U.S. patent number RE42,825 [Application Number 11/805,282] was granted by the patent office on 2011-10-11 for optical pickup head device, information recording/reproducing apparatus, and method for recording information.
This patent grant is currently assigned to Panasonic Corporation. Invention is credited to Shin-Ichi Kadowaki, Yoshiaki Komma, Kousei Sano.
United States Patent |
RE42,825 |
Kadowaki , et al. |
October 11, 2011 |
**Please see images for:
( Certificate of Correction ) ** |
Optical pickup head device, information recording/reproducing
apparatus, and method for recording information
Abstract
An optical pickup head device includes a diffraction grating for
generating zero-order diffracted light and at least first-order
diffracted light and provides a tracking error signal with a DPP
method. The diffraction grating includes grating patterns with a
nonuniform period or phase. The size of the first-order diffracted
light converged on an optical recording medium is larger in the
direction parallel to a tangent to the track than in the direction
perpendicular to the tangent. P1/P0>PW2/PW1 is established,
where PW1 represents the power that is required to record
information on the optical recording medium, PW2 represents the
maximum power that allows information recorded on the optical
recording medium to be reproduced without being erased, P0
represents the light amount of the zero-order diffracted light
converged on the optical recording medium, and P1 represents the
light amount of the at least first-order diffracted light converged
on the optical recording medium. This configuration makes it
possible to detect a tracking error signal with reduced offset,
even if a recordable optical recording medium having two
information recording planes is used.
Inventors: |
Kadowaki; Shin-Ichi (Hyogo,
JP), Komma; Yoshiaki (Osaka, JP), Sano;
Kousei (Osaka, JP) |
Assignee: |
Panasonic Corporation (Osaka,
JP)
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Family
ID: |
19104012 |
Appl.
No.: |
11/805,282 |
Filed: |
May 22, 2007 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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Reissue of: |
10235625 |
Sep 4, 2002 |
6898169 |
May 24, 2005 |
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Foreign Application Priority Data
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Sep 14, 2001 [JP] |
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2001-279922 |
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Current U.S.
Class: |
369/112.12;
369/112.04; 369/110.03; 369/109.02 |
Current CPC
Class: |
G11B
7/094 (20130101); G11B 7/0903 (20130101); G11B
7/0055 (20130101); G11B 2007/0013 (20130101) |
Current International
Class: |
G11B
7/00 (20060101) |
Field of
Search: |
;369/103,112.01,112.1,112.15,44.24,44.23,44.37,112.12,109.02,112.04,110.03,112.02 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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0 762 396 |
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Mar 1997 |
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EP |
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61-233445 |
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Oct 1986 |
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JP |
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7-192287 |
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Jul 1995 |
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JP |
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7-192306 |
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Jul 1995 |
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JP |
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9-81942 |
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Mar 1997 |
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JP |
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9-161295 |
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Jun 1997 |
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JP |
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2000-331370 |
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Nov 2000 |
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JP |
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Primary Examiner: Hindi; Nabil Z
Attorney, Agent or Firm: Hamre, Schumann, Mueller &
Larson, P.C.
Claims
What is claimed is:
1. An optical pickup head device comprising: a light source for
emitting a light beam; a diffraction means for diffracting the
light beam from the light source into a plurality of beams of
zero-order diffracted light and at least first-order diffracted
light; a convergence means for converging the beams from the
diffraction means on an optical recording medium; a beam splitting
means for splitting the beams reflected from the optical recording
medium; and a photodetection means for receiving the beams from the
beam splitting means and outputting a signal that corresponds to an
amount of light received, wherein the optical recording medium
comprises tracks for recording information, the diffraction means
comprises grating patterns with a nonuniform period or phase, a
size of the at least first-order diffracted light converged on the
optical recording medium is larger in a direction parallel to a
tangent to the track than in a direction perpendicular to the
tangent, and P1/P0>PW2/PW1 is established, where PW1 represents
power of the zero-order diffracted light converged on the optical
recording medium that is required to record information on the
optical recording medium, PW2 represents maximum power of the
zero-order diffracted light converged on the optical recording
medium that allows information recorded on the optical recording
medium to be reproduced without being erased, P0 represents a light
amount of the zero-order diffracted light converged on the optical
recording medium, and P1 represents a light amount of one of the at
least first-order diffracted light converged on the optical
recording medium.
2. The optical pickup head device according to claim 1, wherein the
period of the grating patterns formed on the diffraction means
changes gradually.
3. The optical pickup head device according to claim 1, wherein the
grating patterns on both sides of a central portion of the
diffraction means differ from each other in phase.
4. The optical pickup head device according to claim 3, wherein the
phases of the grating patterns on both sides of the central portion
are reversed by 180 degrees with respect to each other.
5. The optical pickup head device according to claim 3, wherein the
central portion has a different grating pattern from the grating
patterns on both sides of the central portion, and the phases of
the grating patterns on both sides of the central portion are
reversed by 180 degrees with respect to each other.
6. The optical pickup head device according to claim 1, wherein the
diffraction means comprises a first pattern region, a second
pattern region, and a third pattern region, the first pattern
region is sandwiched between the second pattern region and the
third pattern region, and a grating pattern is formed in the first
pattern region and not in the second pattern region and the third
pattern region.
7. The optical pickup head device according to claim 1, wherein the
diffraction means comprises a first pattern region, a second
pattern region, and a third pattern region, the first pattern
region is sandwiched between the second pattern region and the
third pattern region, and a grating pattern formed in the first
pattern region differs from that formed in the second pattern
region and the third pattern region.
8. The optical pickup head device according to claim 6, wherein an
average depth of the grating pattern formed in the first pattern
region is equal to an average depth of each of the second pattern
region and the third pattern region.
9. The optical pickup head device according to claim 7, wherein an
average depth of the grating pattern formed in the first pattern
region is equal to an average depth of each of the second pattern
region and the third pattern region.
10. The optical pickup head device according to claim 1, wherein a
plurality of diffracted light beams converged on the optical
recording medium have the same size in a direction perpendicular to
the tracks.
11. The optical pickup head device according to claim 1, wherein
the device satisfies (S1/S0).sup.0.5PW2/PW1>P1/P0>PW2/PW1,
where S0 represents a size of the zero-order diffracted light
converged on the optical recording medium in the direction parallel
to a tangent to the track and S1 represents a size of the at least
first-order diffracted light converged on the optical recording
medium in the direction parallel to a tangent to the track.
