JP2004039177A - Optical recording medium device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical recording medium device suitable for performing recording/reproduction/deletion on an optical recording medium which has a noble metal oxide layer and records information in the noble metal oxide layer by deforming of into a hollow or gas ball. <P>SOLUTION: The optical recording/reproducing device records, reproduces and deletes information by irradiating an optical disk 1 having the recording medium comprising the noble metal oxide layer with light. A control circuit 8 controls driving of a laser driver 9 and controls the power of a laser beam 2 at recording, which is irradiated with semiconductor laser in an optical pickup 3, in accordance with the amplitude or a peak value of a tracking error signal, which is detected in a monitoring circuit 7. At the time of reproduction, information can be recorded with power with which satisfactory tracking is possible. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical recording medium device that performs at least one of recording, erasing, and reproduction on an optical recording medium on which a recording mark having a size near the diffraction limit of light and smaller than the diffraction limit of light is recorded and reproduced. Things.
[0002]
[Prior art]
Normally, in a reproducing method using a laser beam, there is a resolution limit determined by the diffraction limit of light. Assuming that the wavelength of the laser beam is λ and the numerical aperture of the objective lens is NA, the diffraction limit of light is λ / 2NA and the resolution limit is λ / 4NA.
[0003]
In other words, since the cutoff spatial frequency is 2NA / λ, a recording mark row in which the length of a recording mark is the same as the length of the space between two adjacent recording marks is the same if the spatial frequency is 2NA / λ or less. Then, it becomes readable. In this case, the mark length (space length) corresponding to the readable spatial frequency is λ / 4NA. That is, a read signal cannot be obtained by reading a recording mark row having an arrangement pitch of less than λ / 2NA and a mark length of less than λ / 4NA.
[0004]
Therefore, in order to read out a signal recorded at a high density, it is effective to make the resolution limit smaller, that is, make λ smaller and / or make NA larger. Is being done.
[0005]
On the other hand, apart from the study for reducing the resolution limit, a super-resolution recording / reproducing technology has been proposed as a technology for recording and reading a recording mark smaller than the resolution limit. As a super-resolution recording / reproducing technique, for example, a technique has been proposed in which a layer having a function of forming an opening or the like by laser irradiation is provided in a medium to substantially increase the NA in the medium.
[0006]
As an example, Japanese Patent Application Laid-Open No. 8-185,642 discloses a method for performing super-resolution recording / reproduction by irreversibly deforming a mask layer formed on a substrate. In this example, the recording medium includes a mask layer that is an alloy thin film layer containing at least one element of Ge, Ga, Te, Sn, In, Se, Sb, and As. Then, the recording medium is irradiated with intense light to deform the irradiated portion of the mask layer to form a reproduction window, and a recording mark is formed in the lower recording layer. In reproduction, by irradiating weak light through the reproduction window, a recording mark recorded with a size smaller than the resolution limit is reproduced.
[0007]
[Problems to be solved by the invention]
However, in the super-resolution recording / reproducing technique disclosed in the above publication, the signal-to-noise ratio (SNR) of the reproduced signal is low and not at a practical level. Therefore, there is a problem that it is difficult to perform high-density recording and reproduction by super-resolution recording and reproduction.
[0008]
A sufficiently high SNR is required to read a recording mark having a size smaller than the resolution limit at a linear velocity of a practical optical disc. However, in super-resolution recording / reproduction, as the size of the recording mark becomes smaller than the resolution limit, the amount of signal read out gradually decreases, and the SNR becomes insufficient. Even in the super-resolution recording / reproducing technique disclosed in the above publication, a practical level of SNR cannot be obtained because the recording mark is small.
[0009]
On the other hand, the inventors of the present invention have solved this problem by using a noble metal oxide layer as a recording layer in an optical recording medium having a noble metal oxide layer, and forming a fine recording smaller than the resolution limit on this layer. By recording a mark and performing reproduction with a reproduction power (power = irradiation light intensity) equal to or higher than a threshold value, a high CNR can be obtained in super-resolution reproduction, a practically sufficient SNR can be obtained, and a high reproduction durability can be obtained. And proposed an optical recording / reproducing method and an invention of an optical recording medium prior to the present application (Japanese Patent Application No. 2002-183498, filed on Jun. 24, 2002, Unpublished at the time).
[0010]
However, the prior application proposes a more specific configuration as an optical recording medium device that performs at least one of recording, erasing, and reproduction on a new optical recording medium by the novel optical recording / reproducing method. However, there is no mention of, for example, a method of adjusting a suitable light amount of irradiation light intensity (laser power) at the time of recording, a method of erasing a recorded mark once recorded, a method of further improving reproduction durability, and the like. .
[0011]
The present invention provides a preferred configuration of an optical recording medium device that performs at least recording, erasing, or reproducing on an optical recording medium on which recording / reproduction is performed by the novel optical recording / reproduction method of the prior invention. The purpose is to propose.
[0012]
[Means for Solving the Problems]
In order to achieve the above object, the optical recording medium device of the present invention has a noble metal oxide layer, and information is recorded by deformation of the noble metal oxide layer caused by irradiating the noble metal oxide layer with light. An optical recording medium can be mounted, and the optical recording medium is provided with recording means for recording information as the deformation by irradiating the precious metal oxide layer with light having an intensity at which the noble metal oxide layer is deformed. It is characterized in that the irradiation light intensity is controlled based on the tracking performance of the information recording portion.
[0013]
According to this, the noble metal oxide layer has a noble metal oxide layer, and when the noble metal oxide layer is irradiated with light, the noble metal oxide layer is deformed. The means records information by irradiating the noble metal oxide layer with light having an intensity causing deformation.
