JPH0729185A - Optical recording medium - Google Patents

Abstract

PURPOSE:To obtain an optical recording medium in which information can be recorded at high density and continuously. CONSTITUTION:An uneven groove track 102 is formed in a spiral shape on an optical recording medium 101. In the groove track 102, protruding groove tracks 105 and recessed groove tracks 106 are arranged alternately every other circle on the optical recording medium 101. Then, a changeover detection region 103 in which discrimination information discriminating that the shape of the tracks is changed over is recorded is formed at the head of the protruding groove tracks and of the recessed groove tracks. Consequently, the boundary between the protruding groove tracks 105 and the recessed groove tracks 106 can be detected, and a recording and reproduction condition can be changed over easily or the polarity of a tracking control operation can be changed over easily. In addition, even when a track pitch is made narrow, a track width becomes wide as compared with that in conventional cases, and the optical recording medium can be manufactured extremely easily.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical recording medium for irradiating a converged light beam and recording information by heat generated by the light beam, and more particularly to an optical recording medium having a groove track having an uneven shape.

[0002]

2. Description of the Related Art In recent years, optical recording media capable of recording information have been
Since it can hold a large amount of data, voice information data
It is occupying an important position as a storage of video information data and various types of information equipment data. However, there is a demand for a larger capacity, and in order to meet this demand, it is necessary to further improve the information recording density on the optical recording medium.

As a conventional optical recording medium, a spiral groove track having a fine 0.8 μm width and a pitch of 1.6 μm is formed on the surface of a disk-shaped resin substrate, and a method such as sputtering is formed on the surface of the substrate. It is known that a thin film of a ternary phase-change recording material containing Te, Sb, and Ge as main components is formed, and a protective layer is provided on the thin film. This resin substrate is made into a stamper on the basis of a master disc having concave and convex groove tracks, and a large amount of it is reproduced by a method such as injection using this stamper.

The phase-change recording material has a property that when heated and gradually cooled, it becomes crystalline, and when it is melted and rapidly cooled, it becomes amorphous. Utilizing this property, the phase-change recording medium reversibly changes the crystalline state and the amorphous state, and like the magnetic recording medium such as a floppy disk or hard disk, the information can be overwritten in the same place many times. it can. When recording information on a phase-change recording medium, the recording medium is rotated at a predetermined speed and tracking control is performed so that the light beam is positioned on the groove track, and the intensity of the light beam is adjusted according to the signal to be recorded. The intensity is modulated between the amorphous level and the crystallization level. For example, when recording is performed so that the recording mark is in an amorphous state, a light beam having a light amount sufficient to melt the thin film is formed to form an amorphous state mark, and a mark other than the recording mark is not melted. Crystallization is performed by irradiating a light beam of a light amount. Therefore, during the period other than the recording mark, whether the previous state is amorphous or crystalline, the state is crystalline, and overwriting can be performed even at a place where information is already recorded.

The information recorded on the phase change recording medium is reproduced by utilizing the difference in reflectance or transmittance between the amorphous state and the crystalline state. For example, a weak constant light beam is emitted, reflected light from the recording medium is received by a photodetector, and information is reproduced by changing the amount of reflected light.

[0006]

The information density of an optical recording medium of this type is determined by the pitch of the information tracks and the information density in the track direction, that is, the linear density of information. To improve the information density on the optical recording medium, the track is used. Narrow the pitch,
It is necessary to increase the linear density. However, since the conventional optical recording medium is configured to record information on a groove track that is either concave or convex, if the track pitch is narrowed, the track width becomes narrower. Will be difficult. Further, when reproducing the information recorded on the groove track, there is a problem that the reproduction signal quality deteriorates because the amount of reflected light or transmitted light from the groove track decreases. Further, when the positional deviation between the light beam on the optical recording medium and the groove track, that is, the track deviation signal is detected by the push-pull method, the magnitude and dynamic range of the track deviation signal are determined by the groove track width and pitch. If the width of the groove track is narrowed to narrow the pitch, the amplitude of the track deviation signal becomes small and the dynamic range becomes narrow. Therefore, there is a problem in that the tracking control becomes unstable because the quality of the track deviation signal deteriorates, and the track jump easily occurs due to a disturbance such as a vibration shock.