12. The optical pickup head device according to claim 1, wherein
the optical recording medium comprises two or more information
recording planes.
13. An information recording/reproducing apparatus comprising: the
optical pickup head device according to claim 1; a driver for
changing a relative position between an information recording
medium and the optical pickup head device; and an electric signal
processor for performing an operation with a signal output from the
optical pickup head device and providing desired information.
14. A method for recording information on an optical recording
medium with an optical pickup head device, wherein the optical
pickup head device comprises a light emitting means for emitting a
plurality of light beams, a convergence means for converging the
beams from the light emitting means on the optical recording
medium, a beam splitting means for splitting the beams reflected
from the optical recording medium, and a photodetection means for
receiving the beams from the beam splitting means and outputting a
signal that corresponds to an amount of light received, the optical
recording medium comprises tracks for recording information, the
beams comprise a main beam and sub-beams: the main beam being used
to record information on the optical recording medium by causing a
physical change in the optical recording medium; and the sub-beams
being the beams other than the main beam, a size of the sub-beams
converged on the optical recording medium is larger in a direction
parallel to a tangent to the track than in a direction
perpendicular to the tangent, and P1/P0>PW2/PW1 is established,
where PW1 represents power of the main beam converged on the
optical recording medium that is required to record information on
the optical recording medium, PW2 represents maximum power of the
main beam converged on the optical recording medium that allows
information recorded on the optical recording medium to be
reproduced without being erased, P0 represents a light amount of
the main beam converged on the optical recording medium, and P1
represents a light amount of one of the sub-beams converged on the
optical recording medium.
15. The method according to claim 14, wherein the light emitting
means comprises a light source for emitting a single light beam and
a diffraction means for diffracting the single light beam into a
plurality of beams of zero-order diffracted light and at least
first-order diffracted light, the zero-order diffracted light is
used as the main beam and the at least first-order diffracted light
is used as the sub-beams, and the diffraction means comprises
grating patterns with a nonuniform period or phase.
.Iadd.16. An optical pickup head device comprising: a light source
for emitting a light beam; a diffractive optical element for
diffracting the light beam from the light source into a plurality
of beams of zero-order diffracted light and at least first-order
diffracted light; an objective lens for converging the beams from
the diffractive optical element on an optical recording medium; a
beam splitter for splitting the beams reflected from the optical
recording medium; and a photodetector for receiving the beams from
the beam splitter and outputting a signal that corresponds to an
amount of light received, wherein a grating pattern in a central
portion of the diffractive optical element differs from grating
patterns on both sides of the central portion, and the grating
patterns on both sides of the central portion are the same in
direction and period, and differ from each other in phase, and
wherein the phases of the grating patterns on both sides of the
central portion of the diffractive optical element are reversed by
180 degrees with respect to each other..Iaddend.
.Iadd.17. The optical pickup head device according to claim 16,
wherein the grating pattern in the central portion of the
diffractive optical element differs from the grating patterns on
both sides of the central portion in phase..Iaddend.
.Iadd.18. An optical pickup head device comprising: a light source
for emitting a light beam; a diffractive optical element for
diffracting the light beam from the light source into a plurality
of beams of zero-order diffracted light and at least first-order
diffracted light; an objective lens for converging the beams from
the diffractive optical element on an optical recording medium; a
beam splitter for splitting the beams reflected from the optical
recording medium; and a photodetector for receiving the beams from
the beam splitter and outputting a signal that corresponds to an
amount of light received, wherein the diffractive optical element
comprises a first pattern region, a second pattern region, and a
third pattern region, the first pattern region is sandwiched
between the second pattern region and the third pattern region,
grating patterns with different phases are formed in each of the
first to third pattern regions, and the grating pattern formed in
the second pattern region and the grating pattern formed in the
third pattern region are the same in direction and period, and have
phases that are reversed by 180 degrees with respect to each
other..Iaddend.
.Iadd.19. An optical pickup head device comprising: a light source
for emitting a light beam; a diffractive optical element for
diffracting the light beam from the light source into a plurality
of beams of zero-order diffracted light and at least first-order
diffracted light; an objective lens for converging the beams from
the diffractive optical element on an optical recording medium; a
beam splitter for splitting the beams reflected from the optical
recording medium; and a photodetector for receiving the beams from
the beam splitter and outputting a signal that corresponds to an
amount of light received, wherein the diffractive optical element
comprises a first pattern region, a second pattern region, and a
third pattern region, the first pattern region is sandwiched
between the second pattern region and the third pattern region,
grating patterns with different phases are formed in each of the
first to third pattern regions, and an average depth of the grating
pattern formed in the first pattern region is equal to an average
depth of each of the grating patterns formed in the second pattern
region and the third pattern region..Iaddend.
.Iadd.20. An optical pickup head device comprising: a light source;
an optical divider for dividing a light beam emitted from the light
source into at least three light beams; a focusing optical system
for focusing the three light beams onto a recording surface of an
optical recording medium so that three focusing spots are formed
independently; and a photodetector arranged to receive reflected
light from each of the three focusing spots of the optical
recording medium by using divided light receiving surfaces, wherein
the optical divider is a diffraction grating that comprises at
least three regions of a first region, a second region, and a third
region, and each of the first to third regions has a predetermined
periodic structure, wherein the first region is located between the
second region and the third region, the periodic structure in the
second region differs from that in the first region, and the
periodic structure in the third region has a phase different from
the phase of the periodic structure in the second region, and
wherein the periodic structure in the third region has a phase
shifted substantially 180 degrees with respect to the phase of the
periodic structure in the second region..Iaddend.
.Iadd.21. An information recording/reproducing apparatus
comprising: the optical pickup head device according to claim 16; a
driver for changing a relative position between the optical
recording medium and the optical pickup head device; and an
electric signal processor for performing an operation with a signal
output from the optical pickup head device and providing desired
information..Iaddend.
.Iadd.22. An information recording/reproducing apparatus
comprising: the optical pickup head device according to claim 18; a
driver for changing a relative position between the optical
recording medium and the optical pickup head device; and an
electric signal processor for performing an operation with a signal
output from the optical pickup head device and providing desired
information..Iaddend.
