JPH0896400A - Ultrahigh resolution recording method and optical disk - Google Patents

Abstract

PURPOSE: To attain a recording and reproduction with a higher density by so as to utilize a synergistic effect between an ultrahigh resolution optical disk and an ultrahigh resolution optical head so as to increase read resolution at reproduction. CONSTITUTION: Light shield slits 103 are provided in an optical path from a laser 101 of an optical head leading to a beam splitter A104 so as to transmit a high frequency component around a circumferential part of a collimated light beam from a collimator lens 102 and an objective lens 106 is used to emphasize a signal component around the center of a focused beam. When a beam diameter of the beam light intensity of 50% (beam light intensity at the center of the focused beam is 100%) is selected to be 90% of a beam diameter or below when no light shield slits 103 are provided so as to reproduce the information recorded on an ultrahigh resolution optical disk 109.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical recording / reproducing method and an optical disc device, and more particularly to an optical recording / reproducing method and an optical disc device for high density recording using a super-resolution technology for the next generation high-definition television. Regarding

[0002]

2. Description of the Related Art Research on an external storage device having both high-speed accessibility of a magnetic disk for a computer and a large-capacity memory of an optical disk is rapidly progressing. It is expected that next-generation disk devices will be used in considerable fields from the viewpoints of high-speed transfer rates and memory capacities.

Therefore, in order to increase the density and increase the transfer rate of the existing optical recording technology, it is necessary to make the beam focusing diameter as small as possible. Examples of the method include super-resolution optical head technology for an optical head, super-resolution technology for an optical disk medium having a recording information area and an area where recording information is masked, a shorter wavelength laser, and a higher numerical aperture of an objective lens. Yes, a higher density can be achieved by a combination of these techniques.

However, when the wavelength of the laser of the light source is reduced and the numerical aperture of the objective lens is increased, the diameter of the focused beam cannot be reduced to the diffraction limit defined by the Airy disk.

Next, the diameter of the focused beam will be described.

Below, the laser wavelength is λ and the numerical aperture is NA
And the beam diameter of 50%, 13.5% (e ^-2 ), and 0% of the light intensity with respect to the central light intensity (100%) of the focused beam. The beam diameter corresponding to 0% is the air disk diameter.

Light intensity = 50%; Beam diameter = 0.52 × λ / NA (1) Light intensity = 13.5%; Beam diameter = 0.82 × λ / NA (2) Light intensity = 0%; Beam Diameter = 1.22 × λ / NA (3) Here, as an example, λ = 0.68 μm, NA = 0.5
Substituting 5 into equations (1), (2), and (3), the respective diameters are φ0.64 μm, φ1.01 μm, and 1.51 μm.
m. Among these beam diameters, the beam diameter of 50% of the light intensity during recording and the beam diameter of 13.5% of the light intensity during reproducing are related to the optical modulation factor (MTF) during recording and reproduction.

The MTF is an output response when a light beam scans a mark recorded at a constant interval, and is a ratio of reflectance of the mark and other portions, or a polarization axis such as Kerr rotation angle. It represents the rotation ratio of the. The larger this ratio, the carrier-to-noise ratio (CNR) of the reproduced signal
Grows larger.

Next, a description will be given of high density reproduction using a focused beam and a super-resolution optical disk of a conventionally known ordinary optical head.

FIG. 7 is a view for explaining a high-density reproducing method using a focused beam of a conventional ordinary optical head and a super-resolution optical disk.

Regarding this, Nikkei Electronics Update 1993.2 "Development of super-resolution magneto-optical disk technology that achieves dramatically higher density (more than 6 times)" PP-11-
It is published in 13.

According to this, taking a magneto-optical disk as an example, the magneto-optical disk medium structure has a two-layer film. This magneto-optical disk medium has a two-layer structure of a reproducing layer 701 and a recording layer 702, and the reproducing layer 701 is, for example, GdFe.
Co (gadolinium / iron / cobalt), recording layer 702 is DyFe
It consists of a medium such as Co (diprosium / iron / cobalt). When the Gaussian reproduction light is focused on the above-described magneto-optical disk medium, the magnetic domain 703 written in the recording layer at a threshold temperature of about 120 ° C. emerges in a window 701 a of a part of the reproduction layer 701, and the objective lens 705 When the signal is reproduced with an aperture having a diameter 708 of about 50% of the central light intensity as compared with the focused Gaussian beam 706 reproduced with a beam diameter 707 of the e- ² (13.5%) light intensity, the conventional diameter is obtained. Is less than 1/2 of the diameter. 50% of central light intensity
In the above range of the beam diameter, the reproducing layer is heated by the temperature rise due to the light intensity, and the recording signal is reproduced from the recording layer 702 having perpendicular magnetic anisotropy through the window portion 701a.

