JP2828772B2 - Optical recording method - Google Patents

Description

The present invention relates to an optical recording method for performing multiplex recording of information on a medium using a photochromic material as a recording layer material.

(B) Conventional technology An example of an optical recording method for performing multiplex recording of information on a medium using a photochromic material as a recording layer material is disclosed in, for example,
No. 203450 / G03C1 / 733. A medium used in such a recording method is provided with a plurality of recording layers, and each layer contains a photochromic material having a different absorption wavelength. When recording information on such a medium, by irradiating a beam having a wavelength corresponding to the absorption wavelength of the photochromic material of each layer, a photochromic reaction occurs only in the corresponding layer, and recording is performed for each layer. . As a result, information of a type corresponding to the number of recording layers can be multiplex-recorded even with a single medium.

However, according to such a recording method, several types of light sources having different wavelengths must be prepared for the number of recording layers. Also, photochromic materials,
It is necessary to prepare only the types corresponding to the number of recording layers.
In such a case, the configuration of the recording apparatus becomes large and complicated, and the configuration of the recording medium also becomes complicated.

On the other hand, a method of multiplex-recording several types of information on a single recording layer using a single-wavelength beam is disclosed in Japanese Patent Laid-Open No. 2-1442.
No. 7 (G11B7 / 00). According to such a recording method, the size of a recording mark on a recording layer is changed stepwise by thermal diffusion by changing the intensity of a recording beam in a stepwise manner, so that several types of information are multiplex-recorded on a single layer. However, according to this method, the size of the smallest recording mark at most corresponds to the size of the recording beam spot, and the other marks are considerably larger than the recording beam spot. Therefore, the recording density of the recording marks on the medium cannot be increased. Further, since the mark is formed by thermal diffusion, the shape of the mark cannot be made uniform, thereby increasing the noise level during reproduction. Furthermore, when controlling the size of the mark by thermal diffusion, if the surrounding environment such as the temperature of the medium itself changes, the degree of thermal diffusion changes even with the same beam intensity. You lose control.
Thus, in the case of such a conventional method, the problem of the above-mentioned conventional example can be solved for the time being, but on the other hand, there are various problems.

(C) Problems to be Solved by the Invention According to the present invention, multiplex recording can be performed on a single recording layer by a beam of a single wavelength, and in this case, the size of a recording mark substantially matches the size of a recording beam spot. It is an object of the present invention to provide an optical recording method that can perform recording mark control well.

(D) Means for Solving the Problems In view of the above problems, the present invention is an optical recording method for performing optical recording on a medium using a photochromic material as a recording layer material, and irradiating a recording beam to the medium. By recording a first signal based on the length of a recording mark formed by the above or a space between the recording marks, and changing the intensity of the recording beam to change the peak value of the first signal, The second signal is recorded by changing the optical characteristics of the recording mark.

(E) Function The photochromic material has a property that, when irradiated with light having an absorption wavelength, the optical characteristics change in response to the light. Here, the amount of change in the optical characteristics (in this case, the change in reflectance) and the intensity of the irradiation light have a certain correspondence relationship as shown in FIG. Therefore, when such a photochromic material is used as a recording layer material, by changing the intensity of the recording beam stepwise or continuously, the optical characteristics of the recording portion can be accurately changed stepwise or continuously. . Since the photochromic material responds to light, recording marks (changes in optical characteristics) formed in the recording layer occur only in the portions irradiated with the light. Therefore, the size of the recording mark substantially matches the size of the recording beam spot. Also, the shape becomes uniform in accordance with the shape of the recording spot.

(F) Example FIG. 2 shows an example of a photochromic material used as a recording layer material. Such a material undergoes a photochromic reaction when irradiated with ultraviolet light, and changes in absorbance characteristics. FIG. 3 shows absorbance characteristics before and after irradiation with ultraviolet light.

A medium was formed using such a photochromic material as a recording layer material, and a multiplex recording experiment was performed by the recording method according to the present invention. The recording medium is formed by forming an A1 reflection film on a glass substrate by vacuum evaporation, and forming a recording layer containing the photochromic material thereon. The recording layer is formed by dissolving the photochromic material and polyvinyl butyral in methyl ethyl ketone (MEK), and applying this by spin coating. The mixing ratio of the photochromic material and polyvinyl butyral is
10% by weight of photochromic material vs. polyvinyl butyral
90% by weight. The thickness of the formed recording layer is 1 μm.

FIG. 4 shows the configuration of the apparatus used in the experiment. In FIG. 1, reference numeral 1 denotes a recording light source that emits a recording ultraviolet laser beam (wavelength: 360 nm), which is composed of an Ar laser. The recording laser beam is turned on / off by an AO (Acoustic-Optical) element 2.
After the F control, the beam is expanded by the beam expander 3. And, ND (Nutral-De
After the power is adjusted by the filter 4, the light is reflected by the dichroic mirror 5 and converged on the medium 7 by the objective lens 6.

