set of facing corners is included in the other parallelogram. The first light source and the second light source are
A semiconductor laser chip,
16. The hologram laser according to claim 1, wherein the semiconductor laser chip as the first light source and the semiconductor laser chip as the second light source are mounted on one semiconductor substrate. The first light source and the second light source are
16. The semiconductor laser chip according to claim 1, wherein the semiconductor laser element that emits the light L1 and the semiconductor laser element that emits the light L2 are integrated and formed on one submount. The hologram laser according to claim 1. The hologram laser according to claim 1, wherein the arrangement direction of the first light source and the second light source is substantially parallel to the arrangement direction of the first hologram and the second hologram. The wavelength separation element is
19. The reflectance when the reflected light from the optical recording medium of the light L1 is incident light and the light reflected by the wavelength separation surface is reflected light is 10% or less. The hologram laser according to claim 1. 20. The first light source, the second light source, the light receiving element, the wavelength separation element, the first hologram, and the second hologram are integrated into a package having a substantially oval planar shape. The hologram laser according to any one of the above. The first light source and the second light source, the first hologram and the second hologram are:
21. The hologram laser according to claim 1, wherein the hologram laser is disposed in a package having a substantially oval planar shape in parallel with a longitudinal direction of the package. The hologram laser according to any one of claims 1 to 21,
An optical system for guiding light emitted from the hologram laser to the optical recording medium, and guiding reflected light from the optical recording medium to the hologram laser;
An optical pickup device provided in the optical system and including an optical member that rotates the polarization direction of the light L1 emitted from the hologram laser. The hologram laser is
Provided so that the direction of the dividing line that divides the first hologram and the second hologram into the booth lattice is parallel to the track direction of the optical recording medium in a state where the light emitted from the hologram laser is irradiated onto the optical recording medium The optical pickup device according to claim 22, wherein the optical pickup device is used.

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