JPH0210488B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field] The present invention relates to a recording and reproducing method, and particularly to a method for recording high-density information on a recording medium and reproducing information recorded from this medium.

[Prior art]

Many methods are used to record information. Among them, in order to reduce read errors when reading recorded information from a recording medium that has been recorded at a high density, or when recording on a recording medium, devises are being devised to ensure that recording is performed at a high density. It is better to In view of this, various so-called tracking methods have been proposed in the past, in which information is recorded or read by irradiating a light beam onto a recording medium, and the light beam is guided to a predetermined position on the recording medium. For example, Japanese Patent Laid-Open No. 49-32603 discloses a tracking method for reading information recorded on a recording medium. This tracking method will be explained using FIG. 11 and FIG. 12.

In FIGS. 11 and 12, the recording medium 32 is provided with recording grooves 34 arranged in a spiral shape. Information signals are recorded in the recording grooves 34 in high and low ranges. The recording groove 34 is irradiated with a light beam 38, such as a laser beam, generated from a light generator 36. This light beam 38 is focused to be approximately equal to the groove width of the recording groove 34, for example, and is irradiated through an optical deflector 42 having a movable mirror 40 and a fixed mirror 44.
This optical deflector 42 responds to an input signal by moving the movable mirror 4
0 is rotated. Light beam 38 from recording groove 34
The reflected light is detected by two detectors 46, 46 such as phototubes.
The light is received by This light reception is carried out symmetrically with the reflected light of the light beam 38 as the direction of the recording groove 34 as shown in FIG.
The recording is performed at positions in a direction perpendicular to the direction of the recording grooves 34, respectively. Therefore, when the light beam 38 is accurately irradiating the recording groove 34, each detector 46, 4
6 receive the same amount of reflected light. Note that this reflected light may also include reflected diffraction light.

The reflected lights are converted into electrical signals by the detectors 46, 46, respectively, and are led out to the respective output terminals 30, 30. These output terminals 30, 30 are connected to an operating circuit 48 composed of a differential amplifier or the like. By means of this activation circuit 48, only the difference signal between the two electrical signals of the detectors 46, 46 is extracted. This difference signal is supplied to the optical deflector 42, and the movable mirror 40 is rotated. Further, both or one of the output terminals 30, 30 of the detectors 46, 46 are connected to a demodulator (not shown) or the like, and the output signals are processed and reproduced.

With this configuration, the recording medium 32 is rotated in the direction of arrow A, the irradiation point of the light beam 38 moves, and the recording groove 34 is scanned. When the light beam 38 is accurately irradiating the recording groove 34, each detector 4
The amounts of reflected light received at 6 and 46 are equal, and the actuating circuit 48 produces no output. Therefore, the movable mirror 40 of the optical deflector 42 is held in that position.
However, when the light beam 38 slightly deviates from the recording groove 34, the amounts of reflected light received by the detectors 46, 46 differ, and as a result, the magnitudes of the converted electrical signals also differ. A signal representing the difference between these signals is derived in actuation circuit 48 and applied to optical deflector 42. In the optical deflector 42, the movable mirror 40 is rotated according to this difference signal, and the optical beam 38 is
The recording groove 34 is accurately irradiated by changing the irradiation direction.

In this way, the information recorded in the recording groove can be read while tracking the light beam. In addition, a tracking method similar to the above when reading information from a recording medium is disclosed in the US Patent No.
It is disclosed in No. 3452163. The method described in this US patent also focuses a light beam from a light source onto a recording groove provided on a medium, and directs the reflected light from the recording groove in a direction perpendicular to the direction of the recording groove. A device that receives light with a plurality of photodetectors arranged at different positions relative to the recording groove, detects a tracking signal by comparing the outputs of each of these photodetectors, and controls the position of the light beam with respect to the recording groove. It is.