.Iadd.23. An information recording/reproducing apparatus comprising
the optical pickup head device according to claim 20; a driver for
changing a relative position between the optical recording medium
and the optical pickup head device; and an electric signal
processor for performing an operation with a signal output from the
optical pickup head device and providing desired
information..Iaddend.
.Iadd.24. An information recording/reproducing apparatus
comprising: the optical pickup head device according to claim 19; a
driver for changing a relative position between the optical
recording medium and the optical pickup head device; and an
electric signal processor for performing an operation with a signal
output from the optical pickup head device and providing desired
information..Iaddend.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an optical pickup head device that
is used in an apparatus for recording, reproducing or erasing
information on an optical recording medium and an information
recording/reproducing apparatus. The present invention also relates
to an information recording method that employs the optical pickup
head device.
2. Description of the Related Art
An optical memory technique that uses optical disks having pit
patterns as high-density large-capacity recording media is finding
wide application, e.g., to digital audio disks, video disks,
document file disks, and data files. In recent years, high-density
large-capacity optical disks, called DVD, have been put to
practical use and attracted considerable attention as information
media that can handle mass information like animation. The DVD
optical disks are recorded/reproduced with a so-called red
semiconductor laser that emits a laser beam having a wavelength of
about 650 nm.
FIG. 10 shows the configuration of a general optical system used in
an optical pickup head device of an optical disk system that can
perform recording and reproduction. A semiconductor laser source 1,
i.e., a light source, emits a linearly polarized divergent beam 700
having a wavelength .lamda.1 of 650 nm. The beam 700 emitted from
the semiconductor laser 1 enters a diffraction grating 60. The
diffraction grating 60 divides the beam 700 into three beams: a
zero-order diffracted light beam and .+-.first-order diffracted
light beams. The zero-order diffracted light beam is a main beam
700a for recording/reproducing information. The .+-.first-order
diffracted light beams are two sub-beams 700b, 700c used for
differential push-pull (DPP), with which a tracking error signal
can be detected stably. To avoid unnecessary recording by the
sub-beams, the ratio of diffraction efficiency of the zero-order
diffracted light beam 700a to each of the first-order diffracted
light beams 700b, 700c is generally about 20:1. The three beams
700a to 700c generated in the diffraction grating 60 pass through a
polarizing beam splitter 52 and enter a collimator lens 53 having a
focal length of 20 mm. The collimator lens 53 converts the beams
into parallel light. The beams 700a to 700c thus collimated pass
through a quarter-wave plate 54, where the beams are converted into
circularly polarized light. Then, the beams are converted into
convergent beams with an objective lens 56 having a focal length of
3 mm, pass through a transparent substrate 41a of an optical
recording medium 41, and are focused on an information recording
plane 41b. The aperture of the objective lens 56 is limited by an
aperture 55 so that the NA is 0.6. The transparent substrate 41a
has a thickness of 0.6 mm.
FIG. 11A is a front view schematically showing the diffraction
grating 60, and FIG. 11B is a cross-sectional side view of the
diffraction grating 60. A Y-direction is parallel to a tangent to
the track on the optical recording medium 41 and an X-direction is
perpendicular thereto. Straight grating patterns are formed on the
diffraction grating 60 at an equal period of Pt. The grating depth
d0 is set so that the ratio of light amount of the beam 700a to
each of the beams 700b, 700c is 20:1. An angle .theta. between a
spatial frequency axis 60d of the diffraction grating 60 and the
Y-axis is determined by the positional relationship between the
tracks on the information recording plane 41b and the focused beams
700a to 700c, and generally is in the range of about 1 to 2
degrees.
FIG. 12 shows the relationship between the beams 700a to 700c on
the information recording plane 41b and the tracks. The optical
recording medium 41 is provided with continuous grooves that serve
as the tracks. The track period Tp is 0.74 .mu.m. The beams are
arranged so that when the main beam 700a is positioned on a track,
each of the sub-beams 700b, 700c is positioned between tracks. In
other words, a distance L between the main beam 700a and the
sub-beam 700b or 700c in the direction perpendicular to the tracks
is 0.37 .mu.m.
The beams 700a to 700c reflected from the information recording
plane 41b pass through the objective lens 56 and enter the
quarter-wave plate 54, where the beams are converted into linearly
polarized light that differs by 90 degrees from the light traveling
from the semiconductor laser 1 to the optical recording medium 41.
Then, the beams are converted into convergent beams by passing
through the collimator lens 53 and reflected from the polarizing
beam splitter 52. The beams 700a to 700c reflected from the
polarizing beam splitter 52 pass through a cylindrical lens 57 and
enter a photodetector 31. The transmission of beams 700a to 700c
through the cylindrical lens 57 imparts astigmatism to the beams.
The photodetector 31 includes eight light receiving portions 31a to
31h. The light receiving portions 31a to 31d receive the beam 700a,
the light receiving portions 31e, 31f receive the beam 700b, and
the light receiving portions 31g, 31h receive the beam 700c. Each
of the light receiving portions 31a to 31h outputs a current signal
that corresponds to the amount of light received.
The output signals of the light receiving portions 31a to 31d for
receiving the main beam 700a are used to generate a focusing error
signal with an astigmatism method, a tracking error signal with a
phase-difference method, and a tracking error signal with a
push-pull method. When a disk having continuous grooves such as
DVD-RW (registered trademark) is recorded/reproduced, the output
signals of the light receiving portions 31e to 31h for receiving
the sub-beams 700b, 700c are used together with the output signals
of the light receiving portions 31a to 31d so as to generate a
tracking error signal with a DPP method. The focusing error signal
and the tracking error signal are amplified to a desired level and
phase-compensated, and then sent to actuators 91, 92, thereby
performing focusing control and tracking control.
In DVD, a two-layer disk that includes two information recording
planes is standardized for read-only ROM disks. A conventional
optical pickup head device can read information from the read-only
two-layer disk without any problems by detecting a tracking error
signal with the phase-difference method.
Research and development of an optical recording medium having two
recordable information recording planes (hereinafter, referred to
as a two-layer recording disk) has yielded significant results.
