JPH10199009A - Photodetecting means, optical head, optical head adjusting method, and optical recorder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to reproduce a stable high density signal with high resolution and without being affected by the number of revolutions and the reproducing speed of an optical recording medium, by providing a photodetector having a nonlinear effect with a small output efficiency when input light density is small and with a large output efficiency when the input light density is large. SOLUTION: Luminous flux 102 from a semiconductor laser 101 made parallel light by a collimate lens 103 is transmitted through a beam splitter 104 to be converged on the optical recording medium 106 by an objective lens 105. The light reproducing a information pit is reflected by the beam splitter 104 to be separated to an error signal detection part 108 and an information signal detection part 112 by the beam splitter 107. The light made incident on the information signal detection part 112 is converged by a condenser lens 109, and by setting up e.g. a photochromics optical element 110 on a converged position, transmissivity of only a spot central part is increased, and only an optical signal of the central part is picked up selectively, and the high density signal is recorded/reproduced.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light detecting means, an optical head, an optical head adjusting method, and an optical recording apparatus.

[0002]

2. Description of the Related Art For example, as disclosed in JP-A-6-75315, a thin film having a non-linear optical characteristic with respect to this kind of light density is conventionally used for an optical recording medium and transmits a central portion of a spot. By reducing the transmittance of the peripheral portion, light in the peripheral portion is removed, and the pit reproducing resolution is increased. On the other hand, in the optical head, as a method for increasing the pit reproduction resolution, an optical super-resolution effect has been used.

[0003]

However, according to the above-mentioned prior art, a thin film which is non-linear with respect to the light density must be provided on the recording medium, which increases the cost of the recording medium.
Also, current magneto-optical media, CDs and DVD media include:
There is no medium having a thin film that is non-linear with respect to light density, and no improvement in recording density can be expected at present except for reducing the spot shape. As a method for reducing the spot shape, the use of a head for the optical super-resolution effect is currently performed. The spot diameter is reduced by the optical super-resolution effect that gives the intensity distribution on the pupil and the phase difference, but the error rate is increased by increasing the intensity of the side lobe, increasing intersymbol interference, and increasing track crosstalk. There is a problem that increases. In addition, when a thin film that is non-linear with respect to light density is provided on a recording medium, the light reaction speed of the thin film that is non-linear with respect to light density must be increased. That is, since the disk-shaped optical recording medium rotates, the reaction speed must be at least higher than the speed at which the spot moves on the medium.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and does not involve an increase in the cost of an optical recording medium. A main object of the present invention is to provide a light detecting means, an optical head, an optical head adjusting method, and an optical recording apparatus used for high-density recording / reproducing, which can eliminate the disadvantage of the optical super-resolution effect. And

[0005]

The present invention has the following features in order to solve such problems.

(1) The light detecting means of the present invention is provided with a photodetector having a nonlinear effect in which the output efficiency is low when the input light density is low and the output efficiency is high when the input light density is high. .

(2) In the constitution (1), an optical element using a material whose optical characteristics are nonlinear with respect to the light density is provided.

(3) In the constitution (2), the material is a photochromic material, a thermochromic material, a phase change material or a supersaturated absorbing dye material.

(4) In (2), the optical element includes:
It is characterized by having a film having a nonlinear optical characteristic with respect to the light density on a transparent glass or resin.

(5) In (2), the optical element includes:
A film having a non-linear optical characteristic with respect to light density is provided between the transparent resin covering the light detector and the light detection surface of the light detector.

(6) In (2), the optical element is:
It is characterized in that an antireflection film adapted to the wavelength of the incident light is provided on the light incident surface of the film whose optical characteristics are nonlinear with respect to the light density.

(7) In (2), the optical element is:
It is characterized in that a protective layer is provided on a surface of a film whose optical characteristics are non-linear with respect to light density in contact with air.

(8) In (2), the optical element is:
It is characterized in that at least two or more films whose optical characteristics are nonlinear with respect to the light density are stacked.

(9) In (2), the optical element includes:
It is characterized in that the reaction time of the optical characteristics due to the change in light density is longer than the longest information pit reproduction signal cycle.

(10) In (1), there is provided a photodetector which has almost no electrical output when the light density is low and linearly obtains an electrical output when the light density is equal to or higher than the threshold level. .

(11) In (1), the photodetector has little electrical output when the light density is low, and linearly obtains an electrical output when the light density is equal to or higher than a threshold level. Are array-shaped photodetectors.

(12) In the optical head according to the present invention, the light emitted from the light source is irradiated on the optical recording medium by the objective lens, and the return light reflected by the optical recording medium is guided to the light detecting means, whereby the optical recording is performed. In an optical head for reproducing data from a medium, the output efficiency is low when the input light density is low, and the photodetector has high output efficiency when the input light density is high.

(13) In the constitution (12), the light detecting means is arranged at a position where the return light is collected by the light collecting means.

(14) The optical head of the present invention irradiates the light emitted from the light source to the optical recording medium by the objective lens through the hologram element, and branches the return light reflected by the optical recording medium by the hologram element. In the optical head for reproducing data from the optical recording medium, an optical element having a nonlinear effect on the optical density is provided between the hologram element and the photodetector. The return light is condensed at a position where the return light is collected.

(15) An optical head according to the present invention is an optical head using a hologram element as a light branching means, in which a semiconductor laser and a photodetector are integrated, and an optical characteristic having a nonlinear effect on light density. The device is arranged at a position between the hologram device and the photodetector where light flux is condensed substantially.