On the other hand, a tracking method for recording information on a recording medium is disclosed in Japanese Patent Application Laid-open No. 113601/1983. Here, a guide track is provided in advance on the recording medium, a tracking signal is detected using a beam separate from the writing beam, and information is recorded using the writing beam while tracking. This example will be explained below using FIG. 13.

In FIG. 13, reference numeral 51 denotes a disc-shaped recording medium (hereinafter referred to as a disk), on the recording surface of which guide tracks are formed in advance. A beam 70 emitted from a light source 55, such as a laser source, is transmitted to a modulator 56.
The beam is modulated in accordance with the information input to terminals 57 and 57', reflected by a semi-transparent mirror 59, and split into three beams a, b, and c by a diffraction grating 61. Here, a is a writing beam, and b and c are sub-beams for detecting a tracking signal. These beams pass through a semi-transparent mirror 63 and are reflected by a tracking mirror 64 toward the disk 51, with the writing beam a forming a light spot at the center of the guide track, and the sub-beams b and c forming a light spot at the edge of the guide track, respectively. It is irradiated like this.

Beams a, b, reflected by the disk 51
The light beam c is reflected by the tracking mirror 64 and the semi-transparent mirror 63, and is received by the detectors 67, 69, and 68, respectively. Here, if the light spot of beam a deviates from the center of the guide track, the balance of reflected light of beams b and c will be lost, and a tracking signal can be obtained by comparing the outputs of detectors 68 and 69.
Therefore, by rotating the tracking mirror 64 in response to this tracking signal, information can be recorded in the guide track while causing the writing beam a to accurately follow the guide track. In the figure, 60 is the reading beam 7.
During recording, this beam 71 is blocked by closing the hole in the perforated flat plate 66. Further, the detector 67 is used to read information recorded on the disk 51 from the reflected light of the beam 71 during reproduction. During reproduction, the light source 60 is used to irradiate the reading beam a to the center of the information track recorded as described above, and the sub-beams b and c to form light spots at the edges of the information track.

However, in the conventional tracking method as explained in Fig. 13, since information recording and tracking signal detection are performed using separate beams, the mutual positions of the light spots of these beams must be precisely set. Therefore, it was very difficult to assemble and adjust the device. Another problem was that a high-output light source was required to split the beam into multiple parts.

[Summary of the invention]

The present invention further improves the prior art as described above, and provides a recording and reproducing method that is most effective in that it performs tracking and performs recording and reproducing with high density without recording errors or read errors. The purpose is to provide.

The above object of the present invention is to create a state in which the guide grooves are not buried on the substrate in which the guide grooves are formed.
Using a recording medium on which a recording layer made of a material that can be reproduced immediately after recording with a light beam is formed, the guide groove is irradiated with a focused recording laser beam having a spot and a base expanding from the spot, At the same time as this spot records information on the recording layer, the positional deviation between the beam and the guide groove is detected by detecting a change in the amount of reflected light that occurs when the base of the beam is reflected at the bank of the guide groove. By detecting and feeding back the information, tracking of the spot with respect to the guide groove is performed, and at the same time, the information recorded as described above is reproduced by irradiating the guide groove with a reading light beam. This is achieved by a recording and reproducing method that tracks the readout light beam with respect to the guide groove by detecting a change in the amount of light reflected from the side surface of the guide groove of the readout light beam. That is, the present invention eliminates the complexity of position adjustment between a plurality of beams in the prior art by detecting a tracking signal and recording information using a single beam. Furthermore, the present invention uses the tail of the recording beam, which does not contribute to recording, for tracking.
There is no need to increase the output of the light source more than necessary.

Furthermore, in the present invention, since tracking is performed in the same manner during recording and reproduction, it is possible to use a single optical system for both. In this case, recording and reproduction can be switched instantaneously by simply changing the intensity of the light beam. Therefore, by combining this method with a medium that can be reproduced immediately after recording as in the present invention, after recording information,
By immediately lowering the intensity of the light beam and reproducing the previously recorded information, it is possible to confirm whether or not the recording was made correctly.