Since no information is written in the two-layer recording disk in
its initial state, a tracking error signal cannot be detected with
the phase-difference method. Accordingly, like an optical recording
medium having a single recordable information recording plane
(hereinafter, referred to as a single-layer recording disk), the
tracking error signal should be detected with the DPP method.
However, there is a problem of using the two-layer recording disk
in a conventional device having the above configuration. Even if a
tracking error signal is detected by the DPP method, it causes
uncorrectable offset fluctuations when the objective lens follows
tracking or the optical recording medium tilts. The reason for this
is as follows. When information is recorded on one of the
information recording planes (hereinafter, this information
recording plane is referred to as a focusing plane), the beam
focused on the focusing plane is partly reflected and partly
transmitted by the focusing plane. The transmitted beam reaches the
other information recording plane (hereinafter, this information
recording plane is referred to as a non-focusing plane) in a
defocused manner. The beam reflected from the non-focusing plane
also enters the photodetector. However, this beam cannot be
cancelled completely by the DPP method for detecting a tracking
error signal because of aberration, a nonuniform light amount of
the beam, or the like. Therefore, the amount of beam that is not
cancelled varies when the objective lens follows tracking or the
optical recording medium tilts, causing offset fluctuations in the
tracking error signal. As a result, off-track occurs and erases
some of the information recorded on the adjacent tracks during
recording, so that information recorded on the optical recording
medium cannot be read faithfully.
SUMMARY OF THE INVENTION
Therefore, with the foregoing in mind, it is an object of the
present invention to provide an optical pickup head device and an
information recording method. The optical pickup head device can
record information on an optical recording medium without erasing
information recorded on the adjacent tracks and achieve faithful
reading of the information recorded on the optical recording
medium. Moreover, the optical pickup head device can reduce offset
fluctuations in a tracking error signal even when an objective lens
follows tracking or the optical recording medium tilts. Further, it
is an object of the present invention to provide an information
recording/reproducing apparatus that includes the optical pickup
head device.
An optical pickup head device of the present invention includes the
following: a light source for emitting a light beam; a diffraction
means for diffracting the light beam from the light source into a
plurality of beams of zero-order diffracted light and at least
first-order diffracted light; a convergence means for converging
the beams from the diffraction means on an optical recording
medium; a beam splitting means for splitting the beams reflected
from the optical recording medium; and a photodetection means for
receiving the beams from the beam splitting means and outputting a
signal that corresponds to the amount of light received. The
optical recording medium includes tracks for recording information.
The diffraction means includes grating patterns with a nonuniform
period or phase. The size of the at least first-order diffracted
light converged on the optical recording medium is larger in the
direction parallel to a tangent to the track than in the direction
perpendicular to the tangent. P1/P0>PW2/PW1 is established,
where PW1 represents the power of the zero-order diffracted light
converged on the optical recording medium that is required to
record information on the optical recording medium, PW2 represents
the maximum power of the zero-order diffracted light converged on
the optical recording medium that allows information recorded on
the optical recording medium to be reproduced without being erased,
P0 represents the light amount of the zero-order diffracted light
converged on the optical recording medium, and P1 represents the
light amount of one of the at least first-order diffracted light
converged on the optical recording medium.
An information recording/reproducing apparatus of the present
invention includes the following: the optical pickup head device
according to the present invention; a driver for changing a
relative position between an information recording medium and the
optical pickup head device; and an electric signal processor for
performing an operation with a signal output from the optical
pickup head device and providing desired information.
An information recording method of the present invention is a
method for recording information on an optical recording medium
with an optical pickup head device. The optical pickup head device
includes the following: a light emitting means for emitting a
plurality of light beams; a convergence means for converging the
beams from the light emitting means on the optical recording
medium; a beam splitting means for splitting the beams reflected
from the optical recording medium; and a photodetection means for
receiving the beams from the beam splitting means and outputting a
signal that corresponds to the amount of light received. The
optical recording medium includes tracks for recording information.
The beams include a main beam and sub-beams: the main beam is used
to record information on the optical recording medium by causing a
physical change in the optical recording medium; and the sub-beams
are the beams other than the main beam. The size of the sub-beams
converged on the optical recording medium is larger in the
direction parallel to a tangent to the track than in the direction
perpendicular to the tangent. P1/P0>PW2/PW1 is established,
where PW1 represents the power of the main beam converged on the
optical recording medium that is required to record information on
the optical recording medium, PW 2 represents the maximum power of
the main beam converged on the optical recording medium that allows
information recorded on the optical recording medium to be
reproduced without being erased, P0 represents the light amount of
the main beam converged on the optical recording medium, and P1
represents the light amount of one of the sub-beams converged on
the optical recording medium.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic view showing the configuration of an optical
pickup head device of Embodiment 1 of the present invention.
FIG. 2A is a front view showing the configuration of a diffraction
grating used in an optical pickup head device of Embodiment 1 of
the present invention.
FIG. 2B is a cross-sectional side view of the diffraction
grating.
FIG. 3 shows the relationship between an information recording
plane and beams in an optical pickup head device of Embodiment 1 of
the present invention.
FIG. 4 shows the relationship between tracks and beams in an
optical pickup head device of Embodiment 1 of the present
invention.
FIG. 5A is a front view showing the configuration of a diffraction
grating used in an optical pickup head device of Embodiment 2 of
the present invention, and
FIG. 5B is a cross-sectional side view of the diffraction
grating.
FIG. 6 shows the relationship between tracks and beams in an
optical pickup head device of Embodiment 2 of the present
invention.
FIG. 7A is a front view showing the configuration of a diffraction
grating used in an optical pickup head device of Embodiment 3 of
the present invention, and
FIG. 7B is a cross-sectional side view of the diffraction
grating.
FIG. 8A is a front view showing the configuration of a diffraction
grating used in an optical pickup head device of Embodiment 4 of
the present invention, and FIG. 8B is a cross-sectional side view
of the diffraction grating.
FIG. 9 is a schematic view showing the configuration of an
information recording/reproducing apparatus of Embodiment 5 of the
present invention.
FIG. 10 is a schematic view showing the configuration of a
conventional optical pickup head device.
FIG. 11A is a front view showing the configuration of a diffraction
grating used in a conventional optical pickup head device, and
FIG. 11B is a cross-sectional side view of the diffraction
grating.