In view of the above problems, the present invention is to provide an optical recording medium suitable for high density recording which can be easily manufactured without lowering the reliability of the apparatus even if the pitch is narrowed.

[0008]

In order to solve the above problems, in an optical recording medium of the present invention, a recording thin film is formed on a substrate having concave and convex groove tracks, and convex groove tracks and concave grooves are formed. In a disc-shaped optical recording medium in which groove tracks are alternately arranged and one spiral groove track is formed, it is identified that the shape of the track is switched to the head of the convex groove track and the concave groove track. Track identification information is provided.

In the optical recording medium of the second aspect of the present invention, convex groove tracks and concave groove tracks are alternately arranged for each circumference to form one spiral groove track, and a convex groove track is formed. The track address for identifying the recording area is provided at the beginning of the concave groove track.

In the optical recording medium of the third aspect of the present invention, a recording thin film for recording information by heat of a light beam is formed on a substrate having concave and convex groove tracks, and the convex groove tracks and the concave groove tracks are formed. In the disk-shaped optical recording medium in which information is recorded on both sides, the width of the concave groove track is made narrower than the width of the convex groove track.

The optical recording medium of the fourth aspect of the present invention is arranged such that the center of the identification information for identifying the recording area is located between the center of the concave groove track and the center of the convex groove track. It was done.

[0012]

According to the recording media of the first and second aspects of the present invention, the boundary between the convex groove track and the concave groove track can be detected based on the identification information. Switching can be easily performed.

According to the optical recording medium of the third aspect of the present invention, the width of the concave groove track is made narrower than the width of the convex groove track. The conditions for recording information on the top and the conditions for recording information on the concave groove track are almost the same.

According to the optical recording medium of the fourth aspect of the present invention, the center of the identification information for identifying the recording area is located between the center of the concave groove track and the center of the convex groove track. Since the identification information can be widened, the identification information can be cut with the same light beam as the light beam for cutting the groove track, and the configuration of the cutting machine becomes simple.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An optical recording medium according to an embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a schematic view of an optical recording medium according to an embodiment of the present invention. FIG. 1A is a plan view of the optical recording medium 101, showing a concave or convex groove track 10.
2 is provided in a spiral shape. The spiral groove track 102 is formed by alternately repeating a concave groove track and a convex groove track for each circumference of the optical recording medium 101. A switching detection area 103 is provided in the boundary area, and identification information for detecting switching between the concave groove track and the convex groove track is recorded in the switching detection area 103. Reference numeral 104 denotes an information area in which information is recorded or information is recorded. FIG. 1B is a partially enlarged view of the switching detection area 103. Reference numeral 105 indicates a convex groove track, 106 indicates a concave groove track, and a chain line 107 indicates the center of the groove track 102. Reference numeral 108 is an identification information pit recorded in the switching detection area 103 in the form of unevenness. As shown in the figure, the pit 108 is provided at the head of both the convex groove track 105 and the concave groove track 106, and the size and interval of the convex groove track 105 and the concave groove track 106, that is, the spatial frequency. Are different. Therefore, it is possible to easily identify in advance whether the track to be scanned by the light beam next in the switching detection area 103 is a convex groove track 105 or a concave groove track 106.

The track width of the conventional optical recording medium is 0.8 μm.
m, and the track pitch is 1.6 μm, the track width needs to be extremely small, for example, 0.4 μm in order to reduce the track pitch to 0.8 μm, which is ½. It is difficult to cut such a narrow track and also difficult to duplicate. However, in the present invention, since the convex groove tracks 105 and the concave groove tracks 106 are alternately arranged in the radial direction of the optical recording medium 101, when the width of the groove tracks 102 is 0.8 μm, the track pitch is also 0. It becomes 0.8 μm. Therefore, the master can be easily cut, and the duplication becomes easy.