[0014]
As described above, such information recording due to the deformation of the noble metal oxide layer is performed by super-resolution in which at least the shortest deformation (recording mark) has a size smaller than the resolution limit and is reproduced. In spite of reproduction, a high CNR is obtained, a practically sufficient SNR is obtained, and a high reproduction durability is obtained.
[0015]
However, in such a recording method, the difference in height between the land and the groove changes with the deformation of the noble metal oxide layer regardless of whether the recording is performed on the land or the groove. Here, if the irradiation light intensity is too strong, the height difference deviates from a range where a desired diffraction state is obtained. Then, the tracking error signal deteriorates, and the tracking performance decreases. On the other hand, if the irradiation light intensity is too high, the deformation length, that is, the length of the recording mark becomes longer, or the height (thickness) of the deformation increases, so that the tracking error signal also deteriorates and the tracking performance decreases. I do.
[0016]
Therefore, in the above configuration, the recording unit controls the irradiation light intensity at the time of recording based on the tracking performance of the information recording portion, that is, the portion having deformation. Thus, stable reproduction can be performed without causing reproduction to become unstable.
[0017]
Further, in this case, it is preferable that the recording unit controls the irradiation light intensity so that the degree of deterioration of the tracking error signal in the information recording portion falls within an area where stable tracking is possible.
[0018]
As described above, since the tracking performance can be detected from the degree of deterioration of the tracking error signal, the irradiation light intensity of the recording means is set so that the degree of deterioration of the tracking error signal falls within a region enabling stable tracking. , Information can be recorded with an appropriate irradiation light intensity that enables stable tracking during reproduction.
[0019]
In phase change recording or magneto-optical recording in which the recording layer is not deformed when recording information, such deterioration of the tracking error signal does not occur. Therefore, the intensity of the irradiation light is adjusted based on the tracking error signal. The configuration to be performed can be said to be a unique configuration of the optical recording medium for recording information by deformation of the noble metal oxide layer.
[0020]
In order to achieve the above object, the optical recording medium device of the present invention has a noble metal oxide layer, and information is recorded by deformation of the noble metal oxide layer caused by irradiating the noble metal oxide layer with light. An optical recording medium can be mounted, and the optical recording medium has an erasing means for erasing light recorded at the deformation by irradiating light having an intensity at which the noble metal oxide layer is deformed, and the erasing means is provided. In addition, the irradiation light intensity at the time of erasing is controlled based on the tracking performance of the information erasing portion.
[0021]
As described above, the recording of information due to the deformation of the noble metal oxide layer is a super-resolution reproduction in which at least the shortest deformation has a size smaller than the resolution limit and is reproduced. Nevertheless, a high CNR can be obtained, a practically sufficient SNR can be obtained, and a high reproduction durability can be obtained.
[0022]
According to the above configuration, the information recorded by the deformation of the noble metal oxide layer is provided with an erasing unit for erasing the noble metal oxide layer by irradiating light having an intensity at which the noble metal oxide layer is deformed, The erasing means is configured to control the irradiation light intensity at the time of erasing based on the tracking performance of the information erasing portion.
[0023]
As a result, it is possible to measure the deterioration of information at the time of information erasure by tracking performance, and by controlling the amount of irradiation light based on the tracking performance of the information erasure part, the information is degraded and securely erased. Can be. Further, the tracking performance of the information erasure part can be adjusted to a desired state.
[0024]
Therefore, for example, by adopting a configuration in which the erasing means controls the irradiation light intensity so that the degree of deterioration of the tracking performance in the information erasure portion is in an area where unstable tracking is possible, the information erasure in the erasure portion is suppressed. By enabling tracking to an unstable degree even if reproduction is not possible, recording or reproduction of information in sectors or blocks adjacent before and after the erased part can be performed smoothly.
[0025]
Also, for example, the erasing means is configured to control the irradiation light intensity so that the degree of deterioration of the tracking performance in the information erasure portion is in a region where tracking is not possible, so that the information recorded by the deformation is never again. It can be completely erased so that it cannot be reproduced, which is particularly effective for erasing confidential information and the like.
[0026]
Further, in order to achieve the above object, the optical recording medium device of the present invention is an optical recording medium device that at least reproduces recorded information by irradiating the optical recording medium with light. The recording medium has a noble metal oxide layer, and information is recorded by deformation of the noble metal oxide layer caused by light irradiation on the noble metal oxide layer, and the deformation is irradiated with light weaker than at the time of recording. The information is reproduced by being performed, the optical recording medium is provided with tracking means for irradiating light to perform tracking to a predetermined track on which information is recorded by deformation of the noble metal oxide layer, The tracking means is characterized in that the intensity of irradiation light is made weaker at the time of standby and at the time of access to move to a predetermined track than at the time of information reproduction.
[0027]
As described above, the recording of information due to the deformation of the noble metal oxide layer is a super-resolution reproduction in which at least the shortest deformation has a size smaller than the resolution limit and is reproduced. Nevertheless, a high CNR can be obtained, a practically sufficient SNR can be obtained, and a high reproduction durability can be obtained.
[0028]
However, such information recording due to deformation of the noble metal oxide layer, even if the irradiation light intensity for reproduction is weaker than the irradiation light intensity for recording, the information recorded by deformation gradually as the irradiation is continued. Has been found to degrade and destroy information.
[0029]
Therefore, according to the above configuration, the tracking means for irradiating the optical recording medium with light to perform tracking to a predetermined track on which information is recorded by deformation of the noble metal oxide layer is provided in a standby mode other than recording and reproduction. At the time of access and at the time of access, the irradiation light intensity is made weaker than at the time of information reproduction. This makes it possible to further improve the reproduction durability of the optical recording medium as compared with a configuration in which light is always radiated at the irradiation light intensity for reproduction, including standby and access, and tracking is performed. .