It is known that laser light emitted from a laser and condensed by a lens generally has a Gaussian beam radiation distribution represented by the following equation.

I (r) = (2P / πw ² ) EXP (−2r ² / w ² ) where I (r): light intensity at a distance r from the center P: total power of the beam w: output intensity 1 / e ² (13.5%) beam radius e: exponential function r: distance from center The optical system of this Gaussian beam is described in July 1993, by Hideaki Yamada, K. It is described in PP-3 of "Laser & Optics Guide No. 3 (2), Laser Accessories and Detector" published by No Melles Griot Co., Ltd.

[0015]

In order to improve the recording density of the above-mentioned conventional super-resolution optical disk and the ordinary optical head, the beam light intensity of 50% when the light intensity at the center of the focused beam is 100%. 90%, not the beam diameter of
It is conceivable that information is reproduced with a beam diameter having such a light intensity, and a mask of the reproduction layer is opened so that a large modulation degree can be obtained in the window portion. However, in this case, at a light intensity of 90%, it was difficult to obtain a stable reproduction state due to fluctuations in reproduction power, fluctuations in the Curie point due to heating of the disk medium itself, and fluctuations.

Therefore, a first object of the present invention is to provide a method for ensuring stability in high density reproduction, which is the above-mentioned problem in an optical disk apparatus using a super-resolution optical disk, and an optical disk apparatus using the same. To do.

In addition, it is necessary to consider a recording method for an optical head and an optical disk medium in consideration of recording conditions (analog or digital) depending on the form of a signal.

In the case of digital, the crosstalk is -25.
A level of about dB is sufficient, but in the case of analog video recording, a crosstalk of -45 dB is required.

Further, in applying the super-resolution method to a conventional optical disk apparatus, generation of a side lobe of a focused beam on an optical disk medium and a side lobe of a beam focused on an optical sensor for reflected light from the optical disk medium for that purpose. Was a problem.

Therefore, a second object of the present invention is to focus an optimum focused beam form according to an analog or digital recording form on a super-resolution optical disc.
Moreover, the long axis direction of the focused beam ellipse is combined with the super-resolution optical head technology to improve the MTF of recording / reproduction. Furthermore, the super-resolution optical disc and the super-resolution optical head are combined to achieve the super-resolution. In the optical disc device to which the method is applied, the influence of side lobes in the focused beam on the optical disc medium and the optical sensor portion for information detection, which is the above-mentioned problem, is reduced and signal reproduction with higher density is performed.

[0021]

In order to achieve the above-mentioned object, the present invention has a light intensity satisfying a temperature exceeding a thermal threshold value (Curie temperature) in a reproducing state of a super-resolution optical disk, and A super-resolution optical head and a super-resolution optical disk can realize high-density reproduction in a temperature range that is not thermally affected by side lobes formed by a focused beam in the super-resolution optical head.

Further, by removing the side ropes by the spatial filter, the influence of the side lobes is eliminated, and the photodetection of only the main lobe is performed to reduce the inter-pit interference or the inter-bit interference in the case of magneto-optical. I am trying to do it.

As described above, the super-resolution recording method and the optical disc apparatus of the present invention realize higher density recording by combining the super-resolution optical disc and the reduction of the focused beam diameter by the super-resolution optical head. .

Therefore, specifically, according to the super-resolution recording method of the present invention, in a recordable and erasable disc having at least a two-layer structure composed of at least an upper layer and a lower layer, the super-resolution recording method is performed according to the light intensity distribution of the reproducing beam. When a disc temperature is determined, an opening is generated in the upper layer film, and a super-resolution optical disc that reproduces the information recorded in the lower layer through this aperture is used. With a super-resolution optical head having a light-shielding band in the optical path from the beam splitter to the beam splitter, when the light intensity at the center of the focused beam is 100%, the beam diameter of 50% of the light beam intensity It is characterized in that the beam diameter is set to 90% or less in the case where there is no light, and the information recorded on the super-resolution optical disk is reproduced.

