JP3164543B2 - Disk-shaped recording medium - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optically readable disc-shaped recording medium. 2. Description of the Related Art It is known that a groove is formed on a recordable optical disk in advance and a tracking error is detected by using the groove at the time of reproduction. It has been proposed by the present applicant to record other information (positional information on the disk) by wobbling the groove (see Japanese Patent Application No. 61-232741). Further, it is necessary to previously form a pit sequence such as an address for defining a position to be recorded on a disk. Generally, the pit series was not wobbled. Therefore, information other than the information possessed by the pit sequence itself cannot usually be recorded. Accordingly, it is an object of the present invention to provide a disk-shaped recording medium capable of recording predetermined information by wobbling a pit sequence. [0005] According to an aspect of this invention is an optically reproducible disc-shaped recording medium, with at signal modulated by Jo Tokoro signal, wobbled radially pre
And because the formed pit sequence, wider than the area of the pit sequence
A disk-shaped recording medium characterized in that grooves formed in advance by being wobbled in the radial direction are mixed together to form a recordable area for the grooves . [0006] Information such as addresses can be recorded in advance by a pit sequence formed as a discrete information pattern. Since this pit sequence is wobbled based on the predetermined information, it is possible to record the predetermined information together with the pit sequence. An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is an enlarged view showing a part of an embodiment of an optical disk according to the present invention. In this optical disk, TOC (Table Of Contents) information, a pulse signal of a predetermined cycle, and the like are recorded in advance on the lead-in track and the lead-out track in addition to the groove, like the CD (compact disk). Therefore, as shown in FIG. 1, the preformatted optical disk has a mixture of the area where the pits 31 are formed and the wide groove 32. As shown in FIG. 1, the width of the groove 32 is wider than the width of the pit 31. The pit 31 is wobbled. In one embodiment, data is recorded in a wide groove. Typically,
When data is recorded in a groove, noise increases due to the groove and the S / N decreases. On the other hand, when data is recorded in a land, the land adjacent to the disk in the disk radial direction does not have the same phase. However, since the width of the reproduction signal always changes, there is a disadvantage that the fluctuation of the reproduction signal is large. By recording data in a wide groove, it is possible to prevent a decrease in S / N and fluctuation of a reproduced signal. [0008] A recording method for producing the above-described optical disk will be described below. FIG. 2 shows an example of a recording method. In FIG. 2, reference numeral 1 denotes an optically recordable disk (master). The disk 1 is formed, for example, by applying a photoresist with a uniform thickness. Reference numeral 2 denotes a laser, for example, an argon ion laser. A recording beam from the laser 2 is guided to an optical modulator 3 using an acousto-optic effect. When ultrasonic waves are generated in an ultrasonic medium such as zinc molybdate (PbMoO ₄ ) or tellurium dioxide (TeO ₂ ), a periodic change in the refractive index occurs, and a phase type diffraction grating is formed. When a laser beam is incident on
The intensity and direction of the laser beam change depending on the intensity and frequency of the ultrasonic wave. The mutual effect between the ultrasonic wave and the light is the acousto-optic effect. An optical deflector to be described later also utilizes this acousto-optic effect. A signal from an input terminal 4 is supplied to the optical modulator 3 via a driver 5. This signal is an EFM (8 → 14 modulation) signal (pulse signal) when forming a pit sequence, and is used when forming a groove.
It is a constant level DC signal. By the EFM signal,
The recording beam intensity is turned on / off. The recording beam output from the optical modulator 3 is
The light is supplied to the optical deflector 6 using the acousto-optic effect. The optical modulator 3 changes the intensity of the diffracted light while keeping the frequency of the ultrasonic wave constant, while the optical deflector 6 changes the frequency of the ultrasonic wave while keeping the intensity of the diffracted light constant. Causes a deflection. The recording beam output from the optical deflector 6 is
The disk 1 is sequentially passed through the intermediate lens 7 and the objective lens 8.
Irradiated on top. The disk 1 is rotated at a CLV (constant linear velocity) by a spindle motor 9. For the optical deflector 6, a high-frequency signal (for example, 2) generated by a VCO (voltage controlled oscillator) 11 is provided.
24 MHz) is supplied via the driver 12. In order to wobble the recording beam by the optical deflector 6,
The frequency of the high frequency signal can be changed. A control signal is supplied from the terminal 10 to the VCO 11. As shown in FIG. 3A, when a pit sequence is formed, a control signal Sa having a frequency of (fw = 22.05 [KHz]) is supplied from the terminal 10, and the frequency of the high-frequency signal generated from the VCO is the frequency fw. By changing,
The recording beam is swung at this frequency fw. When forming a wide groove, as shown in FIG. 3A, a signal Sb having a sufficiently high frequency f ₀ is applied to the VCO 11 as a control signal in addition to the signal Sa. The frequency f ₀ is selected such that f ₀ > v / d, where d is the spot size of the recording beam and v is the linear velocity at the time of recording. As an example, (d = 0.5 μm, v = 1.25
m / sec), (f ₀ > 2.5 MHz, for example, 5 MHz). As shown in FIG. 3B, when a pit sequence is formed, the recording spot is wobbling at (fw = 22.05 KHz), and corresponds to the EFM signal applied to the optical modulator 3, and has a recording spot size. The same pit width is obtained. In the groove portion, the recording spot draws a trajectory in the width direction, and multiple exposure is performed in the area. With this multiple exposure,