[0030]
The present invention can also be expressed as follows by using different expressions. In other words, the present invention relates to an apparatus for recording and reproducing information by irradiating a recording medium including a noble metal oxide layer with light, comprising: an optical system having a wavelength λ of light and a numerical aperture NA; Recording means for recording at least a deformation smaller than λ / 4NA by condensing the irradiation light of the above, and reflecting light or transmitted light by irradiating the deformation with a second irradiation light weaker than the first irradiation light And tracking means for monitoring a tracking error signal, and first light quantity control means for controlling the light quantity of the first irradiation light, and the first irradiation light is controlled based on the output of the monitoring means. Characterized by controlling the amount of light
According to the present invention, in addition to the above configuration, the monitoring means detects an amplitude value of a tracking error signal at the time of a track jump after recording the information, and controls the first value at the time of information recording so that the amplitude value does not exceed a predetermined value. Characterized by controlling the amount of irradiation light.
[0031]
According to the present invention, in addition to the above configuration, the monitoring means controls the light amount of the first irradiation light at the time of information recording so that a peak value of a tracking error signal at the time of a track jump after information recording does not exceed a predetermined value. It is characterized by doing.
[0032]
According to the present invention, in addition to the above configuration, the monitoring means detects an amplitude value of a tracking error signal at the time of a track jump after information erasure, and performs the first irradiation at the time of information erasure so that the amplitude value exceeds a predetermined value. It is characterized in that the amount of light is controlled.
[0033]
According to the present invention, in addition to the above configuration, the monitoring means controls the light amount of the first irradiation light at the time of information erasing so that a peak value of a tracking error signal at the time of a track jump after information erasing exceeds a predetermined value. It is characterized by the following.
[0034]
Further, the present invention is an apparatus for recording and reproducing information by irradiating a recording medium including a noble metal oxide layer with light, comprising: an optical system having a wavelength λ of light and a numerical aperture NA; Recording means for recording a deformation smaller than at least λ / 4NA by condensing the irradiation light, and irradiating a second irradiation light of moderate intensity to at least λ / 4NA from reflected light or transmitted light) A reproducing means for reading out a smaller deformation, and a tracking means for irradiating weak third irradiation light to track a track including the deformation during standby or access.
[0035]
As described above, according to the present invention, by monitoring the tracking error signal at the time of recording, it is possible to prevent the intensity of the irradiation light from being excessively increased and perform highly reliable information recording. At the time of erasure, similarly, by monitoring the tracking error signal, the CNR can be degraded and information can be erased. In addition, erasing can be performed so that tracking becomes difficult over the entire surface of the optical recording medium, and confidential information and the like can be surely erased.
[0036]
Also, a signal due to deformation is recorded on the optical recording medium with a strong irradiation light intensity, and a signal of a recording mark shorter than the resolution limit can be reproduced with a medium irradiation light intensity. Further, the deterioration of recorded information can be suppressed by making the irradiation light intensity weaker at the time of standby / access than at the time of reproduction. Further, by providing a noble metal oxide layer such as platinum oxide, a high SNR can be obtained, and deterioration of a reproduced signal can be suppressed.
[0037]
BEST MODE FOR CARRYING OUT THE INVENTION
One embodiment of the present invention will be described below with reference to FIGS.
[0038]
The present inventors, in an optical recording medium having a noble metal oxide layer, using a noble metal oxide layer as a recording layer, this layer has a small recording mark smaller than the resolution limit or larger than the resolution limit but the resolution limit. By recording near minute recording marks and performing reproduction with a reproduction power equal to or higher than the threshold value, a high CNR is obtained in super-resolution reproduction, and a practically sufficient SNR is obtained, and a high reproduction durability is obtained. I found that.
[0039]
FIG. 2 shows a cross-sectional view of an optical disc 1 on which an optical recording medium proposed by the present inventors in the above-mentioned prior application is formed.
[0040]
In the optical disc 1, a first dielectric layer 15, a noble metal oxide layer 16, a second dielectric layer 17, a light absorption layer 18, and a third dielectric layer 19 are formed on a substrate 14 in this order. The first dielectric layer 15, the noble metal oxide layer 16, the second dielectric layer 17, the light absorbing layer 18, and the third dielectric layer 19 constitute an optical recording medium. The structure of the optical disc 1 is not limited to this.
[0041]
The thickness and the material of the optical disc 1 are as follows: the substrate 14 is 0.6 mm polycarbonate, and the first dielectric layer 15 is 130 nm ZnS-SiO. ₂ The noble metal oxide layer 16 is 4 nm of platinum oxide, and the second dielectric layer 17 is 40 nm of ZnS-SiO. ₂ The light absorption layer 18 is made of 60 nm Ag-In-Sb-Te, and the third dielectric layer 19 is made of 100 nm ZnS-SiO. ₂ It is.
[0042]
The optical disc 1 is formed with grooves 21 21 and lands 22 22. The width of each of the land 22 and the groove 22 is 0.6 to 0.7 μm. The groove 21 is a portion that becomes a groove on the substrate 14, and the land 22 is a portion between the grooves.
[0043]
With respect to such an optical disc 1, the present inventors use a semiconductor laser having a wavelength λ = 635 nm and an objective lens 11 having a numerical aperture NA = 0.6 to irradiate light intensity (hereinafter, laser power or power). The recording of a signal of 8 to 12 mW, a linear velocity of 6 m / s, and a recording frequency of 15 MHz was attempted. That is, the power of the laser beam 2 was intensity-modulated at a frequency of 15 MHz with a recording power of 8 to 12 mW and a bias power of 1 mW.
[0044]
As a result, a deformation (recording mark) 20 formed of a cavity or a gas sphere is formed in the noble metal oxide layer 16 corresponding to the irradiation position of the laser beam 2 of the recording power, and the light absorbing layer 18 is entirely formed. Crystallization occurred.