This super-resolution optical head technology is described in the literature: Yamanaka, Kubota: "High-density recording of optical discs by super-resolution", "Optics", Vol. 18, No. 12, PP. 691-69
It is listed in 2. According to this, it is possible to narrow down to 80% of the focused beam limited by the Airy disk.

The optical disc apparatus of the present invention is a recordable / erasable disc having at least a two-layer structure composed of at least an upper layer and a lower layer, and the upper layer film is formed by the temperature rise of the disc determined by the light intensity distribution of the reproducing beam. A super-resolution optical disk that generates an opening in the optical disk and reproduces information recorded in the lower layer through this opening, and a light-shielding band is provided in the optical path from the laser to the beam splitter to record information on the super-resolution optical disk. An optical disc device having a super-resolution optical head for reproducing, wherein a light-shielding band of the super-resolution optical head has a light intensity of 1 at a center of a focused beam by an objective lens.
It is characterized in that the size of the beam having a beam light intensity of 50% when it is set to 00% is 90% or less of the size of the beam when there is no light-shielding band of the super-resolution optical head.

In the optical disk device of the present invention, the above-described super-resolution optical head includes a laser, a collimator lens for converting a beam emitted from the laser into parallel light, and a light-shielding band for blocking the collimated beam of parallel light from the collimator lens. The first beam splitter and the second beam splitter that transmit the beam in which the low-frequency part of the parallel light is blocked by the light blocking band, and the beam that passes through the second beam splitter are focused on the super-resolution optical disk surface. The objective lens that emphasizes and focuses the signal component near the center of the super-resolution optical disc and transmits the reflected light beam consisting of the main lobe and side lobes from the optical disc surface and the objective lens that passes through the objective lens and makes a right angle with the second beam sprinter. The half-wave plate that receives the deflected reflected light beam and tilts the plane of polarization by 45 degrees and the plane of polarization that is tilted by 45 degrees by the half-wave plate A spatial filter that removes the side lobes of the incident light beam, a Wollaston prism that linearly polarizes the main rope beam of the reflected light beam that has passed through the spatial filter, and a linearly polarized main rope beam that is received by the Wollaston prism and receives the difference. Two element optical sensors for dynamic magneto-optical detection, the objective lens and the second beam sprinter, and the reflected light beam from the super-resolution optical disk surface bent at a right angle by the first beam sprinter is received to focus and An optical sensor for detecting a tracking error signal is provided.

[0028]

Embodiments of the present invention will now be described with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of a super-resolution optical head and a super-resolution optical disc of the present invention, and FIG. 2 is a diagram for explaining the arrangement of light-shielding bands of the super-resolution optical head corresponding to the digital recording of the present invention. 3 is a diagram for explaining super-resolution recording / reproduction corresponding to digital recording using the super-resolution optical head of FIG. 2, and FIG. 4 is an arrangement of light-shielding bands of the super-resolution optical head corresponding to analog recording of the present invention. 5 is a diagram for explaining super-resolution recording / reproduction corresponding to digital recording using the super-resolution optical head of FIG. 4, and FIG. 6 is a focused beam of the super-resolution optical head of the present invention. It is a figure for demonstrating the high-density reproducing method by a super-resolution optical disk.

Next, a super-resolution recording method and an optical disc apparatus according to claims 1, 2, 3, and 6 will be described with reference to FIG.

The beam emitted from the laser 101 becomes a collimated beam of parallel light by a collimator lens 102,
After passing through the light blocking zone 103, the beam goes straight through the beam splitters A 104 and B 105, and reaches the objective lens 106.

The focused beam forms a super-resolution pattern by the light-shielding band 103, and a side lobe 108 is generated in addition to the focused beam of the main lobe 107.