Further, for example, if the continuous convex groove tracks are formed in a spiral shape, the concave groove tracks are continuous between the convex groove tracks. When the groove track is formed in this way, two spiral tracks are formed, which makes continuous recording and reproduction difficult. For example, information is continuously recorded on a groove track having a convex shape from the inner circumference to the outer circumference of the optical recording medium, and then the information is returned to the inner circumference of the optical recording medium and continuously concave from the inner circumference to the outer circumference. Information needs to be recorded on the groove track. Therefore, information cannot be recorded while returning from the outer circumference to the inner circumference. Further, even if the convex groove track and the concave groove track are alternately recorded every one rotation of the optical recording medium, for example, the convex groove track is changed to the concave groove track every one rotation of the optical recording medium. It is necessary to perform the interlaced scanning of the light beam, and information cannot be recorded during the interlaced scanning of the tracks. However, in the above-described optical recording medium 101 of the present invention, since the groove track 102 is one spiral track, information can be continuously recorded or reproduced.

Since the heat dissipation conditions are generally different between the convex groove tracks 105 and the concave groove tracks 106, it is necessary to change the recording conditions such as the recording light quantity of the light beam for recording information or the irradiation pulse width. Further, when the widths of the convex groove track 105 and the concave groove track 106 are different, the amount of reflected light is different and the magnitude of the reproduction amplitude is different. Furthermore, for example, when tracking control is performed by detecting a track deviation signal by the push-pull method, the polarities of the track deviation signal are opposite between the convex groove track 105 and the concave groove track 106. In the optical recording medium 101 of the present invention, the track identification information for identifying the form of the track is recorded in the switching detection area 103. Therefore, the recording / reproducing condition or tracking is performed by the convex groove track 105 and the concave groove track 106. The control polarity can be easily switched.

FIG. 2 is an enlarged and exaggerated cross-sectional view of the optical recording medium 101 cut in the radial direction. A convex groove track 105 and a concave groove track 106 are formed on one surface of a substrate 201 made of polycarbonate resin or the like. Then, a dielectric film 202 of SiO ₂ or the like, a recording material film 203, and a dielectric film 204 are sequentially provided thereon, and the dielectric film 204 and the protective layer 206 are adhered by an adhesive. 205 is an adhesive layer made of an adhesive. The recording material film 203 is formed, for example, by a method such as sputtering using a phase change recording material containing Te (tellurium), Sb (antimony), and Ge (germanium) as main components. The dielectric films 202 and 204 are for protecting the recording material film 203 from humidity or thermal shock and can be omitted.

A device to which the above-described phase change type optical recording medium 101 is applied will be briefly described with reference to FIG. In FIG. 6, the optical recording medium 101 is attached to the rotation shaft of the motor 601 and is rotated at a predetermined rotation speed. An optical beam generated from a light source 602 such as a semiconductor laser is converted into parallel light by a coupling lens 603,
It passes through a polarization beam splitter 604 and a quarter-wave plate 605, is reflected by a total reflection mirror 606, and a converging lens 607.
Are converged and irradiated onto the optical recording medium 101.
The reflected light reflected by the optical recording medium 101 passes through the converging lens 607, is reflected by the total reflection mirror 606, and is ¼
Polarization beam splitter-6 after passing through the wave plate 605
It is reflected at 04 and is irradiated onto the photodetector 608. The converging lens 607 is attached to the movable portion of the actuator 609. The actuator 609 is composed of a tracking coil provided in the movable part and a permanent magnet attached to the fixed part. Therefore, when a current is applied to this coil, the converging lens 607 moves in the radial direction of the optical recording medium 101, that is, across the groove track on the optical recording medium 101 due to the electromagnetic force received by the coil. A coil for a focus is also attached to the movable part of the actuator 609, and when a current is passed through this coil, the converging lens 607 is perpendicular to the surface of the optical recording medium 101 due to the electromagnetic force received by the coil. It is configured so that it can move in any direction. The converging lens 607 is focus-controlled so that the optical beam irradiated onto the optical recording medium 101 is always in a predetermined converging state.