[0045]
This is because the noble metal oxide layer 16 and the light absorbing layer 18 are irradiated with the laser beam 2 having a predetermined power or more (here, stronger than 8 mW), so that the noble metal oxide layer 16 is decomposed (exploded). ) Occurs, the oxygen gas generated by the decomposition of the noble metal oxide causes a volume expansion in the noble metal oxide layer 16 to deform the noble metal oxide layer 16 and the second dielectric layer 17 and the light absorbing layer 18 It is considered that as a result of pushing up, a deformation 20 consisting of a cavity or a gas sphere was formed in the noble metal oxide layer 16.
[0046]
As a result of observation with a transmission electron microscope, it was confirmed that the length of the deformation 20 corresponded to the irradiation time of the laser beam 2 of the recording power and was 200 nm. From the wavelength λ of the semiconductor laser used here and the numerical aperture NA of the objective lens, the resolution limit (λ / 4NA) of the deformation 20 is 260 nm. Therefore, the deformation 20 formed here has a size smaller than the resolution limit.
[0047]
Next, the power of the semiconductor laser was set to 4 mW (reproduction power), and the reproduction of the deformation 20 formed on the noble metal oxide layer 16 was attempted. As a result, it was confirmed that, despite the recording pitch of the modification 20 being equal to or less than the resolution limit, a CNR (Carrier to Noise Ratio) as high as 40 dB was obtained, and that a practically sufficient SNR was obtained.
[0048]
The regeneration mechanism of variant 20 is considered as follows. In other words, in the deformation 20 consisting of a cavity or a gas sphere, a part of the noble metal generated by the decomposition of the noble metal oxide at the time of recording is aggregated into noble metal particles, while the noble metal that is not aggregated is hollow in the form of ultrafine particles. Or, it is considered that it is attached to the wall surface of the gas bulb. In this state, when the optical disk 1 is irradiated with the laser beam 2 having a certain level of power or more, the noble metal particles aggregate in the cavities or gas spheres constituting the deformation 20, and the noble metal particles precipitate. It is considered that the noble metal particles serve as a probe that scatters near-field light, converts the near-field light into propagating light, and enables super-resolution reproduction. It should be noted that the noble metal particles once precipitated during the regeneration do not disappear even after the regeneration, and thus it is not necessary to precipitate the noble metal particles again during the second and subsequent regenerations.
[0049]
The present inventors have also confirmed that if the optical disc 1 is continuously reproduced with a reproduction power of 4 mW, it can be repeatedly reproduced about 10,000 times. At the same time, it was also confirmed that if irradiation was continued even at the reproducing power, the deformation 20 formed in the noble metal oxide layer 16 was deteriorated, and the reproducing quality was deteriorated.
[0050]
Furthermore, the present inventors also prototyped the optical disc 1 in which the noble metal oxide layer 16 in the optical recording medium was changed from platinum oxide to silver oxide, and tried recording and reproduction in the same manner as described above. As a result, even when the noble metal oxide layer 16 made of silver oxide is irradiated with the laser beam 2 having a predetermined or higher recording power, the noble metal oxide layer 16 is made similar to the noble metal oxide layer 16 made of platinum oxide. A deformation 20 consisting of a cavity or a gas sphere was formed, and it was confirmed that a high CNR was obtained in the reproduced signal.
[0051]
However, in the optical disc 1 in which the noble metal oxide layer 16 is formed of silver oxide, the speed of deterioration of the reproduction signal, that is, the reproduction in the deformation 20, It was confirmed that, with the laser beam 2 applied to the laser beam, the speed at which the information recorded in the deformation 20 deteriorated was high. From this, it was confirmed by experiments that high SNR and high reproduction durability can be obtained by using platinum oxide for the noble metal oxide layer 16 in the optical recording medium.
[0052]
In addition, the present inventors, Jpn. J. Appl. Phys. , Vol. 39, no. 2B, pp. 980-981 (2000) discloses that recording / reproducing is performed on an optical recording medium using a noble metal oxide layer composed of silver oxide. In the noble metal oxide layer 16, the above-mentioned deformation 20 made of a cavity or a gas sphere is not formed. When this was read out at the same reproducing power as described above, a CNR of 30 to 40 dB was obtained, but the signal deteriorated within a few minutes, and the durability that could withstand practical use could not be obtained.
[0053]
Then, this time, the present inventors formed a recording mark composed of the deformation 20 on the noble metal oxide layer 16 on the optical recording medium having such a noble metal oxide layer 16, and recorded and reproduced the recording mark. In addition, as a result of examining a specific configuration as an optical recording medium device that can also perform erasure, more stable reproduction can be performed, and information can be easily and reliably erased, and reproduction durability can be improved. Each configuration that can be further improved has been found.
[0054]
Hereinafter, an optical recording / reproducing apparatus as an optical recording medium device according to the present invention, which performs recording / reproducing / erasing of information on such an optical disc 1, will be described.
[0055]
FIG. 1 is a block diagram showing a main part of an optical recording / reproducing apparatus for recording / reproducing / erasing information on / from the optical disc 1.
[0056]
As shown in FIG. 1, an optical pickup 3, an amplifier 4, a reproducing circuit 5, a tracking circuit 6, a monitoring circuit 7, a control circuit 8, a laser driver 9, a recording circuit 10, and the like are provided.
[0057]
When recording information, the recording information is output from the recording circuit 10 and sent to the laser driver 9. The laser driver 9 sends a drive current according to the recorded information to a semiconductor laser (not shown) in the optical pickup 3. At this time, the laser driver 9 is controlled by a control circuit 8 to be described later, and has a drive current such that the laser beam 2 has a recording power. A laser beam 2 emitted from a semiconductor laser is intensity-modulated by recording information, and focused on an optical disk 1 to perform recording.