〔Example〕

In the recording/reproducing method according to the present invention, a recording medium having a recording layer provided along the shape of a guide groove is used. The most common example of a recording medium used in the recording and reproducing method of the present invention is shown in FIG. The recording medium is composed of a substrate 1 on which guide grooves are formed and a recording layer 3. The substrate 1 has a bank part 2 for forming a guide groove, and accordingly, a bank part 4 is also formed in the recording layer. Usually, records are made in guide grooves between the bank sections. Recording of information is done by a laser beam. When the laser beam records in the guide groove, the bank functions as a guide so that the recording is made in the guide groove with high precision.
An example of recording using the recording medium shown in FIG. 1 is shown in FIG. In FIG. 1, cross-sections at A and A' are shown in FIG. That is, the structure of the recording medium as seen from a cross section consists of a substrate 1, a recording layer 3, and a bank portion 4. The laser beam 6 containing the recorded information becomes a beam 6' focused by the optical system 5,
The recording layer is irradiated. The recording layer absorbs the laser beam, and the irradiated portion of the recording layer undergoes melting deformation, melting, evaporation, etc. due to the thermal effect at that time, and recording is performed. In the case of FIG. 2, a state in which the recessed portion 7 is formed in the irradiation portion in this manner is shown. FIG. 3 shows a portion of the recording medium after recording.
Recording is done by the recess 7. At least one of the area, depth, and interval of the recesses changes depending on the type of recorded information.

The substrate is made of any material such as metal, glass, resin, or ceramics. For example, a substrate having guide grooves is formed by pouring a polymer such as polyvinyl chloride or acrylic between the original plates and polymerizing the polymer.

The recording layer is Bi, Sn, In, Al, Pb, Au, Cu,
It may be formed from a metal such as Cr or Ni, or a non-metallic material may be used. When recording by the thermal effect of light, a nonmetallic material that is light-absorbing and has low thermal conductivity is preferable. Chalcogen glass is a typical example of such non-metallic materials.
That is, glassy substances containing S, Se and/or Te may be mentioned. For example, As ₂ S ₃ , GeS,
These include As ₂ Se ₃ , As ₂ Te ₃ , Ge ₂ S ₃ , Ge ₂ S ₂ , S, and Se. Particularly from the point of view of practicality, Ge-S-based chalcogen glass is recommended. Chalcogen glass has
Metals such as In, Sn, Cu, and Ag may be added as necessary. Furthermore, SnO ₂ , In ₂ O ₃ , TiO ₂ , V ₂ O ₃
Metal oxides such as can also be used as the recording layer.
Also, semiconductor materials such as Si and Ge may be used.
The recording layer may be formed from a stack of a metal layer and a non-metal layer. For example, the lamination of a non-metal layer and a metal layer as described above can increase the recording density and surface strength compared to the case of only a metal layer.

The board is preferably 3 mm or less for discs to be played on a player. In some cases, a sheet with a thickness of 1 mm or less may be used.

The recording layer is usually set to a thickness in the range of 5μ to 0.003μ. The guide grooves can be formed on the substrate by any suitable means. For example, the surface of the substrate material may be etched to form guide grooves, pressed with a mold, or formed by molding. Further, when forming a recording layer on a substrate, it is necessary to form the recording layer so that the guide groove formed on the substrate is not filled with the recording layer. For this purpose, forming the recording layer by vapor deposition or sputtering is
This is one of the most effective methods for forming a recording layer.