The reflected light from the optical disk 109 returns to the beam splitter B105 and is subjected to magneto-optical detection. That is, the reflected light passes through the half-wave plate 110, the plane of polarization is tilted 45 degrees about the optical axis, and the beam focusing lens 11
1 through a spatial filter 112 that removes the super-resolution side lobes. Then, the beam passes through a Wollaston prism 113, and a magneto-optical detection is performed by a differential using an optical sensor 114 composed of two elements. Also,
A part of the reflected light from the optical disk 109 is bent by 90 ° by the beam splitter A104, and a focus and tracking error signal is detected by the optical sensor 115.

Here, the optical disk 109 is a recordable and erasable disk having at least a two-layer structure composed of at least an upper layer and a lower layer. FIG. 6 shows an example of a super-resolution optical disc which generates an opening in the film and reproduces information recorded in a lower layer through the opening.

As described above, in the super-resolution recording method and optical disc of this embodiment, the light-shielding band 10 is provided in the optical path from the laser 101 of the optical head to the beam splitter A104.
3, the high frequency component of the peripheral portion of the collimated beam of parallel light from the collimator lens 102 is transmitted, the signal component near the center of the focused beam focused by the objective lens 106 is emphasized, and the beam light intensity of the focused beam is increased. Information is reproduced with a beam diameter having a beam light intensity of 50% when the center is 100%.

Further, in order to minimize the size of the beam having a beam light intensity of 50% when the beam light intensity at the center of the focused beam is 100%, the width of the light shielding band 103 is set to 10% or more of the diameter of the collimated light. With this setting, the beam diameter can be set to 90% or less of the beam diameter of 50% of the beam light intensity when there is no super-resolution without the light-shielding band 103, and thus the information on the optical disc 109 is reproduced.

Next, these will be described in detail.

First, a super-resolution recording / reproducing and an optical disc apparatus corresponding to the digital recording according to claim 3 will be described with reference to FIGS. 2 and 3.

FIG. 2 shows a rotation center 201 of the super-resolution optical disk.
And a focused beam pattern 204 focused on a super-resolution optical disc by an arrangement of a digital light-shielding band 202 and an objective lens 203 are shown. In the digital method, the crosstalk between adjacent tracks depends on the error correction ability, but
Since there is no problem if it is about 0 dB, a long light-shielding band 202 is arranged in the radial direction of the super-resolution optical disc.

FIG. 3 shows the focused beam shown in FIG. 2 in three views. That is, a plan view 302, an elevation view 303, and a side view 304 of an optical disc track 301 of a super-resolution focused beam having side lobes are shown. The super-resolution is applied in the tangential direction 305 of the optical disc, the temperature of the disc reproducing layer is raised when reading the super-resolution optical disc, and the signal of the recording layer thereunder is reproduced through a mask (window).
This window portion 306 is shown by hatching. At this time, since the window portion 306 does not spread to the side lobe 308 due to the temperature rise, the side lobe 308 accompanying the beam focusing due to super-resolution does not become a big problem. As shown in the elevation view 303 and the side view 304, the size of the window portion 306 is such that the light intensity at the beam center of the main lobe 307 of the substantially Gaussian beam at the center of the focused beam having the side lobes 308 is 100%. Corresponds to the size of the beam diameter of 50% light intensity. This part is shown by the diagonal lines in the above three views.

Next, a super-resolution recording / reproducing and an optical disk device corresponding to the analog recording according to claim 4 will be described with reference to FIGS. 4 and 5.

FIG. 4 shows a super-resolution optical head compatible with analog recording. Long axis 4 of the elliptical main lobe 401 of the focused beam
Reference numeral 02 indicates the direction along the optical disc tangential direction. In analog recording, image quality deteriorates due to the influence of crosstalk between adjacent tracks, and good signal reproduction cannot be performed unless the amount of crosstalk is less than -40 dB. For this reason, the super-resolution effect is used so that the beam convergence in the disk radial direction can be increased. For this purpose, a light-shielding band 404 extending in the tangential direction of the optical disc is arranged on the collimator beam 403 of the optical head.

FIG. 5 shows a plan view 501, an elevation view 502, and a side view 503 of the focused beam in which the major axis of the elliptical main lobe of the focused beam of FIG. 4 is along the optical disk tangential direction.