(16) An optical head according to the present invention is an optical head using a hologram element as a light branching means, wherein an optical element having an optical characteristic having a non-linear effect on light density is arranged on a photodetector. It is characterized by.

(17) An optical head according to the present invention is an optical head using a hologram element as a light branching means, wherein an optical element having an optical characteristic having a non-linear effect on light density is provided by:
The hologram element is arranged on a light exit surface opposite to a light entrance surface forming the hologram element.

(18) In (15), a thin film having a non-linear effect of optical characteristics on light density is formed on a resin or a transparent glass integrally sealing the semiconductor laser and the photodetector. It is characterized by being arranged.

(19) The optical head of the present invention irradiates the light emitted from the light source to the optical recording medium by the objective lens through the hologram element, and branches the return light reflected by the optical recording medium by the hologram element. In the optical head that reproduces data from the optical recording medium by guiding the optical detector to the optical detector, the optical detector whose electric output is non-linear with respect to the light density is arranged almost at the condensing position of the light flux. It is characterized by.

(20) An optical head according to the present invention is an optical head using a hologram element as a light branching means, in which a photodetector and a semiconductor laser are integrated, and whose electrical output is nonlinear with respect to light density. It is characterized in that the detector is arranged substantially at the light-converging position of the light beam.

(21) In the optical head according to the present invention, the light emitted from the light source is irradiated on the optical recording medium by the objective lens, and the return light reflected by the optical recording medium is guided to the light detecting means, whereby the optical recording is performed. In an optical head that reproduces data from a medium, light emitted from a light source is irradiated on the optical recording medium by the objective lens via an optical element having an optical super-resolution effect, and the light detection unit detects input light. When the density is low, the output efficiency is low, and when the input light density is high, the output efficiency is high.

(22) In the constitution (21), the optical element is a transmittance distribution variable filter.

(23) In the constitution (21), the optical element is a variable phase filter for changing a phase distribution of light.

(24) In the optical recording apparatus of the present invention, the light emitted from the semiconductor laser is irradiated on the optical recording medium by the objective lens, and the return light reflected by the optical recording medium is guided to the light detecting means. An optical head for reproducing data from the optical recording medium; the output efficiency is low when the input light density is low; and the output efficiency is high when the input light density is high. A semiconductor laser power control means for controlling the power of the semiconductor laser so that the frequency component is constant is provided.

(25) In (24), the output is:
The output signal from the error signal detector is a sum signal.

(26) In (24), only when the tracking servo is applied, the power of the semiconductor laser is controlled so that the low-frequency component of the output of the return light from the optical recording medium is constant. When the tracking servo is not applied, a control circuit is provided for controlling the power of the semiconductor laser by a monitor output for monitoring the forward emission light or the backward emission light of the semiconductor laser.

(27) In the optical head according to the present invention, the light emitted from the light source is irradiated on the optical recording medium by the objective lens, and the return light reflected by the optical recording medium is guided to the light detecting means, whereby the optical recording is performed. An optical head for reproducing data from a medium is characterized in that an optical element having an irreversible change in optical characteristics with respect to light density is used as the light detecting means.

(28) In the optical head according to the present invention, the light emitted from the light source is irradiated on the optical recording medium by the objective lens, and the return light reflected by the optical recording medium is guided to the light detecting means, whereby the optical recording is performed. In an optical head for reproducing data from a medium, an optical element having an irreversible property in which optical characteristics change with respect to a light wavelength is used as the light detecting means.

(29) In the optical head adjusting method of the present invention, the light emitted from the light source is irradiated on the optical recording medium by the objective lens, and the return light reflected by the optical recording medium is guided to the light detecting means. After assembling an optical head for reproducing data from an optical recording medium, the optical head comprising an optical element having an irreversible property in which an optical property with respect to a light wavelength or a light density is irreversible is assembled. By irradiating a semiconductor laser power that is sufficient to change the element and is at least higher than the information recording pit reproducing power,
The optical element is irreversibly changed.

(30) In the optical head adjusting method of the present invention, the light emitted from the light source is irradiated on the optical recording medium by the objective lens, and the return light reflected by the optical recording medium is guided to the light detecting means. After assembling an optical head for reproducing data from an optical recording medium, the optical detection device having an optical element having an irreversible property in which a change in an optical property with respect to a light wavelength or a light density is provided in the light detecting means. The optical element is irreversibly changed by focusing on a mirror portion of a medium having higher reflectance than the optical recording medium and irradiating the optical element with the reflected light.

(31) In the optical head adjusting method of the present invention, the light emitted from the light source is irradiated on the optical recording medium by the objective lens, and the return light reflected by the optical recording medium is guided to the light detecting means. After assembling an optical head that reproduces data from an optical recording medium, the optical head having an optical element having an irreversible property in which a change in optical characteristics with respect to a light wavelength or a light density is provided in the light detection means, The optical element is irreversibly changed by focusing the optical recording medium using light having a wavelength different from that for reproducing information recording pits and irradiating the optical element with reflected light.

(32) In the optical recording apparatus of the present invention, the light emitted from the light source is irradiated on the optical recording medium by the objective lens, and the return light reflected by the optical recording medium is guided to the light detecting means, whereby the light After assembling an optical head for reproducing data from a recording medium, wherein the optical head includes an optical element having an irreversible property in which an optical characteristic changes with respect to a light wavelength or a light density, An optical head is provided, wherein the optical element is irreversibly changed by focusing on a mirror portion of a medium having a higher reflectance than the recording medium and irradiating the optical element with the reflected light.