The recording medium may have other configurations other than that shown in FIG. 1 as appropriate. The recording medium shown in FIG. 4 is an example of such another configuration, and is a recording medium consisting of a substrate 1, a recording layer 3, and a protective layer 10. This recording medium has bank portions 4 and 11 of a recording layer and a protective layer corresponding to bank portion 2 of the substrate. The results of recording on this recording medium using the same method as in FIG. 2 are shown in FIG. FIG. 5 shows the recording medium after recording, as viewed from the cross-sectional direction of lines C and C' in FIG. In the laser beam irradiated portion of the recording layer 3, a recessed portion 7 serving as a space is formed. The protective layer may be set so as not to be changed by laser irradiation, or it may be protected by increasing the laser irradiation intensity or by using a material that has a high absorption rate for the laser used and a low melting point. By forming the layer, both the recording layer and the protective layer may be deformed in the portion irradiated with the laser beam to form a recessed portion. Further, the protective layer may be applied in advance as a recording medium, or may be applied after recording. For example, by adding a protective layer to the surface of the recording medium after recording shown in FIG. 3, the recording medium has the shape shown in FIG. 6. In FIG. 6, the recording portion forms a concave portion on the surface. The first effect of adding a protective layer is to protect the recording surface from staining. Also,
It also has the effect of preventing the material of the recording layer from scattering around and touching the surface during recording, causing noise. Furthermore, when playing back by optical readout, if the thickness of the protective layer is increased to about 10 μm or more, dust attached to the surface of the protective layer and scratches formed on the surface of the protective layer will have no effect due to blurring. It becomes negligible and also acts to reduce dropout and noise.

Furthermore, depending on the optical properties of the protective layer, it can function as an antireflection layer and improve the recording sensitivity of the recording layer. The protective layer is usually set to a thickness of 0.1μ to 20μ. Materials for forming the protective layer include various resins such as styrene, acrylic, and vinyl, SiO,
Metal oxides such as SiO ₂ , Al ₂ O ₃ , ZrO ₂ , MgF ₂ ,
Metal fluorides such as _CaF2 are particularly effective.

Typical configurations of recording media used in the recording and reproducing method according to the present invention are shown in FIGS. 1 and 4.
Although described with reference to figures and the like, other configurations may also be employed. For example, the recording is usually made in the guide groove, but it goes without saying that the recording may be made in the bank of the recording medium if necessary. Recording means include laser beam, electron beam,
In addition to recording using energy beams such as various types of high-intensity light, recording may be performed using ordinary light. In this case, various photosensitive materials, magnetic materials, etc. may be used as the recording layer, if necessary. Reading of recorded information is carried out optically using changes in optical properties caused by exposure of the recording layer to light, such as optical density, reflected light, curvature, and scattering coefficient.

Various shapes can be adopted as the guide grooves of the recording medium. Among these, some of the most representative ones are shown in FIGS. 7-10. 7 to 10 are cross-sectional views of the recording member, and in the drawings 18, 20, 22 and 2.
4 are bank portions, and 19, 21, 23 and 25 are guide grooves. The shape shown in Figure 7 is an example in which the bank part and the guide groove are clearly distinguished, and the shapes shown in Figures 9 and 10 are examples in which the boundary between the bank part and the guide groove is continuous. It is. Also, the shape shown in Figure 8 is the same as that shown in Figure 7 and Figure 1.
This is an example of a shape intermediate to that shown in FIG.

The example of the shape of the guide groove illustrated above is the most basic one, and various other shapes of the guide groove based on this example can be appropriately employed in the present invention. Guide groove pitch in high-density recording (7th
In each of the recording media shown in FIGS.
The distance expressed as GP) is usually preferably set to 2 to 20 μm, particularly 4 to 8 μm. In addition, in the case of a recording medium having a bank portion having a flat top portion, such as the recording medium shown in FIGS. 7 and 8, the flat top portion is 5 μm.
m or less, particularly 1 μm or less is good. Also,
The depth of the guide groove is preferably set to 0.3 to 3 μm, particularly 0.5 to 1 μm.