[0058]
The optical recording medium including the noble metal oxide layer 16 is formed on the optical disk 1 as described above. By irradiating the noble metal oxide layer 16 with the laser beam 2 of the recording power, a deformation 20 consisting of a cavity or a gas sphere as a recording mark is formed in the noble metal oxide layer 16. This modification 20 has a recording size smaller than the resolution limit represented by λ / 4NA, where λ is the wavelength of the semiconductor laser provided in the optical pickup 3 and NA is the numerical aperture of the objective lens (not shown).
[0059]
On the other hand, at the time of reproducing the recorded information, the laser driver 9 is controlled by the control circuit 8 described later, and supplies a constant drive current weaker than at the time of recording to the optical pickup 3 so that the laser beam 2 has the reproducing power. To a semiconductor laser. The semiconductor laser in the optical pickup 3 irradiates the optical disk 1 with a laser beam 2 having a reproduction power corresponding to the drive current, and the reflected light is converted into an electric signal by a detector (not shown) in the optical pickup 3. After that, the signal is amplified by the amplifier 4.
[0060]
The amplified signal is output to the tracking circuit 6 and the reproduction circuit 5, and the tracking circuit 6 generates a tracking error signal based on the amplified signal, and follows the laser beam 2 to a desired track based on the signal. Let it. The reproducing circuit 5 reproduces the recorded information based on the amplified signal. By irradiating the laser beam 2 with the reproducing power, the deformation 20 smaller than the resolution limit is reproduced from the reflected light or transmitted light.
[0061]
The control circuit 8 is a control center of the recording / reproducing apparatus, and outputs a control signal to the laser driver 9 to drive a drive current for driving the semiconductor laser output to the optical pickup 3 as described above. It is to adjust. The control circuit 8 controls the driving of the laser driver 9 so that the laser power emitted from the semiconductor laser becomes the recording power according to the recording operation during recording and the reproduction power according to the reproduction operation during reproduction. Control.
[0062]
In the optical recording / reproducing apparatus according to the present embodiment, as one of the remarkable components, the control circuit 8 further controls the driving of the laser driver 9 so that the third power is weaker than the reproducing power at the time of reproducing. The optical disk 1 can be irradiated with a laser beam 2 having a power of?
[0063]
As described above, the information recorded on the noble metal oxide layer 16 by the deformation 20 gradually deteriorates with continued irradiation, even if the power is weaker than the recording power. Will be done.
[0064]
Therefore, in the present recording / reproducing apparatus, in order to prevent such information deterioration, the control circuit 8 uses the semiconductor laser during standby and access for accessing a desired track. The driving of the laser driver 9 is controlled so that the laser beam 2 is irradiated with the weakest third power. This makes it possible to further improve the reproduction durability of the optical disc 1 as compared with a configuration in which the laser beam 2 of the reproduction power is always irradiated.
[0065]
The condition required as the third power is that the irradiation with the laser beam 2 of the power enables tracking to a track including the deformation 20 during standby or access. Therefore, by sufficiently weakening the third power within a range where tracking is possible, the reproduction durability can be further improved. Hereinafter, this third power is referred to as standby / access power.
[0066]
Further, in the optical recording / reproducing apparatus of the present embodiment, as another notable configuration, a monitoring circuit 7 for monitoring a change in the tracking error signal generated by the tracking circuit 6 is provided. The control circuit 8 controls the driving of the laser driver 9 based on the change of the tracking error signal due to the above, and performs the power control of the recording power so that the power becomes more appropriate.
[0067]
This is because, as will be described later, if the power of the laser beam 2 is too large during recording, the deformation 20 is excessively formed in the noble metal oxide layer 16 to prevent unstable tracking during reproduction. is there. By controlling the recording power to an appropriate value, tracking during reproduction is stabilized, and stable reproduction is possible.
[0068]
Further, in the optical recording / reproducing apparatus of this embodiment, as another notable configuration, the control circuit 8 controls the driving of the laser driver 9 to securely erase only information of a predetermined sector or block. It is configured to obtain. Further, the optical recording / reproducing apparatus according to the present embodiment has a configuration capable of performing a complete erasing operation that makes it impossible to access a track from which information has been erased at all.
[0069]
The power switching operation of the semiconductor laser of the optical recording / reproducing apparatus having the above configuration will be described with reference to the flowchart of FIG.
[0070]
When the operation of the apparatus starts, it is first determined whether or not the optical disk 1 has the noble metal oxide layer 16 based on the lead-in information of the optical disk (S1). The control circuit 8 also performs such determination. Here, if the optical disk 1 does not include the noble metal oxide layer 16, normal recording and reproduction are performed (S2).
[0071]
On the other hand, in the case of the optical disk 1 having the noble metal oxide layer 16, the operation mode is selected from among recording, reproducing, erasing, and standby / access (S3).
[0072]
Here, in the case of the recording mode, the laser power is set to, for example, 8 mW recording power (high laser power) (S4), and information is recorded by forming a deformation 20 in the noble metal oxide layer 16 (S5). When the recording is completed, the process returns to the step of selecting an operation mode from any of recording, reproduction, erasing, and standby / access (S3).
[0073]
In the reproduction mode, the laser power is set to, for example, 4 mW (during the laser power) (S6), and the information recorded on the noble metal oxide layer 16 by the deformation 20 is reproduced (S7). When the reproduction is completed, the process returns to the step of selecting an operation mode from among recording, reproducing, erasing, and standby / access again (S3).