FIG. 12 shows the relationship between tracks and beams in a
conventional optical pickup head device.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
The above configuration of the present invention can reduce offset
fluctuations in a tracking error signal detected by the DPP method
even when an objective lens follows tracking or an optical
recording medium tilts, so that off-track can be reduced as well.
Therefore, when the optical recording medium is a recordable
two-layer disk, information can be recorded without erasing some of
the information recorded on the adjacent tracks. Thus, it is
possible to achieve a highly reliable information
recording/reproducing apparatus and information recording method
that enable faithful reading of information recorded on the optical
recording medium.
The diffraction means of the optical pickup head device of the
present invention includes grating patterns with a non-uniform
period or phase. The specific configuration of the grating patterns
is not particularly limited. For example, the period of the grating
patterns formed on the diffraction means may change gradually.
The grating patterns on both sides of a central portion of the
diffraction means may differ from each other in phase. In this
case, the phases of the grating patterns on both sides of the
central portion may be reversed by 180 degrees with respect to each
other. The central portion may have a different grating pattern
from the grating patterns on both sides of the central portion, and
the phases of the grating patterns on both sides of the central
portion may be reversed by 180 degrees with respect to each
other.
It is possible that the diffraction means includes a first pattern
region, a second pattern region, and a third pattern region, the
first pattern region is sandwiched between the second pattern
region and the third pattern region, and a grating pattern is
formed in the first pattern region and not in the second pattern
region and the third pattern region.
It is possible that the diffraction means includes a first pattern
region, a second pattern region, and a third pattern region, the
first pattern region is sandwiched between the second pattern
region and the third pattern region, and a grating pattern formed
in the first pattern region differs from that formed in the second
pattern region and the third pattern region.
In this case, it is preferable that the average depth of the
grating pattern formed in the first pattern region is equal to the
average depth of each of the second pattern region and the third
pattern region.
In the optical pickup head device of the present invention, it is
preferable that a plurality of diffracted light beams converged on
the optical recording medium have the same size in the direction
perpendicular to the tracks.
In the optical pickup head device of the present invention, it is
preferable that the device satisfies
(S1/S0).sup.0.5PW2/PW1>P1/P0>PW2/PW1, where S0 represents the
size of the zero-order diffracted light converged on the optical
recording medium in the direction parallel to a tangent to the
track and S1 represents the size of the at least first-order
diffracted light converged on the optical recording medium in the
direction parallel to a tangent to the track.
The optical recording medium may include two or more information
recording planes.
In the information recording method of the present invention, the
light emitting means of the optical pickup head device that emits a
plurality of light beams may include a light source for emitting a
single light beam and a diffraction means for diffracting the
single light beam into a plurality of beams of zero-order
diffracted light and at least first-order diffracted light.
Moreover, it is possible that the zero-order diffracted light is
used as the main beam and the at least first-order diffracted light
is used as the sub-beams, and that the diffraction means includes
grating patterns with a nonuniform period or phase.
In this case, the grating patterns with a nonuniform period or
phase can be formed specifically as described above.
Hereinafter, embodiments of an optical pickup head device, an
information recording/reproducing apparatus, and an information
recording method of the present invention will be described with
reference to the accompanying drawings. In each of the drawings,
identical elements that have the same effect and perform the same
operation are denoted by the same reference numerals.
Embodiment 1
FIG. 1 shows an example of the configuration of an optical pickup
head device of the present invention. A semiconductor laser source
1, i.e., a light source, emits a linearly polarized divergent beam
70 having a wavelength .lamda. of 650 nm. The beam 70 emitted from
the semiconductor laser 1 enters a diffraction grating 61. The
diffraction grating 61 divides the beam 70 into three beams: a
zero-order diffracted light beam and .+-.first-order diffracted
light beams. The zero-order diffracted light beam is a main beam
70a for recording/reproducing information. The .+-.first-order
diffracted light beams are two sub-beams 70b, 70c used for DPP,
with which a tracking error signal can be detected stably. To avoid
unnecessary recording by the sub-beams 70b, 70c, the ratio of
diffraction efficiency of the zero-order diffracted light beam 70a
to each of the first-order diffracted light beams 70b, 70c is
generally about 20:1. In this embodiment, however, the ratio is
10:1. The three beams 70a to 70c generated in the diffraction
grating 61 pass through a polarizing beam splitter 52 and enter a
collimator lens 53 having a focal length of 20 mm. The collimator
lens 53 converts the beams into parallel light. The beams 70a to
70c thus collimated pass through a quarter-wave plate 54, where the
beams are converted into circularly polarized light. Then, the
beams are converted into convergent beams with an objective lens 56
having a focal length of 3 mm, pass through a transparent substrate
41a of an optical recording medium 41, and are focused on an
information recording plane 41b. The aperture of the objective lens
56 is limited by an aperture 55 so that the NA is 0.6. The
transparent substrate 41a has a thickness of 0.6 mm.
The beams 70a to 70c reflected from the information recording plane
41b pass through the objective lens 56, where the beams are
converted into parallel light. The beams 70a to 70c transmitted
through the objective lens 56 enter the quarter-wave plate 54,
where the beams are converted into linearly polarized light that
differs by 90 degrees from the light traveling from the
semiconductor laser 1 to the optical recording medium 41. Then, the
beams are converted again into convergent beams by passing through
the collimator lens 53. The beams 70a to 70c transmitted through
the collimator lens 53 are reflected from the polarizing beam
splitter 52. The beams 70a to 70c reflected from the polarizing
beam splitter 52 pass through a cylindrical lens 57 and enter a
photodetector 31. The transmission of the beams 70a to 70c through
the cylindrical lens 57 imparts astigmatism to the beams. The
photodetector 31 includes eight light receiving portions 31a to
31h. The light receiving portions 31a to 31d receive the beam 70a,
the light receiving portions 31e, 31f receive the beam 70b, and the
light receiving portions 31g, 31h receive 70c. Each of the light
receiving portions 31a to 31h outputs a signal that corresponds to
the amount of light received.
The light receiving portions 31a to 31h output current signals I31a
to I31h that correspond to the amount of light received,
respectively. Using the signals I31a to I31d output from the
photodetector 31, a focusing error signal can be obtained with the
astigmatism method, i.e., a calculation of (I31a+I31c)-(I31b+I31d).