The super resolution is used in the radial direction of the optical disc to increase the temperature of the disc reproduction layer when reproducing information from the super resolution optical disc, and the signal of the recording layer thereunder is reproduced through a mask (window portion) 504. I do. Side lobe 5 at this time
Since the reference numeral 06 does not cover the window portion 504 due to a temperature rise, the super-resolution side lobe 506 does not become a significant problem. The effective beam is shown by diagonal lines in the elevation view 502 and the side view 503. As shown in this figure, the side lobes 506 do not leak into the main beam 505.

Further, for analog recording, leakage from adjacent tracks, that is, crosstalk is a major problem, but since the major axis direction of the focused elliptical beam is in the disc tangential direction, it is a conventional reproducing method. Thirty
Although the limit of obtaining the crosstalk of dB is limited, the combination of the super-resolution optical disk and the super-resolution optical head obtains the crosstalk of -40 dB.

Next, a high-density reproducing method using a focused beam and a super-resolution optical disk of the super-resolution optical head of the present invention and an optical disk apparatus will be described with reference to FIG.

As described in the section of the prior art, a magneto-optical disk medium is taken as an example of a super-resolution optical disk, and the magneto-optical disk medium has a two-layer film structure of a reproducing layer 601 and a recording layer 602. When the Gaussian reproduction light is focused on the magneto-optical disk medium, the magnetic domain 603 written on the recording layer at a threshold temperature of about 120 ° C. emerges in a window portion 601 a of a part of the reproduction layer 601, and the objective lens 605 When the signal is reproduced with an aperture having a diameter 608 of about 50% of the central light intensity as compared with the focused Gaussian beam 606 reproduced with a beam diameter 607 of e- ² (13.5%) light intensity, the conventional diameter is obtained. Is less than 1/2 of the diameter. In the range of the beam diameter of 50% or more of the central light intensity, the reproducing layer is heated by the temperature rise due to the light intensity, and the recording signal is reproduced from the recording layer 602 having perpendicular magnetic anisotropy through the window portion 601a. Here, a side lobe 609 is generated in the Gaussian beam 606 condensed by the light-shielding band 604 and the objective lens 605 constituting the super-resolution optical head. However, as described above, the temperature rise of the magneto-optical disk medium, which is a super-resolution optical disk, due to the side lobes 609 does not reach the threshold temperature, so that the side lobes 609 have no effect.

[0048]

As described above, the super-resolution recording method and the optical disc apparatus of the present invention combine the super-resolution optical disc and the super-resolution optical head to mask a part of the super-resolution optical disc at the time of reproduction. The side filter is removed by the spatial filter of the resolution optical head, and the optimum focused beam form according to the analog or digital recording form is focused on the super-resolution optical disc, so that the linear velocity direction of signal recording / reproduction in the optical disc device or The optical modulation degree (MTF) in the radial direction of the disc can be greatly increased to achieve high resolution of signal recording / reproduction, and optical recording useful for high density and high bit rate compatible such as next-generation HDTV. It is possible to provide a method and an optical disc device.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an embodiment of a super-resolution optical head and a super-resolution optical disc of the present invention.

FIG. 2 is a diagram for explaining the arrangement of light-shielding bands of the super-resolution optical head corresponding to the digital recording of the present invention.

FIG. 3 is a diagram for explaining super-resolution recording / reproduction corresponding to digital recording using the super-resolution optical head of FIG. 2;

FIG. 4 is a diagram for explaining the arrangement of light-shielding bands of a super-resolution optical head corresponding to analog recording of the present invention.

5 is a diagram for explaining super-resolution recording / reproduction corresponding to digital recording using the super-resolution optical head of FIG.

FIG. 6 is a diagram for explaining a high-density reproducing method using a focused beam and a super-resolution optical disk of the super-resolution optical head of the present invention.

FIG. 7 is a diagram for explaining a focused beam of a conventional super-resolution optical head and a super-resolution optical disc.