In the recording and reproducing method of the present invention, when recording is performed by running a laser beam along the guide groove, the difference in reflection between the reflected light from the bottom of the guide groove and the reflected light from the bank is detected, By detecting when the laser beam is about to deviate from the guide groove and controlling it so that it always follows the guide, accurate tracking, that is, making the laser beam run along the guide groove is facilitated. Also,
The guide grooves are previously formed on the substrate, eliminating the difficulty of forming the guide grooves at the same time as recording. Furthermore, since recording is performed using a laser beam, real-time recording is possible. Furthermore, additional information can be additionally recorded within the range allowed by the recording capacity of the recording medium.

Further, in the present invention, since tracking errors are detected using the base of the spot, no recording is made on the part that functions as a guide for reasons that will be described later. Therefore, by using the present invention, it is possible to perform recording such that there are fewer read errors when reproducing information later.

To explain the above reason, generally speaking, the intensity distribution of a focused laser beam is
As is well known from the authors (page), the beam spot is high at the center and falls at the periphery, as if by subtracting a tail. If the base of this spot is made to span the bank of the guide groove, the light intensity at the base is low, and the slope of the bank is tilted with respect to the direction of incidence of the light beam, so the light intensity is not applied to the recording layer in this area. The energy per area is small, and no information is recorded and only tracking errors can be detected. Information is recorded only at the position where information is to be written, due to the center of the spot with high intensity. Also, when performing reproduction using a light beam, tracking of the readout light is performed using the directionality of the light reflected from the side surface of the guide groove.

Example 1 In the same way as when making a record, a polyvinyl chloride plate with a diameter of 30 mm and a thickness of 1.5 mm was brought into close contact with the master mold using a conventional method using a metal mold, and heated and pressurized. If the pitch of the guide groove is as shown in Figure 8.
A 4.03μ substrate was created.

A film with a thickness of 300 mμ was deposited on this substrate by vacuum evaporation.
A GeS layer was formed. Furthermore, a polyester layer having a thickness of 3 μm was formed thereon by coating by dating.

This recording medium was subjected to recording using a laser recording device using an 800 mW argon laser beam with a wavelength of 4579 Å. The recording medium was vacuum-adsorbed onto a turntable and rotated at 1500 rpm. The laser beam was intensity-modulated using an electro-optic modulation element using a video signal used in television.

Light was focused on a 0.7μ x 2μ spot using a 100x objective lens. 2μ is the length of the spot in the direction perpendicular to the direction of the guide groove, but the light beam naturally has a base that expands over 2μ, and this part reflects light from the bottom of the guide groove and the slope of the bank. arise. If the spot deviates from the center of the guide groove, the angle of reflection of the reflected light beam from the base to the bottom or from the bottom to the bank changes, so the amount of light incident on the photodetector placed at a predetermined position changes. Change. By detecting the change in the amount of incident light, the positional deviation can be detected, and this can be fed back to track the spot with respect to the guide groove.

The principle of detecting the positional deviation of the light beam described above will be explained using FIG. 14. FIGS. 14a and 14b are schematic cross-sectional views of one side end of the guide groove, respectively. first,
When the base L of the light beam is incident as shown in a, a part of it is reflected diagonally on the slope 82 of the bank and becomes a reflected light beam _R2 , and the remaining part is reflected on the bottom 81 and returns to the incident direction. The reflected light flux becomes _R1 . Here, when the base L of the light beam moves as shown in b, a portion of the base light beam that has been reflected at the bottom 81 moves to the slope 82 of the bank, and its reflection angle changes. Therefore, the amount of reflected light beam R ₁ returning to the incident direction decreases, and the amount of reflected light beam R ₂ in the oblique direction increases by that amount (actually, the incident light beam is not a parallel light beam but a convergent light beam). (Since the reflected light beam is not a parallel light beam, but a light beam having a certain angular range.) Therefore, by placing a photodetector at an arbitrary predetermined position that receives such a reflected light beam, it is possible to detect a positional shift of the light beam based on a change in the amount of received light. Also,
In reality, the intensity distribution of the light beam irradiated onto the guide groove is not uniform; it is high at the center and low at the periphery, so which part of the base of the light beam is the bottom? Also, the amount of reflected light differs depending on which part is reflected by the bank, and the change in the amount of light received by the photodetector due to the above-mentioned positional shift is further accentuated.