A tracking error signal can be obtained with the DPP method, i.e.,
a calculation of
{(I31a+I31d)-(I31b+I31c)}-K{(I31e+I31g)-(I31f+I31h)}. Here, K
represents a coefficient that is determined by the ratio of
diffraction efficiency of the zero-order diffracted light beam 70a
to the first-order diffracted light beams 70b, 70c of the
diffraction grating 61. The focusing error signal and the tracking
error signal are amplified to a desired level and
phase-compensated, and then sent to actuators 91, 92 for driving
the objective lens 56, thereby performing focusing control and
tracking control.
FIG. 2A is a front view schematically showing the diffraction
grating 61, and FIG. 2B is a cross-sectional side view of the
diffraction grating 61. A Y-direction is parallel to a tangent to
the track on the optical recording medium 41 and an X-direction is
perpendicular thereto. Straight grating patterns are formed on the
diffraction grating 61. The period of the grating patterns changes
gradually according to a position in the Y-direction, and there is
the relationship given by Pt1<Pt2<Pt3, where Pt1 represents
the grating period in the upper portion of the diffraction grating
61, Pt2 represents the grating period in the central portion, and
Pt3 represents the grating period in the lower portion. The grating
depth d is set so that the ratio of the light amount of the beam
70a to each of the beams 70b, 70c is 10:1. A maximum power PW2 of
the zero-order diffracted light beam 70a with which the recordable
optical recording medium 41 can be irradiated for reproducing
information recorded thereon is 1 mW. An optimum power PW1 of the
zero-order diffracted light beam 70a for recording information on
the optical recording medium 41 is 12 mW.
FIG. 3 shows the beams 70a to 70c converged on the information
recording plane 41b of the optical recording medium 41 with the
objective lens 56. FIG. 4 schematically shows the beams 70a to 70c
on the information recording plane 41b of the optical recording
medium 41. The information recording plane 41b is provided with
grooved tracks. The track pitch Tp is 0.74 .mu.m. Information is
recorded on the grooves. To detect a tracking error signal with the
DPP method, the beams 70a to 70c are arranged so that when the beam
70a is positioned on a track, each of the beams 70b, 70c is
positioned between tracks. In other words, both distances L between
the beams 70a and 70b and between the beams 70a and 70c in the
X-direction are Tp/2. An angle .theta. between an imaginary line
containing the beams 70b, 70c and a track is generally 1 to 2
degrees. Since the angle .theta. is small, beam expansion in the
direction perpendicular to the tracks is negligibly small, even if
the direction in which the grating pattern period changes gradually
is perpendicular to the grating patterns. By making the direction
of change in grating pattern period perpendicular to the grating
patterns, a large tolerance can be ensured in the X-direction for
installing the diffraction grating 61 in the optical pickup head
device. It should be noted that the diffraction grating can be
produced by designing the grating patterns precisely to eliminate
the beam expansion in the direction perpendicular to the tracks
completely.
The beam 70a is converged to a diffraction-limited size and focused
on the information recording plane 41b. The diffraction limit is
determined by the wavelength .lamda. of the semiconductor laser
source 1 and the NA of the objective lens 56. The beams 70b, 70c
are converged to the diffraction-limited size and focused on the
information recording plane 41b in the XZ-plane. However, the beams
70b, 70c are not focused on the information recording plane 41b in
the YZ-plane. When viewed from the objective lens 56, the beam 70c
is focused on this side of the information recording plane 41b and
the beam 70b is focused on the opposite side thereof. Therefore,
the size of the beams 70b, 70c on the information recording plane
41b in the Y-direction is larger than the diffraction limit. A
difference in focusing position in the YZ-plane between the beams
70b and 70c and their increased size in the Y-direction result from
the fact that the period of the grating patterns formed on the
diffraction grating 61 changes gradually in the Y-direction. The
size of the beams 70b, 70c in the Y-direction can be designed
arbitrarily by changing the grating pattern period of the
diffraction grating 61. In this embodiment, the size is two times
larger than the diffraction limit.
A detailed explanation of a method for designing the grating
patterns of the diffraction grating 61 will be omitted because a
general method for designing and producing a hologram can be
employed. There is no particular limitation to a material for the
diffraction grating 61, and resin or glass can be used. In this
embodiment, the diffraction grating 61 is produced in the following
manner: a master of the diffraction grating 61 is prepared, and
then polyolefin resin is molded by using the master as a die.
The ratio of power P0 of the beam 70a focused on the information
recording plane 41b to power P1 of each of the beams 70b, 70c is
equal to the ratio of diffraction efficiency of the zero-order
diffracted light beam to each of the first-order diffracted light
beams of the diffraction grating 61, i.e., P0:P1=10:1. Therefore,
there is the relationship given by P1/P0>PW2/PW1. For a
conventional optical pickup head device, if P1/P0<PW2/PW1 is not
established, information that has been recorded is erased by the
sub-beams during recording of information on the optical recording
medium 41. In contrast, the optical pickup head device of the
present invention allows the size of the beams 70b, 70c on the
information recording plane 41b to be made larger in the
Y-direction. Therefore, the energy of the sub-beams 70b, 70c is
dispersed due to the increased size. Consequently, even if
P1/P0>PW2/PW1, the beams 70b, 70c do not erase information
recorded on the information recording plane 41b.
It is not solely determined to what extent the sub-beams should be
made large in the Y-direction so that information recorded on the
information recording plane 41b is not erased. This is because the
extent of increase in size of the sub-beams depends on the
characteristics of a recording film that constitutes the
information recording plane 41b. In general, the maximum
irradiation power can be raised to about the square root of
magnification at which the beam size is increased. In other words,
S1/S0=2 can increase the power of the sub-beams by 1.4 times, where
S0 represents the size of the zero-order diffracted light beam 70a
(main beam) in the direction parallel to a tangent to the track,
and S1 represents the size of the first-order diffracted light
beams 70b, 70c (sub-beams) in the direction parallel to a tangent
to the track.
The intensity of the first-order diffracted light beams is higher
than that in a conventional optical pickup head device. Therefore,
even if a two-layer recording disk is used as the optical recording
medium, the optical pickup head device of the present invention is
hardly affected by stray light generated by a beam reflected from
the non-focusing plane. Moreover, the optical pickup head device
can reduce offset fluctuations in a tracking error signal even when
the objective lens 56 follows tracking or the optical recording
medium tilts and thus can perform stable tracking control. In the
case of a single-layer recording disk, offset fluctuations in a
tracking error signal are caused when the objective lens 56 follows
tracking, due to scratches and dirt on the optical recording medium
or the optical components of the optical pickup head device.