[0074]
In the standby / access mode, the laser power is set to, for example, 1 mW standby / access power (lower laser power) (S8), and the track including the information recorded by the modification 20 is tracked (S9). Thereby, it is possible to prevent the deformation 20 from deteriorating during standby / access. At this time, since the laser power is weak, a mark shorter than the resolution limit cannot be reproduced. However, the amount of reflected light required for tracking is obtained, so that there is no problem in tracking. When the standby / access ends, the process returns to the step of selecting an operation mode from recording, reproduction, erasing, and standby / access again (S3).
[0075]
Further, in the case of the erasing mode, the laser power is set to the same power as the recording power (higher laser power) (S10), and the semiconductor laser is DC-driven with the power, whereby the noble metal oxide layer 16 is deformed and deformed. The information is erased by continuously forming a cavity or a gas sphere so as to be connected to 20 (S12). When the erasing is completed, the process returns to the step of selecting an operation mode from any of recording, reproduction, erasing, and standby / access (S3).
[0076]
Although not described in the flowchart of FIG. 3, if the erase mode is a complete erase operation mode for erasing information so that access to the erase track is completely impossible, the fourth laser power even stronger than the recording power Is driven by DC to completely fill the groove 21 in the noble metal oxide layer 16 in which the deformation 20 is formed with a cavity or a gas sphere and disable tracking.
[0077]
Next, based on the flowchart of FIG. 4, laser power control for controlling the recording power set in the erasing operation mode and the recording operation mode in the optical recording / reproducing apparatus so as to be the optimum power according to each operation mode. Will be described.
[0078]
First, the control circuit 8 selects a recording operation mode or an erasing operation mode (S21). If it is a recording operation, first, information is recorded as a modification 20 with a predetermined recording power (S22).
[0079]
However, as shown in FIG. 2, in the optical disc 1, the average groove depth is reduced due to the formation of the cavity 20 or the gas sphere in the noble metal oxide layer 16, so that the tracking error signal is deteriorated. I do.
[0080]
Therefore, subsequently, the degree of deterioration of the tracking error signal is detected by the monitoring circuit 7 based on the amplitude or peak value at the time of the track jump, as described later (S23).
[0081]
The control circuit 8 determines whether or not the deterioration detected by the monitoring circuit 7 is within a predetermined range (S24). If the deterioration is within the predetermined range, recording is continued with the recording power unchanged (S25).
[0082]
On the other hand, otherwise, the tracking becomes unstable during reproduction. Therefore, the recording power is slightly weakened by a predetermined amount (S26), the information recorded in S22 is re-recorded again (S27), and the tracking error is returned again. Returning to the signal deterioration detection (S23), it is determined whether the signal is within a predetermined range (S24). This loop is repeated until the value falls within a predetermined range.
[0083]
Thereby, the recording power is appropriately controlled, and the information recorded with this recording power can be reproduced by normal tracking.
[0084]
Next, if an erasing operation is performed in S21, DC driving is performed with the recording power to erase information (S28). That is, the deformation 20 is formed so as to be overwritten on the deformation 20, and the information is erased by connecting the deformations 20, that is, the cavities or the gas spheres.
[0085]
In this case as well, the formation of the deformation 20 reduces the groove depth, so that the tracking error signal deteriorates. In addition to the deformation 20, the deformation 20 is further formed, and the deformations 20, that is, the cavities or the gas spheres are connected to form a continuous sequence. Therefore, the degree of deterioration of the tracking error signal is larger than that during recording.
[0086]
Therefore, subsequently, the degree of deterioration of the tracking error signal is detected by the monitoring circuit 7 based on the amplitude or peak value at the time of the track jump as described later (S29).
[0087]
The control circuit 8 determines whether or not the deterioration detected by the monitoring circuit 7 is outside the predetermined range (S30). If not, the control circuit 8 continues erasing the information while keeping the recording power (S31). That is, if it is outside the predetermined range, the erasure is completed because the information is significantly deteriorated.
[0088]
On the other hand, if not, the information can be reproduced because the deterioration of the information is small. Therefore, the erasing laser power is slightly increased by a predetermined amount (S32), and the information is erased again (S33). Then, returning to the detection of the deterioration of the tracking error signal again (S29), it is determined whether or not the tracking error signal is out of the predetermined range (S30). This loop is repeated until the value falls outside the predetermined range.
[0089]
As a result, information is erased. At this stage, it is possible to perform tracking although it is unstable. When erasing some sectors (or blocks) of the track and continuously reproducing the immediately preceding and succeeding sectors, at least only the tracking is performed even for the erased sectors. Recording and playback can be performed smoothly and continuously.
[0090]
As described above, in the complete erasing operation, the groove 21 may be filled with a cavity or a gas ball so that the laser power is further increased so that the tracking itself becomes impossible. As a result, since tracking becomes completely impossible, access to the erased track becomes difficult at all, and reliable information erasure becomes possible. In particular, when erasing the entire surface of the optical disc 1, it is very effective to make all tracks untrackable, which is a practical method when erasing confidential information or the like.
[0091]
FIG. 5 is a diagram for explaining the determination operation of the control circuit 8 based on the detection of deterioration of the tracking error signal during recording in the flowchart of FIG.
[0092]
FIG. 7A shows a tracking error signal in a normal state. When there is no deterioration due to recording, the amplitude V1 of the tracking error signal is obtained at the time of the track jump (the position of Tj in the drawing). FIG. 2B shows a case where the tracking error signal is deteriorated by the recording. The amplitude is reduced to V2 as compared with the case where there is no deterioration (broken line). Therefore, the control circuit 8 determines whether or not tracking is normal based on whether V2 / V1 (or V2-V1) is within a predetermined range.
[0093]
In addition, the peak value on the minus side may decrease greatly as shown in FIG. At this time, the control circuit 8 determines whether or not tracking is normal based on whether V4 / V3 (or V4-V3) is within a predetermined range.