As the reproducing light source 8, a HeNe laser which emits a beam having a wavelength of 633 nm, which is well absorbed only by the photochromic material after irradiation with ultraviolet light, is selected from the absorption wavelength characteristics shown in FIG. The laser beam for reproduction is linearly polarized light, passes through the AO element 9 and the beam expander 10 in the same manner as described above, and is almost totally reflected by the polarization beam splitter 11. Then, after being converted into circularly polarized light by the 波長 wavelength plate 12, it is transmitted through the dichroic mirror 5,
Converges on the medium 7. The reflected light from the medium 7 travels in the same optical path as described above,
Reach 11 In such a case, however, since the light is converted into linearly polarized light whose polarization plane is orthogonal to that at the time of incidence by the quarter-wave plate 12, almost all light is transmitted through the polarization beam splitter 11. Thereafter, the reflected light is converted into a PI by the objective lens 13.
The light is converged on the N photodiode 14. The PIN photodiode 14 outputs a voltage corresponding to the intensity of the reflected light. The storage oscilloscope 15 sequentially stores this voltage.

In the experiment, the recording laser light was first applied to the AO element 2 by 5 μm.
The recording is performed on the medium 7 by irradiating the medium 7 for sec. afterwards,
The recording portion is irradiated with a reproduction laser beam for 1 Msec, and the reflectance of the recording portion is determined from the intensity of the reflected light. In this experiment, the power of the recording laser beam on the medium was 1 mW, 2.5 mW, 4.5 mW
Is performed when Here, the switching of the power of the recording laser light is performed by appropriately replacing the ND filter 4. The intensity of the reproducing laser beam is set to a weak level (about 0.5 mW) so that the photochromic material in the recording portion does not react in the reverse direction.

The following results according to the level of the recording laser beam were obtained. For comparison, the measurement results of the reflectance at the time of non-recording are also shown.

From these measurement results, it was confirmed that the reflectance of the medium changed according to the power of the recording laser beam. In addition, this measurement result well corresponds to the relationship shown in FIG. Therefore, it is recognized that the reflectance of the medium can be similarly changed not only for the recording laser power at the time of the experiment but also for other laser powers.

When the recorded portion of the medium on which recording was performed was observed with a microscope, a recorded mark as shown in FIG. 5 could be observed. In the figure, R ₀ indicates an unrecorded state, and R ₁ , R ₂ , R ₃
Indicates recording marks according to Examples 1, 2 and 3, respectively.
The shape of the recording mark in each experiment was almost uniform and had a clear contour, and almost coincided with the size of the convergent spot of the recording laser beam. The coloring density of each recording mark was in accordance with the recording power.

As described above, when the power of the recording laser beam is changed in three stages, the information of each channel can be represented by a binary value, so that information of two channels can be recorded on a single recording layer. An example is shown in the following table. Note that R ₀ , R ₁ , R ₂ , and R ₃ indicate recording marks in FIG. 5, respectively.

Such a multiplex recording method can be used for recording digital signals or FM signals.

Further, according to the present invention, information can be analog-multiplexed by continuously changing the optical characteristics of the recording mark. FIG. 6 shows an example of multiplex recording. Depending on recording mark length and space between recording marks
The FM-modulated first analog information signal is recorded. Also, by changing the density of each recording mark, the first
The peak value of the FM signal is changed to obtain a second analog information signal AM-modulated by the envelope detection signal of the first FM signal. Thus, according to such a recording method, two analog information signals can be multiplex-recorded. Such a recording method can be applied to, for example, multiplex recording of a luminance signal component and a carrier chrominance signal component (having different frequencies) in a video image signal. Further, the envelope detection signal may be a digital signal.

Although all of the above recording methods are for a single photochromic material, a plurality of types of photochromic materials (such as a case where the recording layer is another layer or a case where several types of photochromic materials are mixed in a single recording layer) are used. When used, the multiplicity of information can be further improved.
In addition, although the coloring density is used as a change factor of the optical property of the photochromic material, a change in other optical properties, for example, a change in optical rotation or a change in birefringence may be used.

Next, an example of a recording apparatus according to the recording method of the present invention will be described below.

FIG. 7 is a diagram showing a first recording device. This recording apparatus multiplex-records information on a disk D which is a recording medium, and spirally records the information on the disk by rotating the disk D and moving a light spot little by little in the radial direction of the disk. Form a track.