A light source 602, a coupling lens 603, a polarization beam splitter 604, and 1 are provided on the transfer table 610.
/ 4 wavelength plate 605, total reflection mirror 606, photodetector 608, and actuator 609 fixed parts are attached, and transfer table 610 is configured to move in the radial direction of optical recording medium 101 by linear motor 611. Has been done. The photodetector 608 has a two-part structure, and its output is an I / V converter 612, 613 that converts current into voltage.
Have been entered respectively. I / V converters 612 and 61
The output signal of No. 3 is input to the differential amplifier 614, and the differential amplifier 614 outputs a signal according to the difference between the two signals.
The output signal of the differential amplifier 614 becomes a signal representing the positional deviation between the optical beam and the groove track converged on the optical recording medium 101, that is, a track deviation signal. The method of detecting this track deviation signal is push. It is called the pull method.

The signal of the differential amplifier 614 has a polarity switching circuit 61 for switching the polarity of tracking control.
5, added to the tracking coil of the actuator 609 via the phase compensation circuit 616 for compensating the phase of the tracking control system and the drive circuit 617 for power amplification, and converged on the optical recording medium 101. Light beer
The tracking is controlled so that the track is always located on the groove track. Further, the signal of the differential amplifier 614 is applied to the linear motor 611 via the polarity switching circuit 615, the phase compensation circuits 616 and 618, and the drive circuit 619 for power amplification, and the converging lens 607 is centered on a natural state. The transfer is controlled to move. An adder circuit 620 outputs a signal obtained by adding the signals of the I / V converters 612 and 613. The adder circuit 620 outputs a signal according to the difference in reflectance between the amorphous state and the crystalline state, and reads the information recorded on the optical recording medium 101 from this signal. Further, the adding circuit 620 outputs a signal corresponding to the pit 108 in the switching detection area 103. The discrimination circuit 621 discriminates from the output signal of the adder circuit 620 whether the groove track 102 on which the light beam is located next is the convex groove track 105 or the concave groove track 106, and sends this discrimination signal to the polarity switching circuit 615. The polarity switching circuit 615 switches the polarity of the input signal in response to the output signal of the identification circuit 621. For example, the polarity switching circuit 6
When a low level signal indicating the convex groove track 105 is sent from the identification circuit 621, the differential amplifier 15 receives the differential amplifier 101.
A signal in phase with the output signal of No. 4 is output, and when a high level signal representing the concave groove track 106 is sent, a signal in antiphase is output. Therefore, the polarity of the tracking control is reversed every one rotation of the optical recording medium 101, so that the light beam has a convex groove track 105 and a concave groove track 106.
Is continuously traced every one turn, and continuously traced on one spiral track formed.

When recording information, the intensity of the light beam generated from the light source 602 is modulated according to the information to be recorded, which will be described with reference to FIG. In FIG. 7, the vertical axis represents the light amount of the light beam and the horizontal axis represents time.
P0 is a reproduction light amount when reading information recorded on the optical recording medium 101, P1 is a crystallization light amount that makes the phase change material into a crystalline state, and P2 is an amorphous light amount that makes the phase change material into an amorphous state. is there. The recording material in the portion irradiated with the amorphization light amount P2 is melted to be in an amorphous state regardless of whether the state before irradiation is the crystalline state or the amorphous state. Also, the crystallization light amount P
The portion of the recording material irradiated with 1 is in a crystalline state regardless of whether the state before irradiation is a crystalline state or an amorphous state.