[Description of Reference Signs] 101 laser 102 collimator lens 103 light-shielding band 104 beam splitter A 105 beam splitter B 106 objective lens 103 light-shielding band 107 main lobe 108 side lobe 109 optical disk 110 1/2 wavelength plate 111 beam focusing lens 112 spatial filter 113 worrus Ton prism 114 Optical sensor 115 Optical sensor 201 Rotation center 202 Light-shielding band 203 Objective lens 204 Focused beam pattern 301 Optical disk track 302 Plan view 303 Elevation view 304 Side view 305 Tangent direction 306 Window portion 307 Main lobe 308 Side lobe 401 Main lobe 402 Long axis 403 Collimator beam 404 Shading band 501 Plan view 502 Elevation view 503 Side view 504 Window part 505 Main lobe 06 side lobe 601 reproducing layer 601a window portion 602 recording layer 603 magnetic domain 604 light-shielding band 605 objective lens 606 Gaussian beam 607 beam diameter 608 50% diameter 609 side rope 701 reproducing layer 701a window portion 702 recording layer 6 703 objective lens 70 magnetic domain Gaussian beam 707 Beam diameter 708 50% diameter

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display location G11B 11/10 D 9296-5D

Claims (6)

[Claims] 1. In a recordable / erasable disc capable of having a two-layer structure or more having at least an upper layer and a lower layer, an opening is made in the upper layer film due to a temperature rise of the disc determined by a light intensity distribution of a reproducing beam. Raise the part,
A super-resolution optical head having a light-shielding band in the optical path from the laser to the beam splitter when recording and reproducing information by using the super-resolution optical disk for reproducing information recorded in the lower layer through this opening. According to the above, the beam diameter with a beam light intensity of 50% when the light intensity at the center of the focused beam is 100% is 90% or less of the beam diameter without the light-shielding band of the super-resolution optical head. A super-resolution recording method characterized by reproducing the information recorded in the above. 2. In a recordable / erasable disc which can have a two-layer structure including at least an upper layer and a lower layer, an opening portion is formed in the upper layer film due to a temperature rise of the disc determined by a light intensity distribution of a reproducing beam. A super-resolution optical disc that generates and reproduces information recorded in the lower layer through this opening, and a light-shielding band is provided in the optical path from the laser to the beam splitter to record and reproduce information on the super-resolution optical disc. An optical disk device having a super-resolution optical head, wherein a beam diameter of 50% of the beam light intensity when the light intensity at the center of the focused beam by the objective lens is 100% in the light-shielding band of the super-resolution optical head. 90% of the beam diameter without the light-shielding band of the resolution optical head
An optical disk device characterized by being arranged as follows. 3. A super-resolution optical head, a laser, a collimator lens for converting a beam emitted from the laser into parallel light, a light-shielding band for shielding the collimated beam of parallel light from the collimator lens, and the light-shielding band. In the first beam splitter and the second beam splitter that transmits the beam where the low-frequency part of the parallel light is shielded, and the beam that has passed through the second beam splitter is focused on the super-resolution optical disc surface. An objective lens that emphasizes and focuses a signal component near the center and transmits a reflected light beam composed of a main lobe and a side lobe from the surface of the super-resolution optical disk, and a right angle that passes through the objective lens and is transmitted by the second beam sprinter. The half-wave plate that receives the reflected light beam that is polarized at a tilt angle of 45 degrees and the half-wave plate tilts the polarization surface by 45 degrees A spatial filter that removes the side lobes of the reflected light beam that has been eclipsed, a Wollaston prism that linearly polarizes the main rope beam of the reflected light beam that has passed through the spatial filter, and a main rope that is linearly polarized by the Wollaston prism. Element optical sensors for receiving the beam of the above and detecting the differential magneto-optical, and the super-resolution optical disk surface which is transmitted through the objective lens and the second beam sprinter and is bent at a right angle by the first beam sprinter. 3. An optical disk device according to claim 2, further comprising an optical sensor which receives a reflected light beam from the optical sensor and detects a focus and tracking error signal. 4. A signal component near the center of the focused beam in the radial direction of the surface of the super-resolution optical disk is emphasized with respect to elliptic light having a major axis in the tangential direction of the surface of the super-resolution optical disk in the light-shielding band. 3. The arrangement according to claim 2, wherein
Alternatively, the optical disk device according to claim 3. 5. The light-shielding band is arranged so that the beam is arranged at a right angle to the direction of the beam, and the signal component near the center of the focused beam is emphasized in the tangential direction of the surface of the super-resolution optical disc. The optical disk device according to claim 2 or 3, wherein 6. The optical disk device according to claim 2, wherein the width of the light-shielding band is 10% or less of the diameter of the collimated beam.