[0038]

According to the above configuration of the present invention, 1) Photochromic materials, thermochromic materials, phase-change materials, and supersaturated absorbing dye materials are examples of nonlinear materials whose transmittance reversibly changes depending on the light density. . Hereinafter, a film using a photochromic material will be described as a typical example. By providing the photochromic film at the light condensing position of the light detection unit, the transmittance can be changed depending on the density of light at the light condensing position. In other words, the light density is high at the center of the spot where the light intensity is high, thereby increasing the transmittance of the photochromic thin film. Conversely, the light density is low around the spot where the light intensity is low,
Thereby, the transmittance of the photochromic thin film decreases. Therefore, only the center of the spot is incident on the photodetector, and the periphery of the spot is removed. The shape of the focused spot on the optical recording medium and the shape of the focused spot on the photochromic thin film are similar, and the relationship between the spot center and the peripheral portion on the optical recording medium and the spot center on the photochromic thin film are similar. The relationship between and the peripheral part is almost the same. Therefore, removing the spot peripheral portion on the photochromic thin film is equivalent to substantially removing the spot peripheral portion on the optical recording medium, and has the effect of increasing the resolution for reproducing information pits. Reproduction becomes possible.

2) Some photochromic materials have a refractive index that varies depending on the density of light. If a multilayer film of such a material is used, the same effect as that of the type that changes the transmittance described in (2) can be obtained. Can be

3) The photoreaction time of the photochromic thin film used in the present invention may be slow since it is not on the recording medium. In other words, when the recording medium is on the recording medium, the recording medium rotates, so that a photoreaction speed that can follow the linear velocity is required. Very slow and good. In an extreme case, if only the center of the spot becomes transparent, an irreversible change that does not cause a change may be used.

4) The photodetector used in the present invention has almost no electric output when the light density is small, and generates an electric output when the light intensity exceeds a certain intensity. The electrical output is obtained linearly. Accordingly, the super-resolution effect described in (2) can be obtained by this photodetector, and reproduction of a high-density recording medium becomes possible.

5) The side rope of the light spot obtained by the optical head having the optical super-resolution effect can be removed by the above-mentioned light detecting means.

[0043]

BEST MODE FOR CARRYING OUT THE INVENTION

(Embodiment 1) FIG. 1 is a schematic view of an optical head according to Embodiment 1 of the present invention. A light beam 102 emitted from a semiconductor laser 101 becomes parallel light by a collimating lens 103,
The light enters the beam splitter 104. The light transmitted through the beam splitter 104 is collected on an optical recording medium 106 by an objective lens 105. The light obtained by reproducing the information pits on the optical recording medium 106 is reflected by the beam splitter 1 104 and guided to the light detecting unit. The beam splitter 107 separates the signal into an error signal detector 108 and an information signal detector 112. The light that has entered the information signal detection unit 112 is condensed by the condensing lens 109, and the photochromic optical element 110 is
Is installed. All the light transmitted through the photochromic optical element 110 enters the photodetector 111.

Next, the photochromic optical element shown in Embodiment 1 will be described. FIG. 2A shows the light density with respect to the radial position of the spot. Since the intensity of the condensed spot increases toward the center, the light density expressed as the intensity of light per unit area decreases in proportion to the intensity as the distance from the center increases. FIG. 2B shows the transmittance of the photochromic optical element with respect to the light density. The transmittance is low at the light density around the spot, and the transmittance sharply increases at the light density near the center of the spot. FIG. 3 is a schematic diagram showing the effect of the photochromic optical element on the actual spot cross-sectional view. The horizontal axis shows the distance from the center of the spot, and the vertical axis shows the light density. Reference numeral 301 denotes a cross-sectional view of the spot intensity distribution. Reference numeral 302 denotes a light density at which the transmittance of the photochromic optical element changes. In a region 303 having a higher light density than 302, the transmittance becomes higher, and in a region 304 having a lower light density than 302, the transmittance becomes lower. Therefore, the transmitting portion indicated by 305 is substantially transmitted toward the photodetector, and the portion indicated by 306 is shielded from light and does not reach the photodetector. As a result, only the central portion of the spot can be selectively picked up by the photodetector, and high-density recording and reproduction can be performed by the super-resolution effect. Here, a photochromic material is used for a material whose optical characteristics are non-linear with respect to light density, but a material whose optical characteristics are non-linear with respect to other light densities,
For example, the same effect can be obtained with an optical element using a thermochromic material, a phase change material, or a saturable absorbing dye material.

(Embodiment 2) FIG. 4 is a schematic view of a photochromic optical element according to a second embodiment of the present invention. 4
Numeral 01 is made of a transparent resin, and a thin film 402 having a photochromic effect is provided on the surface thereof. The transparent resin may be glass. Condensed light beam 403 is transparent resin 4
01 and condensed on the photochromic thin film. Here, in this embodiment, the transparent resin is disposed on the light incident side, but there is no problem if it is disposed on the light exit side. (Embodiment 3) FIG. 5 is a schematic view of a photodetector using a photochromic optical element according to a third embodiment of the present invention. Reference numeral 501 denotes a transparent resin for protecting the photodetector 504;
4. Thin film 5 having photochromic effect on light incident surface
03 is worn. A terminal 502 picks up a signal output from the photodetector. The condensed light beam 505 is a transparent resin 50
1 and is condensed on the photochromic thin film 503. Here, the light around the spot is removed by a filter effect based on the light density, and the light enters the photodetector 504. Therefore, high-density optical recording / reproducing with a super-resolution effect can be realized with one photodetector having a photochromic thin film.