In the embodiment of the invention of FIG. 1, the switching groove 103 has a convex groove track 105 and a concave groove track 1.
Although the uneven signal having different spatial wavelengths is recorded in No. 06, it is not limited to this. For example, the switching area 10
The identification information recorded in 3 can be the track address. In this case, for example, if continuous track numbers are recorded from the inner circumference to the outer circumference of the optical recording medium 101, it is possible to determine whether the groove number is a convex groove track 105 or a concave groove track 106 depending on whether the track number is an even number or an odd number. You can

Further, each time the optical recording medium 101 is rotated, the convex groove tracks 105 and the concave groove tracks 106 are alternately repeated to form one spiral track, but the optical recording medium surface is radially formed. It is possible to form one spiral groove track by dividing into an odd number and alternately switching the convex groove track and the concave groove track a plurality of times per revolution. In this case, it is not always necessary to divide the optical recording medium into equal angles, and if n is a positive integer, it becomes (2n + 1) so that convex groove tracks and concave groove tracks are alternately arranged in the radial direction of the optical recording medium. Just divide it. And
When tracking control is performed by detecting a track deviation signal by the push-pull method, if the polarity of the track deviation signal is reversed at the switching point between the convex groove track and the concave groove track, the light beam will have one spiral shape. It can be followed continuously so as to be located on the groove track.

One embodiment in which one spiral groove track is formed by alternately switching the convex groove track and the concave groove track a plurality of times per revolution will be described with reference to FIG. FIG. 3A is a plan view of the optical recording medium 301, in which concave or convex groove tracks 302 are provided in a spiral shape. Reference numeral 303 is an ID in which identification information for identifying the position of the information area is recorded in the form of uneven pits.
An area 304 is an information area in which information is recorded or information is recorded. One spiral track is divided into a plurality of odd-numbered sectors, that is, three sectors 305 of 0, 1, and 2 in FIG.
Is composed of a pair of ID area 303 and information area 304. FIG. 3B is a partially enlarged view in which the ID area 303 is enlarged. Reference numeral 306 is a convex groove track, 307 is a concave groove track, and identification information composed of pits 308 is provided corresponding to each information area. ID area 3
The track number and sector number are recorded in 03,
If the track number and the sector number are odd or even, the groove track 302 to be scanned by the light beam next is a groove track 30 having a convex shape.
6 or concave groove track 307.

In the embodiment of the present invention shown in FIG. 3, the ID area 30 is used.
Although the track number and the sector number are recorded in No. 3, it is not limited to this. For example, consecutive sector numbers may be recorded in the ID area 303 from the inner circumference to the outer circumference of the optical recording medium 301. For example, 0 to 2 on the innermost first groove track 302 and the second groove track 3
The sector numbers from 3 to 5 are recorded on 02, and the following consecutive sector numbers are recorded in the same manner. By recording the consecutive sector numbers in this manner, it is possible to identify whether the groove track 302 scanned by the light beam next is a convex groove track 306 or a concave groove track 307, depending on whether the sector number is an odd number or an even number.

In the embodiment of the present invention shown in FIG. 3, the convex groove tracks 306 and the concave groove tracks 307 are alternately repeated every one rotation of the optical recording medium 301, as in the embodiment shown in FIG. One spiral groove track 302 can be formed. For example, the convex groove track 306 and the concave groove track 307 are switched with the sector 0 as a boundary. In this case, the number of sectors per round should be an even number,
Whether the groove track 302 to be scanned by the light beam next is a convex groove track 306 or a concave groove track 307 can be identified based on whether the track number is odd or even.

An optical recording medium having two spiral groove tracks, a continuous convex groove track and a concave groove track, for recording information on both the convex groove track and the concave groove track. The suitable identification information will be described with reference to FIG. FIG. 4A is a plan view of the optical recording medium 401, showing a spiral convex groove track 402 and a concave spiral groove track 4 between the convex groove tracks 402.
Two groove tracks 404 of No. 03 are provided. 40
Reference numeral 5 is an ID area, and 406 is an information area, and the spiral groove track 404 for one round is divided into four sectors 407. FIG. 4B is a partially enlarged view of the ID area 405. The identification information provided in the ID area 405 is the convex groove track 402 and the concave groove track 4.
It is arranged almost on the boundary line of 03. That is, the center of the convex groove track 402 and the concave groove track 40.
The centers of the pits 408 forming the identification information are arranged between the three centers, and the information areas of the adjacent convex groove tracks 402 and concave groove tracks 403 are identified based on one identification information. Is formed. In FIG. 4B, the convex groove track 402a and the concave groove track 403a, and the convex groove track 402b and the concave groove track 403b are respectively identified based on the same identification information. In the information areas of the convex groove track 402 and the concave groove track 403, when the track shift signal is detected by the push-pull method and tracking control is performed, the polarities of the track shift signal become opposite. Therefore, even if the identification information of the information areas of the convex groove track 402 and the concave groove track 403 is the same, it is possible to determine the convex groove track 402 and the concave groove track 403 from the polarity of the tracking control. Can be identified without.