However, the optical pickup head device of the present invention
can reduce the offset fluctuations in a tracking error signal and
perform stable tracking control, as with the two-layer recording
disk.
To enhance the light amount of the beams 70b, 70c for an
improvement in stability of tracking control, the grating patterns
may be designed so that the depth d of the diffraction grating 61
is increased to make the beams 70b, 70c larger in the Y-direction.
The size of the beams 70b, 70c in the Y-direction can be set
arbitrarily depending on the design of the grating patterns. The
amplitude of a tracking error signal is affected by the size of the
beams 70b, 70c in the X-direction and the track pitch and not by
the size in the Y-direction. Therefore, though the size of the
beams 70b, 70c in the Y-direction is made large in the optical
pickup head device of the present invention, a favorable tracking
error signal can be detected without adverse effect.
The configurations for recording information on the information
recording plane 41b are classified into two types: groove format
and land-groove format. In the groove format, information is
recorded on either grooves or between the grooves, like DVD-RW
(registered trademark). In the land-groove format, information is
recorded on both grooves and between the grooves, like DVD-RAM
(registered trademark). This embodiment describes an example of the
groove format. However, the application of the optical pickup head
device of the present invention to the land-groove format is not a
problem.
A material for the information recording plane 41b of the optical
recording medium is not particularly limited, as long as it causes
a physical change in reflectance, refractive index, Kerr rotation
angle, or the like by irradiation of light. All general optical
recording materials, such as an organic dye material, a phase
change material and magneto-optical material, can be used.
This embodiment uses the semiconductor laser having a wavelength of
650 nm as a light source and the objective lens having an NA of
0.6. However, the amount of information to be recorded on the
optical recording medium can be increased by setting the wavelength
of the light source to 405 nm and the NA of the objective lens to
0.85. Various modifications of the optical pickup device of the
present invention may be made without departing from the sprit and
the scope of the invention. Examples of such modifications include
the following: a focusing detection method is changed from the
astigmatism method to a spot size detection method, and a beam
forming prism is used to enhance the light utilization
efficiency.
In this embodiment, the first-order diffracted light beams 70b and
70c are the same in diffraction efficiency. However, the beams 70b,
70c may have different diffraction efficiencies. In that case, at
least one of the first-order diffracted light beams should satisfy
the above conditions.
In this embodiment, the first-order diffracted light beams
generated in the diffraction grating 61 serve as the sub-beams.
However, diffracted light with two or more orders may be used as
the sub-beams.
Embodiment 2
FIG. 5A is a front view schematically showing a diffraction grating
62 used in another example of an optical pickup head device of the
present invention, and FIG. 5B is a cross-sectional side view of
the diffraction grating 62. The optical pickup head device can be
formed by using the diffraction grating 62 instead of the
diffraction grating 61 in Embodiment 1.
The diffraction grating 62 includes two pattern regions 62a and
62b. Both grating patterns formed in the pattern regions 62a, 62b
are straight patterns and have a constant period of Pt. However,
the phase is reversed at an imaginary boundary line 62c in the
center of the diffraction grating 62 by 180 degrees. The
diffraction grating 62 receives a beam 70 emitted from a
semiconductor laser source 1 and generates a zero-order diffracted
light beam 71a and first-order diffracted light beams 71b, 71c.
FIG. 6 schematically shows the beams 71a to 71c on an information
recording plane 41b of an optical recording medium 41, together
with a change in light intensity of each beam spot on the left. The
beam 71a is the zero-order diffracted light beam of the diffraction
grating 62. Like the optical pickup head device of Embodiment 1,
the beam 7 1a is converged to the diffraction-limited size, which
is determined by the wavelength .lamda. of the semiconductor laser
light source 1 and the NA of an objective lens 56. The beams 71b,
71c are the first-order diffracted light beams of the diffraction
grating 62. The beams 71b, 71c are converged to the
diffraction-limited size in the X-direction. However, there are two
peaks of intensity for each of the beams 71b, 71c, so that the size
of the beams 71b, 71c in the Y-direction is about two times as
large as the diffraction limit. The reason each of the beams 71b,
71c has two peaks of intensity and increases in size in the
Y-direction is that the phases of the grating patterns 62a, 62b
formed on the diffraction grating 62 are reversed by 180
degrees.
The optical pickup head device of this embodiment also allows the
size of the beams 71b, 71c to increase in the Y-direction.
Therefore, even if P1/P0>PW2/PW1 is established under the
condition that the ratio of intensity of the beam 71a to each of
the beam 71b, 71c is, e.g., 10:1, none of the beams 71b, 71c erases
information recorded on the information recording plane 41b. Thus,
a tracking error signal can be obtained that enables stable
tracking control.
In the above example, the grating patterns formed in the regions
62a and 62b are reversed by 180 degrees with respect to each other.
However, a phase difference between the two grating patterns is not
necessarily 180 degrees, and the same effect can be obtained as
long as the grating patterns have different phases.
Embodiment 3
FIG. 7A is a front view schematically showing a diffraction grating
63 used in another example of an optical pickup head device of the
present invention, and FIG. 7B is a cross-sectional side view of
the diffraction grating 63. The optical pickup head device can be
formed by using the diffraction grating 63 instead of the
diffraction grating 62 in Embodiment 2.
Like the diffraction grating 62, the diffraction grating 63
includes two pattern regions 63a and 63b. Both grating patterns
formed in the pattern regions 63a, 636 are straight patterns and
have a constant period of Pt. However, the phase is reversed at an
imaginary boundary line 63c in the center of the diffraction
grating 63 by 180 degrees. The diffraction grating 63 differs from
the diffraction grating 62 in that a pattern 63d is provided at the
boundary between the pattern regions 63a and 63b. The formation of
the pattern 63d can reduce unnecessary light that is present
between a zero-order diffracted light beam and each of first-order
diffracted light beams of the diffraction grating 63 when those
diffracted light beams are converged on an information recording
plane 41b. Thus, a tracking error signal can be obtained that
enables more stable tracking control In the above example, the
grating patterns formed in the regions 63a and 63b are reversed by
180 degrees with respect to each other. However, a phase difference
between the two grating patterns is not necessarily 180 degrees,
and the same effect can be obtained as long as the grating patterns
have different phases.