(Embodiment 4) FIG. 6 is a schematic view of a photodetector using a photochromic optical element according to a fourth embodiment of the present invention. A photodetector 601 has a light incident surface on which a thin film 602 having a photochromic effect is attached. Reference numeral 603 denotes a multilayer antireflection film for suppressing the reflectance at the wavelength of the incident light 604. This antireflection film may be a single-layer antireflection film. Thereby, the loss of the incident light 604 is eliminated until the light reaches the photochromic thin film, and a high-density recording / reproducing optical head having a good s / n can be realized.

(Embodiment 5) FIG. 7 is a schematic view of a photodetector using a photochromic optical element according to a fifth embodiment of the present invention. A photodetector 701 has a light incident surface on which a thin film 702 having a photochromic effect is attached. 703 is a thin film 702 having a photochromic effect
And protects the photochromic thin film 702 from deterioration due to oxygen, moisture, and the like. Further, this protective layer may be a dielectric film having an antireflection effect on the incident light 704 described in the fourth embodiment. As a result, deterioration of the photochromic thin film due to aging can be prevented, and a stable photochromic effect can be maintained.

(Embodiment 6) FIG. 8 is a schematic diagram showing characteristics of a photochromic optical element used in a sixth embodiment of the present invention. The photochromic optical element shown here has a photochromic effect in which the refractive index changes with the light density. When the light density is plotted on the horizontal axis and the refractive index is plotted on the vertical axis, the light density around the spot shows a substantially constant refractive index. In the density, the amount of change in the refractive index reaches about 0.05. With a multilayer film in which a thin film having such photochromic characteristics and a dielectric film are stacked, a thin film whose transmittance can be changed with respect to the light density shown in FIG. 9 can be realized.

(Embodiment 7) FIG. 10 is a schematic diagram of a photodetector in Embodiment 7 of the present invention. The condensed light beam 1005 is split by the beam splitter 1002. The light transmitted through the beam splitter 1002 enters the error signal detection unit 1001. On the other hand, beam splitter 100
The light reflected by 2 is condensed on the exit end face of the beam splitter. A photochromic thin film 1003 is attached to the end face of the beam splitter. The peripheral portion of the spot is removed by this film, and the light enters the photodetector 1004.
By obtaining a photodetection output of 1004, high-density recording / reproduction having a super-resolution effect becomes possible. In addition, the photochromic thin film can be installed in either the one whose transmittance changes with respect to the light density shown in the first embodiment or the one whose refractive index changes with respect to the light density shown in the sixth embodiment.

(Embodiment 8) FIG. 11 shows an optical head in which a hologram element is used as a light splitting means in Embodiment 8 of the present invention.
Light 1107 emitted from the semiconductor laser 1101 passes through the hologram element 1102 and is focused on the optical recording medium 1104 by the objective lens 1103. Optical recording medium 1104
The light obtained by reproducing the above information pit is diffracted by the hologram element 1102 and guided to the light detection unit. The + 1st-order diffracted light 1109 of the hologram element 1102 enters the error signal detector of 1110, and the -1st-order light 1108 enters the information signal detector. The light that has entered the information signal detection unit is focused on the photochromic optical element 1106. All the light transmitted through the photochromic optical element 1106 is incident on the photodetector 1105. Accordingly, a super-resolution effect can be obtained by the photochromic optical element 1106, and a high-density recording / reproducing head using a hologram element and having a small number of optical components can be realized.

Ninth Embodiment FIG. 12 shows an optical head according to a ninth embodiment of the present invention in which a hologram element is used as a light splitting unit and a semiconductor laser and a photodetector are integrated. Light 120 emitted from a semiconductor laser 1201 provided on a substrate of a photodetector
Reference numeral 2 denotes an objective lens 120 which transmits through the hologram element 1203 and
4 converges on the optical recording medium 1205. The light obtained by reproducing the information pits on the optical recording medium 1205 is diffracted by the hologram element 1203 and guided to the light detecting section. The + 1st-order diffracted light 1207 of the hologram element 1203 is 121
The zero-order error signal detector enters, and the -1st order light 1206 enters the information signal detector. The light that has entered the information signal detector is collected on the photochromic optical element 1209. All the light transmitted through the photochromic optical element 1209 is incident on the photodetector 1208. Therefore, a super-resolution effect was obtained with the photochromic optical element 1209, and a high-density recording / reproducing head using a hologram element and having a small number of optical components was realized. The semiconductor laser photodetector integrated element, the hologram element, and the objective lens
An integrated drive type super-resolution optical head that forms one part by 211 and performs focusing and tracking of the entire part can be realized.