When two spiral tracks are cut, for example, if a continuous convex groove track 402 is cut into a spiral shape, the convex groove track 40 is cut.
A continuous groove track 403 is formed between the two. When the identification information is separately provided to the convex groove track 402 and the concave groove track 403, at least the concave groove is provided in addition to the light beam for cutting the identification information for the convex groove track 402 and the convex groove track 402. A light beam is needed to cut the identification information for track 403. However, if the convex groove track 402 and the concave groove track 403 are shared as the identification information as in the embodiment of FIG. 4, only the convex groove track 402 and the light beam for cutting the identification information are used. be able to. Further, by providing the identification information in this way, the width W3 of the pit 408 of the identification information can be made approximately the same as the width of the groove track. Therefore, it is necessary to slightly move in the radial direction of the optical recording medium 401 using an optical deflector or the like for recording, but the identification information is recorded with the same light beam as the light beam for cutting the convex groove track 402. Since the cutting machine is simple and the pit can be enlarged, it can be easily molded.

In FIG. 4, W1 is a convex groove track 4
02, W2 indicates the width of the concave groove track 403, respectively. Since the identification information of the convex groove track 402 and the concave groove track 403 are also used, if the width W3 of the pit 408 is too small, it becomes difficult to read the identification information. Therefore, if W3 ≧ W1 or W3 ≧ W2, the convex groove track 402 or the concave groove track 4 is formed.
In the state in which the light beam is scanning over 03, almost half of the light beam spot scans over the pit 408, so that high-quality identification information can be obtained. Also, the width W of the pit 408 is excessively large.
When 3 is increased, crosstalk from adjacent identification information increases, and this crosstalk makes it difficult to read the identification information. According to the experiment, W3 ≦ (W1 + W
When 2) × 0.8, the result that the identification information can be read with high reliability is obtained.

The optical recording medium 401 of the embodiment shown in FIG. 4 has a continuous convex groove track 402 and a concave groove track 403.
Although two spiral groove tracks 404 are formed, the convex groove tracks and the concave groove tracks are alternately repeated every one rotation of the optical recording medium, as in the embodiment of FIG. A spiral groove track of a book can be formed. In this case, since the polarities of tracking are opposite between the convex groove track and the concave groove track, the polarity of the tracking control can be automatically reversed every one rotation of the optical recording medium, for example, every time sector 0 is detected. Good. Needless to say, in the embodiment of FIG. 4, the optical recording medium 401
The number of sectors per round may be an odd number, and the concave groove track and the convex groove track may be switched for each sector.

Next, the convex groove track and the concave groove track are
The width of the circle will be described with reference to FIG. Figure 5 is light
Enlarged sectional view of the recording medium 501 cut in the radial direction
To improve heat dissipation and improve heat dissipation.
Of the dielectric film 505 to protect the recording material film 504.
A structure in which a reflective layer 506 of aluminum or the like is further provided thereon
I am trying. That is, a convex groove track on one surface
509 and a grooved track 510 having a concave groove are formed.
SiO on the substrate 502 such as polycarbonate resin ₂ Etc.
Electric film 503, recording material film 504, dielectric film 505,
A reflective layer 506 and a protective layer 5 are provided in order.
08 is bonded with an adhesive.

Considering the reproduced signal quality, it is desirable that the amount of reflected light from the convex groove track 509 and the amount of reflected light from the concave groove track 510 are equal. To satisfy this condition, the width W1 of the convex groove track 509 and the width W2 of the concave groove track 510 may be made substantially equal.