In the above description, the shape of the guide groove shown in FIG. 7 has been taken as an example, but it is possible to similarly detect the positional deviation of the light beam with guide grooves having other shapes. For example, Figures 8 and 10
In the example shown in the figure, the bottom of the guide groove and the bank are smoothly continuous. Therefore, the reflection angle of the reflected light flux gradually changes as the light beam moves. Therefore, if a photodetector is placed at an arbitrary predetermined position to receive this reflected light beam, the amount of light received will increase or decrease according to the change in the reflection angle, and the positional deviation of the light beam can be detected from this. Further, in the example shown in FIG. 9, the guide groove is formed in a V-shape. In this case as well, as the light beam moves, the direction in which the light beam is reflected changes between one side and the other side with the central part of the groove as a boundary. Therefore, by placing a photodetector at an arbitrary predetermined position where this reflected light beam is received, it is possible to detect the positional shift of the light beam as a change in the amount of received light.

In this way, it was possible to perform recording by forming recesses with a minimum recording wavelength of 2.51μ and a maximum recording wavelength of 7.77μ.

Example 2 A 5000 Å Al layer formed on an acrylic plate was used as the substrate, and a 5000 Å Al layer of GeS ₂ was used as the recording layer.
layer was used.

A recording medium was formed by coating the butyral layer, which served as an insulating layer, to a thickness of 2 μm using alcohol as a solvent. Recording was performed on this medium using the same recording device as in Example 1. However, the rotation speed is
At 450 rpm, minimum recording wavelength 0.64μm, maximum recording wavelength
The pitch of the guide grooves was 6.35 μm, and the cross-sectional shape was as shown in FIG.

[Brief explanation of drawings]

FIG. 1 is a diagram showing one embodiment of a recording medium used in the recording and reproducing method of the present invention. FIG. 2 is a diagram showing one embodiment of the recording/reproducing method of the present invention. FIG. 3 is a diagram showing one aspect of the recording medium after recording according to the present invention.
FIG. 4 is a diagram showing another embodiment of the recording medium used in the recording and reproducing method of the present invention. FIG. 5 and FIG. 6 are diagrams each showing another aspect of the recording medium after recording according to the present invention. FIG. 7, FIG. 8, FIG. 9, and FIG. 10 are diagrams each showing another embodiment of the recording medium used in the recording/reproducing method of the present invention. Figure 11,
FIGS. 12 and 13 are schematic diagrams illustrating conventional reproduction and recording methods. FIG. 14 is a schematic diagram illustrating the principle of recording and tracking in the present invention. 1 is the substrate, 2 is the bank of the substrate, 3 is the recording layer, 4
5 is a bank of the recording layer, 5 is an optical system, 6 and 6' are laser beams, and 7 is a concave portion.

Claims (1)

[Claims] 1. A recording medium in which a recording layer made of a material that can be reproduced immediately after recording with a light beam is formed on a substrate on which guide grooves are formed, in such a manner that the guide grooves are not buried. A recording laser beam having a spot and a base expanding from the spot is focused and irradiated onto the guide groove, and at the same time information is recorded on the recording layer by the spot, the base part of the beam is A positional deviation between the beam and the guide groove is detected by detecting a change in the amount of reflected light caused by reflection on the bank of the guide groove, and this is fed back to track the spot with respect to the guide groove, and The information recorded as described above is reproduced by irradiating the guide groove with a readout light beam, and at the same time, by detecting a change in the amount of light reflected from the side surface of the guide groove, the readout light beam is A recording and reproducing method that tracks a guide groove.