[0094]
FIG. 2D is a diagram for explaining the relationship between the recording power, the amplitude of the tracking error signal, and the CNR. From this, it can be seen that as the recording power is gradually increased, the tracking error signal is gradually deteriorated and its amplitude is reduced. Also, it can be seen that CNR gradually increases. When the recording power reaches P0, the CNR becomes maximum, and the tracking error signal is in a normal range. When the power is further increased and the recording power exceeds P1, the tracking error signal is significantly deteriorated, and the tracking becomes unstable.
[0095]
Therefore, in the optical recording / reproducing apparatus of the present embodiment, the recording power is controlled to be lower than the laser power P1 at which tracking is normal. Preferably, control is performed so that the CNR is between the laser power P0 at which the CNR becomes maximum and the laser power P1.
[0096]
FIG. 6 is a diagram for explaining the relationship between the laser power at the time of erasing, the amplitude of the tracking error signal, and the CNR. From this, it is understood that when the recording power at the time of erasing is gradually increased, the CNR is deteriorated and the tracking error signal is gradually deteriorated. When the laser power exceeds P2, the deformations 20 formed of cavities or gas spheres start to connect with each other, deteriorating the recorded information, and significantly deteriorating the tracking error signal. That is, if the laser power exceeds P2, the CNR of the reproduction signal deteriorates due to the deterioration of the recorded information or the unstable tracking, and the reproduction becomes difficult.
[0097]
Therefore, in the optical recording / reproducing apparatus of the present embodiment, the laser power is controlled to be stronger than P2 during erasing so that the amplitude of the tracking error signal is out of the normal range.
[0098]
Specifically, in the optical recording / reproducing apparatus of the present embodiment, in the normal erasing operation, it is possible to perform unstable tracking from the laser power at the time of erasing to the power P3 at which tracking is impossible at all. The power has been adjusted. This makes it possible to smoothly record or reproduce information in sectors or blocks adjacent before and after the erased portion.
[0099]
In the complete erasing operation mode selected when erasing the entire surface of the disk or when completely erasing information is desired, the laser power is increased to P3 or more. As a result, the tracking at the time of reproduction cannot be performed at all, and the information can be completely and reliably erased.
[0100]
In erasing the information recorded in the noble metal oxide layer 16 by the modification 20, the semiconductor laser is driven by a direct current here. However, the present invention is not limited to the direct current and is completely different. May be overwritten with the recording power by the recording means. In this case, the deformations 20 cannot be completely connected to each other, but the original information cannot be reproduced alone, so that the information can be erased.
[0101]
In the above embodiment, the timing for controlling the recording power and the erasing power is not described, but the recording power and the reproducing power are controlled by the thickness and material of the noble metal oxide layer on the optical disc 1 and the light absorbing layer. The test information may be changed depending on various conditions such as the material and thickness of the optical disc 1. By recording or erasing test information in the test area when the optical disc 1 is mounted on the optical recording / reproducing apparatus, the optical disc 1 can be changed. The power of each operation mode may be determined in advance.
[0102]
【The invention's effect】
As described above, the optical recording medium device of the present invention has a noble metal oxide layer, and an optical recording medium on which information is recorded by deformation of the noble metal oxide layer caused by irradiation of the noble metal oxide layer with light. Recording means for irradiating the optical recording medium with light having an intensity at which a noble metal oxide layer is deformed to record information as the deformation, wherein the recording means has an irradiation light intensity at the time of recording. Is controlled based on the tracking performance of the information recording portion.
[0103]
According to this, the noble metal oxide layer has a noble metal oxide layer, and when the noble metal oxide layer is irradiated with light, the noble metal oxide layer is deformed. Since the means is configured to record information by irradiating light with an intensity that causes deformation of the noble metal oxide layer, at least the shortest deformation has a dimension smaller than the resolution limit, and In spite of super-resolution reproduction, high CNR is obtained and practically sufficient SNR is obtained, and high reproduction durability is obtained.
[0104]
In addition, in such a recording method, if the irradiation light intensity is too strong, the tracking performance is reduced. However, in the above configuration, the recording means sets the irradiation light intensity at the time of recording to an information recording portion, that is, a portion having deformation. Since the control is performed based on the tracking performance described above, there is an effect that the reproduction does not become unstable and stable reproduction becomes possible.
[0105]
Further, in this case, it is preferable that the recording unit controls the irradiation light intensity so that the degree of deterioration of the tracking error signal in the information recording portion falls within an area where stable tracking is possible.
[0106]
Since the tracking performance can be detected from the degree of deterioration of the tracking error signal, by controlling the irradiation light intensity of the recording means so that the degree of deterioration of the tracking error signal falls within a region enabling stable tracking. In addition, information can be recorded with an appropriate irradiation light intensity that enables stable tracking during reproduction.
[0107]
As described above, the optical recording medium device of the present invention has a noble metal oxide layer, and an optical recording medium on which information is recorded by deformation of the noble metal oxide layer caused by irradiation of the noble metal oxide layer with light. And an erasing means for erasing the information recorded as the deformation by irradiating the optical recording medium with light having an intensity that causes deformation of the noble metal oxide layer. Is controlled based on the tracking performance of the information erased portion.
[0108]
As described above, the recording of information due to the deformation of the noble metal oxide layer is a super-resolution reproduction in which at least the shortest deformation has a size smaller than the resolution limit and is reproduced. Nevertheless, a high CNR can be obtained, a practically sufficient SNR can be obtained, and a high reproduction durability can be obtained.
[0109]
According to the above configuration, the information recorded by the deformation of the noble metal oxide layer is provided with an erasing unit for erasing the noble metal oxide layer by irradiating light having an intensity at which the noble metal oxide layer is deformed, The erasing means is configured to control the irradiation light intensity at the time of erasing based on the tracking performance of the information erasing portion.