However, when a material such as a phase change recording material on which information is recorded by heat is used as the recording material, the convex groove track 509 and the concave groove track 5 are used.
The 10 width relationship requires consideration of the record.

The thermal conductivity of the substrate 502 depends on the recording material film 50.
4. The thermal conductivity of the reflective layer 506 is smaller than that of the reflective layer 506 by almost an order of magnitude, and the thermal conductivity of the reflective layer 506 is higher than that of the recording material film 504. Therefore, the heat generated by the light beam applied onto the convex groove track 509 or the concave groove track 510 is radiated through the reflection layer 506, the recording material film 504 or the dielectric films 503 and 505. As shown in FIG. 5, the concave groove track 510 is surrounded by the reflective layer 506 and the dielectric films 503 and 505, but the convex groove track 509 is not surrounded. Therefore, the optical recording medium 5
In the radial direction 01, the concave groove track 510 radiates heat better than the convex groove track 509, and the sensitivity is lowered. It is desirable that the recording sensitivities of the convex groove track 509 and the concave groove track 510 are equal. To equalize the heat radiation, the width W2 of the concave groove track 510 is made smaller than the width W1 of the convex groove track 509. Good.
In addition, the convex groove track 509 and the concave groove track 51
When the track deviation is detected by the push-pull method, the step d of 0 is best at about λ / (8n).
Here, λ is the wavelength of the light beam, and n is the refractive index of the substrate 501.

Some devices rotate the optical recording medium at a rotational speed that is inversely proportional to the radius so that the peripheral speed becomes constant, and there are devices that rotate so that the angular velocity becomes constant. There is no problem when rotating so that the peripheral speed becomes constant, but it is necessary to consider the peripheral speed dependency when rotating so that the angular velocity becomes constant. As described above, the phase-change recording material has a property of becoming crystalline when heated and then slowly cooled, and becomes amorphous when rapidly melted and then rapidly cooled, but the crystallization speed and the peripheral speed are closely related. . That is, it is necessary to increase the crystallization speed as the speed of the light beam and the optical recording medium in the track direction (called linear speed) increases. For example, Te, S
b, in the case of a phase change recording material containing Ge as a main component, Sb
The crystallization rate becomes slower when the amount of is increased. Therefore, in an optical recording medium that is used by rotating at a constant angular velocity,
If the recording material is formed so that the amount of Sb increases as the radius decreases, the peripheral speed dependency can be reduced.

Further, by changing the width of the groove track between the inner circumference and the outer circumference of the optical recording medium, the dependence on the peripheral speed can be alleviated. For example, in the case of an optical recording medium in which the crystallization rate is set to be optimal for the outer linear velocity and the information is recorded with the amorphous state as a recording mark, when the information is recorded at the lower inner linear velocity, Also, the recording marks are less affected by the heat before and after the recording marks, so that the cooling effect is produced and the amorphous recording marks become smaller. Therefore, in this case, if the width of the groove track on the inner circumference is made wider so that the heat can be easily dissipated in the radial direction of the optical recording medium, an amorphous mark of a predetermined size can be formed. Further, in the case of an optical recording medium in which the crystallization speed is set to be optimal for the linear velocity of the inner circumference, when information is recorded at a high linear velocity of the outer circumference, a quenching effect occurs because the linear velocity is high, It becomes difficult to crystallize. In this case, if the groove track on the outer periphery is made narrower to make it difficult for heat to be dissipated in the radial direction of the optical recording medium, the unerased portion can be reduced. As described above, the peripheral speed dependence can be alleviated by changing the width of the groove track according to the radius of the optical recording medium.

Although the present invention has been described in detail above, the present invention is not limited to the embodiments described above. For example, a magneto-optical material may be used as the optical recording material without any problem, and any material capable of recording with a light beam may be used.