(Embodiment 10) FIG. 13 shows Embodiment 1 of the present invention.
0 indicates an optical head using a hologram element as a light branching means. Semiconductor laser 130 provided on substrate of photodetector
The light 1302 emitted from 1 passes through the hologram element 1303 and is focused on the optical recording medium by the objective lens. The light obtained by reproducing the information pits on the optical recording medium is diffracted by the hologram element 1303 and guided to the light detecting section. The + 1st-order diffracted light 1304 of the hologram element 1303 is 1308
-1st order light 1305 is guided to the information signal detector. Surface 1 from which diffracted light from the hologram of the optical element constituting hologram element 1303 is emitted
A photochromic optical element 1306 is provided on 309, and a light beam is focused on the photochromic optical element 1306. All the light transmitted through the photochromic optical element 1306 is incident on the photodetector 1307. Therefore,
A super-resolution effect can be obtained by the hologram element and the photochromic optical element 1306 integrated element, and a high-density recording / reproduction head using the hologram element and having a small number of optical components can be realized.

(Embodiment 11) FIG. 14 shows Embodiment 1 of the present invention.
1 shows an optical head in which a semiconductor laser and a photodetector are integrated. A semiconductor laser 1401 is provided on a substrate of a photodetector, and a transparent glass 1401 surrounds the substrate 1409.
5 is sealed. Emitted from the semiconductor laser 1401,
The light is focused on the optical recording medium by the objective lens. The light obtained by reproducing the information pits on the optical recording medium is guided to the light detecting section by the light branching means. One part of the optically branched light enters the error signal detector 1408, and the other part is the information signal detector 140.
7 is incident. The light beam 1403 heading for the information signal detecting unit is formed by a photochromic optical element 14 provided on the lower surface of 1405.
06. Photochromic optical element 140
All the light transmitted through 6 enters the photodetector 1407. Accordingly, a super-resolution effect is obtained by the photochromic optical element 1406, and a high-density recording / reproducing head using a hologram element and having a small number of optical components can be realized. Also, the sealing member 1
Since the photochromic optical element 1406 is provided inside the 405, deterioration factors such as humidity and oxygen can be eliminated, and stable signal detection can be achieved.

(Twelfth Embodiment) A twelfth embodiment of the present invention of an optical head using an irreversible material which maintains its state once it becomes transparent will be described. After the assembling adjustment of the optical head in which the irreversible material is incorporated in the information signal reproducing unit is completed, a special disk having only the mirror unit is prepared, and the focusing servo is applied on the mirror surface. In that state,
The semiconductor laser output is increased to a light density at which only the central part of the spot focused on the irreversible photochromic optical element becomes transparent. This laser output is two to three times the normal reproducing power. The once irreversible optical element which has become transparent does not change thereafter with normal reproduction power, so that a very small pinhole that passes only through the center of the spot can be realized. As a result, only the central portion of the spot can be selectively detected by the photodetector, and high-density reproduction can be performed by the super-resolution effect.

(Thirteenth Embodiment) A thirteenth embodiment of the present invention will be described for an optical head using an irreversible material that maintains its state once it becomes transparent. After the assembly and adjustment of the optical head in which the irreversible material is incorporated in the information signal reproducing unit, a special disk having only the mirror unit and a reflectivity sufficiently higher than the reflectivity of the normally reproduced disk is prepared. Apply focusing servo on the surface. As a result, the intensity of the spot focused on the irreversible optical element becomes about twice as large as that during normal disc reproduction, and irreversible changes occur only in the central portion of the spot to make it transparent. The once irreversible optical element which has become transparent does not change thereafter with normal reproduction power, so that a very small pinhole that passes only through the center of the spot can be realized. As a result, only the central portion of the spot can be selectively detected by the photodetector,
The super-resolution effect enables high-density reproduction.

(Embodiment 14) A fourteenth embodiment of the present invention of an optical head using an irreversible material which maintains its state once it becomes transparent will be described. After the assembly adjustment of the optical head incorporating the irreversible material in the information signal reproducing unit is completed, the information signal reproducing unit is temporarily equipped with a wavelength conversion element and an optical element that corrects the error due to the wavelength of the focusing position of the detection unit. Then, prepare a special disk having a reflectivity sufficiently higher than the reflectivity of the disk to be normally reproduced, and apply focusing servo on the mirror surface. As a result, the light can be condensed on the irreversible optical element, and irreversibility occurs only at the center of the spot due to the difference in the wavelength characteristics of the material, and the spot becomes transparent. Thereafter, the wavelength conversion element and the focus correction optical element are removed to complete the optical head. The once irreversible optical element, which has become transparent, does not change thereafter with normal reproduction power and wavelength, so that a very small pinhole that passes only through the center of the spot can be realized. As a result, only the central portion of the spot can be selectively detected by the photodetector, and high-density reproduction can be performed by the super-resolution effect.

(Embodiment 15) FIG. 15 shows Embodiment 1 of the present invention.
5 shows a schematic diagram of the optical recording device. Semiconductor laser 1
The light beam 1502 emitted from the light source 501 is the collimating lens 1
503 turns into parallel light, and the beam splitter 150
4 is incident. The light transmitted through the beam splitter 1504 is passed through the objective lens 1505 to the optical recording medium 1506.
Focused on top. The light obtained by reproducing the information pits on the optical recording medium 1506 is reflected by the beam splitter 1 1504 and guided to the light detecting unit. The error signal detection unit 1508 and the 1505
Nine information signal detectors. Error signal detector 1
The light incident on 508 generates astigmatism by a condenser lens 1510 and a cylindrical lens 1511, and a focus error signal and a track error signal are detected by a quadrant sensor 1512. On the other hand, the light incident on the information signal detection unit is collected, and a photochromic optical element is installed at the collection position. All the light transmitted through the photochromic optical element is incident on the photodetector. The sensor output is converted into a current and a voltage to reproduce an information signal. As a result, the resolution can be improved by the super-resolution effect even in ordinary focusing, tracking control, and information signal reproduction, and an optical recording device with a high s / n and a low error rate can be realized.