Embodiment 4
FIG. 8A is a front view schematically showing a diffraction grating
64 used in another example of an optical pickup head device of the
present invention, and FIG. 8B is a cross-sectional side view of
the diffraction grating 64. The optical pickup head device can be
formed by using the diffraction grating 64 instead of the
diffraction grating 63 in Embodiment 3.
The diffraction grating 64 includes three pattern regions 64a to
64c. The pattern region 64a is provided with a grating pattern
having a period of Pt and a duty of 1:1. Neither of the pattern
regions 64b, 64c is provided with a grating pattern. The whole beam
70 entering the pattern regions 64b, 64c is transmitted as a
zero-order diffracted light beam. The relationship given by d2=d1/2
is established, where d1 represents the depth of the grating
pattern formed in the pattern region 64a and d2 represents the
depth of the pattern regions 64b, 64c (i.e., the distance from the
top of the pattern region 64a). The depth d2 is set so that phase
changes in the zero-order diffracted light beam caused when it
passes through each of the pattern regions 64a to 64c of the
diffraction grating 64 are the same. As a result, the zero-order
diffracted light beam generated from the diffraction grating 64 can
be converged to the diffraction-limited size on an information
recording plane 41b. When the size of the pattern region 64a in the
Y-direction corresponds to 1/a of the NA of an objective lens 56,
first-order diffracted light beams that are generated in the
diffraction grating 64 and focused on the information recording
plane 41b can form spots whose size in the Y-direction is a times
larger than the diffraction limit. Since a can be set arbitrarily
in accordance with the necessary intensity of the first-order
diffracted light beams, the intensity of the first-order diffracted
light beams is increased sufficiently compared with a conventional
optical pickup head device. Thus, an optical pickup device that is
hardly affected by stray light can be achieved.
The pattern region 64a of the diffraction grating 64 is smaller
than the NA of the objective lens 56. Therefore, to ensure the same
power of the sub-beams converged on the information recording plane
41b as that produced by the diffraction gratings 61, 62 or 63, the
diffraction efficiency of the first-order diffracted light beams in
the pattern region 64a should be higher than that of the
first-order diffracted light beams of the diffraction gratings 61
to 63. In this case, the light amount of the zero-order diffracted
light beam passing through the pattern region 64a is less than that
passing through the pattern regions 64b, 64c. Accordingly, the
zero-order diffracted light beam focused on the information
recording plane 41b can form a super-resolution spot, and thus the
size of the spot of the zero-order diffracted light beam in the
direction parallel to a tangent to the track (Y-direction) becomes
smaller than the diffraction limit. This can improve the response
characteristics at higher frequencies during reproduction of
information recorded on the optical recording medium 41 and
suppress errors even in the presence of noise, thereby achieving an
optical pickup head device capable of reproducing highly reliable
information.
In the optical pickup head device of this embodiment, a grating
pattern is not formed in the pattern regions 64b, 64c. However, a
grating pattern having a different period from that of the pattern
region 64a may be formed in each of the pattern regions 64b, 64c,
which leads to an optical pickup head device that can provide a
tracking error signal to enable stable tracking control.
Embodiment 5
FIG. 9 shows an example of an information recording/reproducing
apparatus that uses the optical pickup head device described above.
The information recording/reproducing apparatus includes an optical
pickup head device 80, an optical recording medium driver 81, an
optical pickup head device driver 82, an electric circuit 83, and a
power source 84. The driver 81 rotates an optical recording medium
41. The driver 82 includes a feed motor 85 and a feed screw 86,
which constitute a so-called traverse mechanism. The feed motor 85
is driven to rotate the feed screw 86 connected directly to the
rotation axis of the feed motor 85, and thus the optical pickup
head device 80 is transferred to a desired position in the radial
direction of the optical recording medium 41. The optical pickup
head device 80 sends to the electric circuit 83 a signal that
corresponds to the positional relationship between the optical
pickup head device 80 and the optical recording medium 41. The
electric circuit 83 amplifies or calculates this signal and
slightly moves the optical pickup head device 80 or an objective
lens in the optical pickup head device 80. The optical pickup head
device 80 also sends to the electric circuit 83 a signal obtained
by reading information recorded on the optical recording medium 41.
Moreover, the electric circuit 83 demodulates information recorded
on the optical recording medium 41. Actuators 91, 92 drive the
objective lens 56 in the optical pickup head device. Using the
above signal and the driver 82 or actuators 91, 92, focusing servo
and tracking servo are performed to read, write, or erase
information on the optical recording medium 41. The power source 84
supplies electricity needed for operation to each of the electric
circuit 83, the optical pickup head device driver 82, and the
optical recording medium driver 81.
The information recording/reproducing apparatus of this embodiment
can record/reproduce information faithfully because it uses the
optical pickup head device that can suppress offset fluctuations
caused in a tracking error signal when the objective lens 56
follows tracking or the optical recording medium 41 tilts and can
perform stable tracking control.
The optical pickup head device in Embodiments 1 to 5 has the
configuration in which a beam emitted from a single light source
enters a diffraction grating to generate a plurality of beams.
However, the present invention is not limited to this
configuration, and various modifications may be made in the
invention without departing from the spirit and the scope thereof.
For example, a plurality of beams may be generated by using a
plurality of semiconductor lasers formed on the same semiconductor
substrate instead of the diffraction grating. In this case, to
expand beams (sub-beams) that correspond to the first-order
diffracted light beams in Embodiment 1 in the direction parallel to
a tangent to the track, the transverse mode of the semiconductor
laser that emits those beams should be changed into a multimode.
The expansion of the sub-beams in the track direction can provide
the same effect as that in the above embodiments.
The invention may be embodied in other forms without departing from
the spirit or essential characteristics thereof. The embodiments
disclosed in this application are to be considered in all respects
as illustrative and not limiting. The scope of the invention is
indicated by the appended claims rather than by the foregoing
description, and all changes which come within the meaning and
range of equivalency of the claims are intended to be embraced
therein.
* * * * *