[0110]
As a result, it is possible to measure the deterioration of information at the time of information erasure by tracking performance, and by controlling the amount of irradiation light based on the tracking performance of the information erasure part, the information is degraded and securely erased. Can be. Further, there is an effect that the tracking performance of the information erasure part can be adjusted to a desired state.
[0111]
Further, the erasing means controls the irradiation light intensity such that the degree of deterioration of the tracking performance in the information erasure portion is in an area where unstable tracking is possible. Even if it is not possible, by enabling tracking of an unstable degree, information can be smoothly recorded or reproduced in sectors or blocks adjacent before and after the erased portion.
[0112]
In addition, the erasing means controls the irradiation light intensity so that the degree of deterioration of the tracking performance in the information erasure portion is in an untrackable area, so that the information recorded by the deformation cannot be reproduced again. This is particularly effective for erasing confidential information and the like.
[0113]
Further, the optical recording medium device of the present invention is, as described above, an optical recording medium device that at least reproduces recorded information by irradiating the optical recording medium with light, wherein the optical recording medium is Information is recorded by deformation of the noble metal oxide layer caused by irradiating the noble metal oxide layer with light, and the deformation is irradiated with light weaker than at the time of recording. And a tracking means for irradiating the optical recording medium with light to perform tracking to a predetermined track on which information is recorded by deformation of the noble metal oxide layer; Is characterized in that the intensity of irradiation light is made weaker at the time of standby and at the time of access to move to a predetermined track than at the time of information reproduction.
[0114]
As described above, the recording of information due to the deformation of the noble metal oxide layer is a super-resolution reproduction in which at least the shortest deformation has a size smaller than the resolution limit and is reproduced. Nevertheless, a high CNR can be obtained, a practically sufficient SNR can be obtained, and a high reproduction durability can be obtained.
[0115]
In addition, even if the recording of information due to the deformation of the noble metal oxide layer is performed at an irradiation intensity for reproduction lower than the irradiation light intensity for recording, the information recorded gradually becomes deformed as the irradiation is continued. According to the above configuration, tracking means for irradiating the optical recording medium with light and performing tracking to a predetermined track on which information is recorded by deformation of the noble metal oxide layer. However, at the time of standby and access other than recording and reproduction, the intensity of irradiation light is made weaker than at the time of information reproduction. Therefore, compared to a configuration in which tracking is always performed by irradiating the irradiation light intensity during reproduction, there is an effect that the reproduction durability of the optical recording medium can be further improved.
[Brief description of the drawings]
FIG. 1 illustrates one embodiment of the present invention, and is a block diagram illustrating a configuration of a main part of an optical recording / reproducing apparatus.
FIG. 2 is an explanatory diagram showing a sectional structure of an optical disk used in the recording / reproducing apparatus.
FIG. 3 is a flowchart showing an operation of switching the laser power according to an operation mode in the recording / reproducing apparatus.
FIG. 4 is a flowchart showing an operation of laser power control during recording and erasing in the recording / reproducing apparatus.
5 (a) to 5 (d) are diagrams illustrating detection of deterioration of a tracking error signal during recording in the flowchart of FIG.
6 is a diagram illustrating a relationship between a laser power at the time of erasing, an amplitude of a tracking error signal, and a CNR, for explaining detection of deterioration of a tracking error signal at the time of erasing in the flowchart of FIG. 4;
[Explanation of symbols]
1 optical disk
2 Laser beam
3 Optical pickup
4 Amplifier
5 Regeneration circuit
6. Tracking circuit (tracking means)
7. Monitoring circuit (recording means, erasing means, tracking means)
8. Control circuit (recording means, erasing means, tracking means)
9 Laser driver (recording means, erasing means, tracking means)
10 Recording circuit

Claims (6)

It has a noble metal oxide layer, it is possible to mount an optical recording medium on which information is recorded by deformation of the noble metal oxide layer caused by irradiating the noble metal oxide layer,
The optical recording medium, recording means for recording information as the deformation by irradiating light of an intensity that causes deformation of the noble metal oxide layer,
An optical recording medium device, wherein the recording means controls the intensity of irradiation light during recording based on tracking performance of an information recording portion. 2. The optical recording medium device according to claim 1, wherein the recording unit controls the irradiation light intensity so that the degree of deterioration of the tracking performance in the information recording portion falls within an area where stable tracking is possible. It has a noble metal oxide layer, it is possible to mount an optical recording medium on which information is recorded by deformation of the noble metal oxide layer caused by irradiating the noble metal oxide layer,
The optical recording medium has erasing means for erasing light recorded as the deformation by irradiating light having an intensity at which the noble metal oxide layer is deformed,
The optical recording medium device, wherein the erasing means controls the irradiation light intensity at the time of erasing based on the tracking performance of an information erasing portion. 4. The optical recording medium device according to claim 3, wherein the erasing means controls the irradiation light intensity such that the degree of deterioration of the tracking performance at the information erasing portion falls within a region enabling unstable tracking. . 4. The optical recording medium device according to claim 3, wherein the erasing means controls the irradiation light intensity so that the degree of deterioration of the tracking performance at the information erasing portion falls within a region where tracking is impossible. By irradiating the optical recording medium with light, an optical recording medium device that performs at least reproduction of recorded information,
The optical recording medium has a noble metal oxide layer, and information is recorded by deformation of the noble metal oxide layer caused by irradiating the noble metal oxide layer with light. The information is reproduced by being irradiated,
The optical recording medium, tracking means for irradiating light to perform tracking to a predetermined track where information is recorded by deformation of the noble metal oxide layer,
The optical recording medium device, wherein the tracking means weakens the intensity of irradiation light at the time of standby, at the time of access to move to a predetermined track, and at the time of information reproduction.

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