(Embodiment 16) FIG. 16 shows Embodiment 1 of the present invention.
6 is a schematic diagram of semiconductor laser control in the optical recording device No. 6; The light incident on the error signal detection unit is given astigmatism, and is incident as a spot 1602 on the four-divided sensor. A focus error signal 1605 is obtained by a computing unit 1603 that calculates the difference between the sum of the output of the four-divided sensor 1601a and the output of 1601c and the sum of the output of 1601b and the output of 1601d. Also, a four-divided sensor 1601
An arithmetic unit 1604 that calculates the sum of the sum of the output of a and the output of 1601c and the sum of the output of 1601b and the output of 1601d provides a total sum signal 1606. On the other hand, the semiconductor laser 1
The light emitted from the light splitter 609 is split by the beam splitter 1612 and the light is incident on the APC sensor 1611.
The output of the APC sensor 1611 is input to the input selection circuit 1610 together with the total output 1607. The output of the input selection circuit 1610 is input to a semiconductor laser power control circuit 1608 to control the power of the semiconductor laser 1609. The input selection circuit 1610 selects an input by a control line 1613. A tracking servo monitoring circuit 1614 outputs a state where tracking servo is applied and a state where tracking servo is not applied to the control line 1613. Here, when the tracking servo is applied, the total signal 1607 is selected, and otherwise, the AP 1611 is selected.
Select the C sensor output. Here, the output of the APC sensor is the detection of the front emission light, but the output of the rear emission light detection sensor installed in the housing on which the semiconductor laser is mounted may be used. As a result, at the time of reproducing the information signal, the amount of light incident on the information signal detecting section is kept constant with respect to the variation of the reflectance of the optical recording medium, and the super-resolution effect is stably obtained between various optical recording media. Can be

(Embodiment 17) FIG. 17 shows Embodiment 1 of the present invention.
FIG. 7 is a schematic diagram showing an operation in the photodetector of FIG. FIG.
(A) shows the output current with respect to the light density of the photodetector. 1
Reference numeral 701 denotes an output current with respect to the light density.
3, the light output with respect to the light density increases linearly. On the other hand, the output current hardly occurs below the light density at the transition point 1703. Therefore, as shown in FIG.
An output current does not occur in a shaded area below a change point 1703 of the spot cross-sectional view 1702, and only a portion above 1703 is obtained as an output current. As a result, an output current can be selectively generated from the photodetector only at the center of the spot, and high-density reproduction can be performed by the super-resolution effect.

(Embodiment 18) FIG. 18 shows Embodiment 1 of the present invention.
8 is a schematic diagram showing an optical head having an optical super-resolution effect of No. 8; FIG. The light beam 102 emitted from the semiconductor laser 101 is converted into parallel light by the collimator lens 103. In the light beam, a transmittance distribution variable filter 1801 is provided. The transmittance distribution variable filter 1801 is located at the center 1
802 has a low transmittance, and the area of the peripheral portion 1803 has a high transmittance. Variable transmittance distribution type filter 1801
Is incident on the beam splitter 1 104, and the light transmitted through the beam splitter 1 is the objective lens 105.
Is condensed on the optical recording medium 106. At this time, the spot on the medium is changed by the transmittance distribution variable filter 1801.
The spot diameter is smaller due to the optical super-resolution effect as compared with the case without. This effect can be obtained not only in the transmittance distribution variable type filter but also in the phase variable type filter.

FIG. 19 is a schematic view showing a spot sectional view of an optical head according to Embodiment 18 of the present invention. This is a spot cross-sectional view of an optical head in which an optical super-resolution effect has been obtained by the transmittance distribution variable filter 1801 shown in FIG.
1902 shows a cross section of a normal light spot by a density distribution,
1901 shows a density distribution of a cross section of a light spot obtained by the optical super-resolution effect by the transmittance distribution variable filter 1801. Variable transmittance distribution type filter 1801
Although the spot diameter of the light spot obtained by the optical super-resolution effect is smaller, the side lobe is larger. Therefore, the light is incident on a non-linear element having an output inflection point shown in 1903 to thereby make it 1903.
The side lobe having the following light density can be removed, and only the merit of reducing the spot diameter by the optical super-resolution effect can be utilized. The same effect can be obtained by using an optical nonlinear element for the light density.

[0062]

As described above, according to the present invention, 1) By incorporating a photochromic optical element into an optical head, super-resolution high-density signal reproduction can be obtained without affecting the optical recording medium. In addition, signal reproduction by the super-resolution effect can be similarly obtained in an optical recording medium which has already spread in the world. 2) Since the photochromic optical element is incorporated in the optical head, stable super-resolution high-density signal reproduction can be obtained without being affected by the rotation speed of the optical recording medium, the speed of reproducing information, and the like. That is, even in an optical head compatible with high density and a high transfer rate, super-resolution high-density signal reproduction can be obtained even with a photochromic optical element having a low photoreaction speed. As an extreme example, super-resolution high-density signal reproduction is possible even with irreversible changes.

3) By providing the photochromic optical thin film on the photodetector, an inexpensive optical head having a small number of parts and having a super-resolution effect can be realized. Further, by providing an antireflection film and a protective film on the thin film, a photochromic optical element having no loss of light amount and no change with time can be realized.