In the figure, reference numeral 21 denotes a recording light source that emits linearly polarized laser light. The laser light is converted into pulse light corresponding to the recording signal by the AO element 22, and then converted to a prism light.
Reflected by 23. An AO element control circuit 24 supplies a control signal to the AO element 22. The polarization direction of the laser light reflected in this manner is controlled by the Faraday rotation element 25. That is, the Faraday rotation element 25 rotates the polarization plane of the laser light according to the control signal from the Faraday element control circuit 26.

Thereafter, the laser is expanded by the beam expander 27 and then enters the polarization beam splitter 28. Here, part of this laser light is polarized beam splitter
Reflected by 28 and subject to transmission restrictions. The transmission amount of the laser light is determined by the state of the polarization plane of the laser light with respect to the polarization beam splitter 28. That is, when the laser light is incident on the polarization beam splitter in a P-wave state, the laser light is transmitted almost completely through the polarization beam splitter, and is incident on the polarization beam splitter in an S-wave state in which the polarization plane is orthogonal to The laser light is almost totally reflected by the polarizing beam splitter.
The laser beam transmitted through the polarizing beam splitter in this manner is converged on the disk by the objective lens 29.

According to this embodiment, the polarization plane of the laser beam with respect to the polarization beam splitter can be changed by appropriately changing the polarization direction of the laser beam by the Faraday rotator 25, and thus the intensity of the laser beam on the disk D can be reduced. Can be changed.

FIG. 8 shows a second recording apparatus. In such a recording device, a Michelson interferometer (Junpei Tsujiuchi, “Introduction to Optics II”, p.
38) is used to change the intensity of the recording laser light. That is, the laser light is separated into transmitted light and reflected light by the beam splitter 31, and the reflected light is sequentially reflected by the mirrors 32 and 33, and then the reflected light and the transmitted light are combined by the beam splitter 31. Let
The reflected light interferes with the transmitted light. At this time, the intensity of the transmitted light after interference changes according to the phase difference between the transmitted light and the reflected light. In this embodiment, such a phase difference is referred to as EO (Electro-O
ptic) is adjusted by the element 34. The EO element 34 has a property that the refractive index changes according to the applied voltage, and can change the phase of the light passing therethrough according to the applied voltage. 35 is an EO element control circuit, which performs EO according to the recorded information.
A voltage is applied to the element 34, thereby changing the intensity of the laser beam on the disk D. As a means for changing the phase difference, instead of using such an EO element,
The mirror 32 or 33 may be slightly moved in the optical axis direction to change the optical path length of the reflected light. in this case,
As means for moving the mirror, for example, a piezoelectric element can be used.

FIG. 9 shows a third recording apparatus. Such a recording device is a Fabry-Perot interferometer (Junpei Tsujiuchi, "Introduction to Optics II")
(See P43-P48) 36 is used to adjust the intensity of the laser beam. In the figure, 37 and 38 are half mirrors, and 39 is an EO element. Half of the laser light transmitted through the half mirror 37 is transmitted through the half mirror 38, and the other half is transmitted through the half mirror 38.
Is reflected by The Fabry-Perot interferometer 36 adjusts the intensity of the transmitted light by causing the reflected light to interfere with the transmitted light. That is, the reflected light is partially reflected by the half mirror 37 and then transmitted through the half mirror 38 to be combined with the transmitted light. The phase difference between the reflected light and the transmitted light is adjusted by the EO element 39 as in the recording apparatus described above. In this recording apparatus, the intensity of the laser beam may be changed by slightly moving the half mirrors 37 and 38 in the optical axis direction.

As described above, according to the present invention, it is possible to perform multiplex recording of two completely different signals on a single recording layer using a single wavelength beam.
Moreover, in this case, the size of the recording mark can be substantially matched with the size of the recording beam spot, and the recording mark can be controlled well.

[Brief description of the drawings]

FIG. 1 is a diagram showing the relationship between the irradiation light intensity and the reflectance of the photochromic material, FIG. 2 is a diagram showing the photochromic material used in the experiment, FIG. 3 is a diagram showing the optical characteristics of the photochromic material, FIG. The figure shows the apparatus used for the experiment, FIG. 5 shows the recording marks, FIG. 6 shows an example of the multiplex recording method, FIG. 7, FIG. 8, and FIG. FIG. 1, 21: recording light source, 4: ND filter, 25: Faraday rotating element, 30: Michelson interferometer, 36: Fabry-Perot interferometer.

Claims (1)

(57) [Claims] 1. An optical recording method for performing optical recording on a medium using a photochromic material as a recording layer material, wherein a length of a recording mark or a distance between recording marks formed by irradiating a recording beam to the medium. The first signal is recorded on the basis of the space, and the intensity of the recording beam is changed to change the peak value of the first signal, thereby changing the optical characteristics of the recording mark and forming the second signal. An optical recording method characterized by recording.