[0041]

According to the optical recording medium of the present invention, the convex groove tracks and the concave groove tracks are alternately arranged to form one spiral groove track, and the convex groove tracks and the concave groove tracks are formed. Since track identification information is provided at the beginning of the track to identify that the form of the track is switched, the boundary between the convex groove track and the concave groove track can be detected based on the identification information, and the recording / reproducing condition is switched. Alternatively, the polarity of tracking control can be easily switched. Further, since the track width can be widened even if the track pitch is narrowed, the manufacture of the optical recording medium is simplified.

Further, in the optical recording medium of the present invention, since the width of the concave groove track is made narrower than the width of the convex groove track, the heat dissipation conditions of the concave groove track and the convex groove track are almost equal. Therefore, it is possible to easily record high-quality information on both the convex and concave groove tracks. Also,
Since the optical recording medium of the present invention is provided with the identification information for identifying the recording area substantially on the boundary between the concave groove track and the convex groove track, the width of the identification information can be widened and the cutting can be performed. The configuration of the machine is simplified and the crosstalk between adjacent identification information can be reduced, so that the identification information can be read easily.

[Brief description of drawings]

FIG. 1A is a schematic front view of an optical recording medium according to a first embodiment of the present invention, and FIG. 1B is a partially enlarged view of an optical recording medium surface according to a first embodiment of the present invention.

FIG. 2 is an enlarged cross-sectional view of the optical recording medium according to the first embodiment of the present invention.

3A is a schematic front view of an optical recording medium according to a second embodiment of the present invention, and FIG. 3B is a partially enlarged view of an optical recording medium surface according to a second embodiment of the present invention.

4A is a schematic front view of an optical recording medium according to a third embodiment of the present invention, and FIG. 4B is a partially enlarged view of an optical recording medium surface according to the third embodiment of the present invention.

FIG. 5 is an enlarged cross-sectional view for explaining the width and step of the groove track of the optical recording medium.

FIG. 6 is a block diagram of an apparatus suitable for the optical recording medium according to the first embodiment of the present invention.

FIG. 7 is an explanatory diagram of a light beam irradiation light amount when recording information on a phase change recording medium.

[Description of Reference Signs] 101 Optical recording medium 102 Groove track 103 Switching detection area 104 Information area 105 Convex groove track 106 Concave groove track 107 Groove track center 108 Pit

Claims (8)

[Claims] 1. A recording thin film is formed on a substrate having concave and convex groove tracks, and convex groove tracks and concave groove tracks are alternately arranged to form one spiral groove track. An optical recording medium having a disc shape, wherein track identification information is provided at the head of the convex groove track and the concave groove track to identify that the form of the track is switched. 2. The optical recording medium according to claim 1, wherein the track identification information of the convex groove track and the track identification information of the concave groove track are made different. 3. The optical recording medium according to claim 1, wherein track identification information provided at the head of the convex groove track and the concave groove track is used as identification information for identifying a recording area. 4. A recording thin film is formed on a substrate having concave and convex groove tracks, and convex groove tracks and concave groove tracks are alternately arranged for each circumference to form one spiral groove track. A disc-shaped optical recording medium,
An optical recording medium in which a track address for identifying a recording area is provided at the head of the convex groove track and the concave groove track. 5. A recording thin film for recording information by heat of a light beam is formed on a substrate having concave and convex groove tracks, and information is recorded on both the convex groove track and the concave groove track. A disk-shaped optical recording medium, wherein the width of the concave groove track is narrower than the width of the convex groove track. 6. A disc-shaped optical recording medium in which a recording thin film is formed on a substrate having concave and convex groove tracks, and information is recorded on both convex groove tracks and concave groove tracks. An optical recording medium arranged such that the center of identification information for identifying a recording area is located between the center of the concave groove track and the center of the convex groove track. 7. The optical recording medium according to claim 6, wherein the width of the identification information is substantially equal to the convex groove track width or the concave groove track width. 8. The width of the identification information is made wider than the convex groove track width or the concave groove track width, and is 80% or less of a value obtained by adding the convex groove track width and the concave groove track width. Item 6. The optical recording medium according to item 6.