4) Since the output of the semiconductor laser is controlled by the return light from the optical recording medium, the super-resolution effect can be stably obtained between various optical recording media.

5) Since the side rope of the light spot obtained by the optical head having the optical super-resolution effect can be removed by the light detecting means, the increase in the side lobe, which is a disadvantage of the optical super-resolution effect, can be ignored. In addition, it is possible to obtain a super-resolution effect of only the effect of reducing the spot diameter by the optical super-resolution effect.

[Brief description of the drawings]

FIG. 1 is a schematic diagram illustrating an optical head according to a first embodiment of the present invention.

FIGS. 2A and 2B are schematic diagrams showing a photochromic effect of Example 1 of the present invention.

FIG. 3 is a schematic diagram illustrating a photochromic effect of Example 1 of the present invention.

FIG. 4 is a schematic view showing a photochromic optical element according to Example 2 of the present invention.

FIG. 5 is a schematic view showing a photochromic optical element according to Example 3 of the present invention.

FIG. 6 is a schematic view showing a photochromic optical element according to Example 4 of the present invention.

FIG. 7 is a schematic view showing a photochromic optical element according to Example 5 of the present invention.

FIG. 8 is a schematic diagram showing characteristics of the photochromic optical element of Example 6 of the present invention.

FIG. 9 is a schematic diagram illustrating characteristics of a photochromic optical element according to Example 6 of the present invention.

FIG. 10 is a schematic diagram illustrating a light detection unit according to a seventh embodiment of the present invention.

FIG. 11 is a schematic view showing an optical head according to an eighth embodiment of the present invention.

FIG. 12 is a schematic view showing an optical head according to a ninth embodiment of the present invention.

FIG. 13 is a schematic view showing an optical head according to a tenth embodiment of the present invention.

FIG. 14 is a schematic diagram illustrating an optical head according to an eleventh embodiment of the present invention.

FIG. 15 is a schematic view showing an optical recording apparatus according to Embodiment 15 of the present invention.

FIG. 16 is a schematic view showing an optical recording apparatus according to Embodiment 16 of the present invention.

17 (a) and (b) are schematic diagrams illustrating the operation of a photodetector according to Embodiment 17 of the present invention.

FIG. 18 is a schematic diagram of an optical super-resolution optical head according to Embodiment 18 of the present invention.

FIG. 19 is a schematic diagram showing a spot cross-sectional view of an optical head according to Embodiment 18 of the present invention.

[Explanation of symbols]

 Reference Signs List 110 photochromic optical element 111 photodetector 112 information signal detector 603 antireflection film 604 protective film 1102 hologram element 1608 semiconductor laser power control circuit 1610 input selection circuit

Claims (32)

[Claims] 1. A photodetector comprising: a photodetector having a nonlinear effect in which output efficiency is low when the input light density is low and output efficiency is high when the input light density is high. 2. The light detecting means according to claim 1, further comprising an optical element using a material whose optical characteristic is nonlinear with respect to light density. 3. The light detecting means according to claim 2, wherein said material is a photochromic material, a thermochromic material, a phase change material, or a saturable absorbing dye material. 4. The light detecting means according to claim 2, wherein said optical element has a film having a nonlinear optical characteristic with respect to light density on a transparent glass or resin. 5. The optical element according to claim 2, wherein the optical element has a film whose optical characteristic is nonlinear with respect to light density between a transparent resin covering the photodetector and a photodetection surface of the photodetector. Light detection means. 6. The light detecting means according to claim 2, wherein said optical element has an anti-reflection film adapted to the wavelength of the incident light on a light incident surface of the film whose optical characteristic is nonlinear with respect to light density. . 7. The light detecting means according to claim 2, wherein the optical element has a protective layer provided on a surface of the film having a non-linear optical characteristic with respect to a light density in contact with air. 8. The light detecting means according to claim 2, wherein said optical element has at least two layers of films whose optical characteristics are nonlinear with respect to light density. 9. The light detecting means according to claim 2, wherein the optical element has a response time of an optical characteristic due to a change in light density longer than a longest information pit reproduction signal cycle. 10. The light according to claim 1, further comprising a photodetector that has little electric output when the light density is low and linearly obtains an electric output when the light density is equal to or higher than a threshold level. Detection means. 11. The light detector according to claim 1, wherein the light detector has little electric output when the light density is low, and has an array of minute light detectors that can linearly obtain an electric output when the light density is equal to or higher than a threshold level. 2. The light detecting means according to claim 1, wherein the light detecting means is a detector. 12. An optical head for reproducing data from the optical recording medium by irradiating light emitted from a light source to the optical recording medium by an objective lens and guiding return light reflected by the optical recording medium to light detecting means. 3. The optical head according to claim 1, wherein the output efficiency is low when the input light density is low, and the output efficiency is high when the input light density is high. 13. An optical head according to claim 12, wherein said light detecting means is arranged at a position where said return light is collected by said light collecting means. 14. A light emitted from a light source is irradiated on an optical recording medium by an objective lens through a hologram element, and return light reflected by the optical recording medium is branched by the hologram element and guided to a photodetector. An optical head for reproducing data from the optical recording medium, wherein an optical element having an optical characteristic having a non-linear effect on light density is provided between the hologram element and the photodetector and the return light is condensed. An optical head, wherein the optical head is arranged at a position where 15. An optical head in which a semiconductor laser and a photodetector are integrated and a hologram element is used as a light branching means, wherein an optical element having a nonlinear effect on optical density has a nonlinear effect on light density. An optical head, wherein the optical head is disposed substantially at a position where a light beam is condensed with a detector. 16. An optical head using a hologram element as a light branching means, wherein an optical element having a non-linear effect of optical characteristics with respect to light density is arranged on a photodetector. 17. An optical head using a hologram element as a light branching means, wherein an optical element having an optical characteristic having a non-linear effect on light density is placed on an opposite side to a light incident surface forming the hologram element. An optical head, which is disposed on a light emitting surface. 18. A thin film having a non-linear effect of optical characteristics with respect to light density is disposed on a resin or transparent glass integrally sealing the semiconductor laser and the photodetector. The optical head according to claim 15, wherein 19. A light emitted from a light source is irradiated on an optical recording medium by an objective lens via a hologram element, and return light reflected on the optical recording medium is branched by the hologram element and guided to a photodetector. An optical head for reproducing data from the optical recording medium, wherein a photodetector whose electrical output is non-linear with respect to light density is
An optical head, wherein the optical head is disposed substantially at a light-converging position. 20. An optical head in which a photodetector and a semiconductor laser are integrated and a hologram element is used as a light branching means, wherein a photodetector whose electric output is non-linear with respect to light density is provided.
An optical head, wherein the optical head is disposed substantially at a light-converging position. 21. An optical head for reproducing data from the optical recording medium by irradiating the optical recording medium with light emitted from a light source by an objective lens and guiding return light reflected by the optical recording medium to light detection means. In the above, while irradiating the light emitted from the light source to the optical recording medium by the objective lens via an optical element having an optical super-resolution effect, the light detection means, when the input light density is small, the output efficiency is small An optical head, comprising: a photodetector having a non-linear effect of increasing output efficiency when input light density is high. 22. The optical head according to claim 21, wherein the optical element is a transmittance distribution variable filter. 23. The optical head according to claim 21, wherein the optical element is a variable phase filter that changes a phase distribution of light. 24. Light for reproducing data from the optical recording medium by irradiating the light emitted from the semiconductor laser to the optical recording medium by the objective lens and guiding the return light reflected by the optical recording medium to the light detecting means. A light output means having a low output efficiency when the input light density is low, and a high output efficiency when the input light density is high, wherein the low-frequency component of the output from the light detection means is constant. An optical recording apparatus comprising a semiconductor laser power control means for controlling a power of a laser. 25. The optical recording apparatus according to claim 24, wherein the output is a sum signal of output signals from an error signal detector. 26. Only when a tracking servo is applied, the power of the semiconductor laser is controlled so that a low-frequency component of the output of the return light from the optical recording medium is constant, and no tracking servo is applied. 25. The optical recording apparatus according to claim 24, further comprising a control circuit for controlling the power of the semiconductor laser based on a monitor output for monitoring forward or backward emitted light of the semiconductor laser. 27. An optical head for reproducing data from the optical recording medium by irradiating the optical recording medium with light emitted from a light source by an objective lens and guiding return light reflected by the optical recording medium to light detection means. 3. The optical head according to claim 1, wherein an optical element having an irreversible property of changing optical characteristics with respect to light density is used for the light detecting means. 28. An optical head which reproduces data from the optical recording medium by irradiating the optical recording medium with light emitted from a light source by an objective lens and guiding return light reflected by the optical recording medium to light detecting means. 3. The optical head according to claim 1, wherein an optical element having an irreversible property of changing optical characteristics with respect to a light wavelength is used as the light detecting means. 29. An optical head for reproducing data from the optical recording medium by irradiating the optical recording medium with light emitted from a light source by an objective lens and guiding return light reflected by the optical recording medium to light detection means. After assembling an optical head provided with an optical element having an irreversible property to the optical wavelength or the optical density has an irreversible property, sufficient to change the optical element, and An optical head adjusting method, wherein the optical element is irreversibly changed by irradiating at least a semiconductor laser power higher than an information recording pit reproducing power. 30. An optical head for reproducing data from the optical recording medium by irradiating the optical recording medium with light emitted from a light source by an objective lens and guiding return light reflected by the optical recording medium to light detection means. And after assembling an optical head having an optical element having an irreversible property with respect to a light wavelength or a light density in an optical element having an irreversible property, at least a medium having a higher reflectance than the optical recording medium. An optical head adjustment method, wherein the optical element is irreversibly changed by focusing on a mirror section and irradiating the optical element with reflected light. 31. An optical head for reproducing data from an optical recording medium by irradiating light emitted from a light source to an optical recording medium by an objective lens and guiding return light reflected by the optical recording medium to light detection means. After assembling an optical head provided with an optical element having an irreversible property in which the change in optical characteristics with respect to the light wavelength or light density is irreversible, a light having a wavelength different from that of normal information recording pit reproduction is used. An optical head adjusting method, wherein the optical element is irreversibly changed by focusing the optical recording medium using light and irradiating the optical element with reflected light. 32. An optical head for reproducing data from the optical recording medium by irradiating the optical recording medium with light emitted from a light source by an objective lens and guiding return light reflected by the optical recording medium to light detection means. And after assembling an optical head having an optical element having an irreversible property with respect to a light wavelength or a light density in an optical element having an irreversible property, at least a medium having a higher reflectance than the optical recording medium. An optical recording apparatus, comprising: an optical head in which a mirror unit is irreversibly changed by irradiating the optical element by irradiating the optical element with reflected light.