After phenomena treatment of the photoresist, a wide groove wobbling at the frequency fw is obtained. The width w of the groove is determined by the amplitude of the signal Sb (d ≦ w ≦ q).
(Q: track pitch). The linear velocity at the time of recording may be slowed down as necessary, so that fine multiple exposure is performed. The signal of the frequency fw is not limited to a sine wave signal, but may be a clock signal or a signal frequency-modulated by absolute time information of a CD. FIG. 4 shows another example of the recording method. In this other example, unlike the above-described example, the optical modulator 3 and the optical deflector 6 are separately used, and the modulation and the deflection are performed by one device (referred to as an optical modulation deflector). It is like that. As shown in FIG. 4, the recording beam from the laser 2 is input to the light modulation deflector 22 via the intermediate lens 21. The light modulation deflector 22 uses an acousto-optic effect. The intermediate lens 21 is provided to narrow down the spot size. The position of the focal length F of the intermediate lens 21 and the center of the light modulation deflector 22 are separated by a distance of df. Even if the light modulation deflector 22 is deflected at the focal point of the intermediate lens 21, no wobbling occurs on the disk 1. When the distance df is increased,
Although the amount of wobbles on the disk increases, the spot size increases, making high-speed beam deflection and high-speed modulation difficult. Therefore, df depends on the required wobble amount.
Is determined. In FIG. 4, θd indicates the deflection angle. A high frequency signal from a driver 23 is supplied to the light modulation deflector 22. The driver 23 is supplied with an EFM signal (pulse signal) from a terminal 24. The driver 23 turns on / off the output signal of the driver 23 according to the EFM signal “0” and “1”. When forming the groove, a signal of the “1” level of the EFM signal is supplied from the terminal 24. When the EFM signal is "0", the output signal of the driver 23 is turned off, and the recording beam is not irradiated onto the disk 1. Therefore, pits corresponding to the EFM signal supplied from the terminal 24 are formed on the disk 1. A high frequency signal from the VCO 25 is supplied to the driver 23. A control signal is supplied from a terminal 26 to the VCO 25. This control signal is a 22.05 kHz signal as shown in FIG. 5A when a pit is formed, and as shown in FIG. 5B when a groove is formed.
The signal of 22.05 kHz and the signal of 5 MHz are superimposed. The VCO 25 has a center frequency of, for example, 224 MHz.
The frequency changes in accordance with the signal from The output signal of the VCO 25 is supplied to the optical modulation deflector 22 via the driver 23, whereby wobbling and formation of a wide groove are performed. Unlike the above-described recording method, when the pits 31 and the grooves 32 having different widths are formed by separate recording spots, the following problem occurs. With the same lens, the effective N.D. A. When the spot size is changed by changing the spot size, the spot size ratio cannot be so large. For example, a spot having a width of 0.5 [μm] and a groove having a width of 1.1 [μm] cannot be formed. Since it is necessary to form two beams, it is necessary to increase the laser power. For a spot having a large diameter, a groove having a sharp sectional shape cannot be obtained unless the shape is shaped. The groove width tends to change depending on the exposure level and the development conditions. On the other hand, according to the above-described one example of the recording method and other examples, when both the pit sequence and the wide groove are formed on the disk (master), both are formed by one recording beam. Can be formed. Accordingly, the following advantages are obtained, unlike the case where a separate recording beam is used. First, the width is electrically controlled, and a groove having a desired width can be easily formed. Second, since there is one recording beam, the configuration and adjustment of the optical system are simplified. Third, since a groove is formed by a thin spot, a groove having a sharp cross section can be obtained. Further, according to the other recording method, since the light modulation and the light deflection are performed by one device, the following advantages are provided in addition to the above advantages. First, the distortion of the spot shape of the recording beam can be reduced. Second, there is no need to synchronize the optical deflector and the optical modulator, and the alignment of the optical system is simplified. Third, the loss of laser power is small. Fourth, the deflection band becomes larger than when a parallel beam is incident on the optical deflector. The disk-shaped recording medium according to the present invention is
Information such as an address can be recorded in advance by a pit sequence formed as a discrete value information pattern.
Since the pit sequence is wobbled based on the predetermined information, it is possible to record predetermined information in addition to the information based on the pit sequence.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram showing a signal pattern of an optical disk to which the present invention is applied. FIG. 2 is a block diagram of an example of a recording method for creating a master optical disc according to the present invention. FIG. 3 is a schematic diagram used for describing an operation of an example of a recording method. FIG. 4 is a block diagram of another example of the recording method. FIG. 5 is a schematic diagram used to explain the operation of another example of the recording method. [Description of Signs] 1 disk, 2 laser, 3 optical modulator, 6 optical deflector, 21 intermediate lens, 22
..Light modulation deflectors

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-62-8341 (JP, A) JP-A-62-28944 (JP, A) JP-A-63-96736 (JP, A) JP-A 60-88 167129 (JP, A) JP-A-62-110637 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) G11B 7/24

Claims (1)

(57) [Claims] Be optically reproducible disc-shaped recording medium, with at signal modulated by Jo Tokoro signal, and the pit sequence formed previously been wobbled in the radial direction, wider than the area of the pit sequence, Wobbling in the radial direction
The formed grooves are mixed and the above grooves are recorded
A disk-shaped recording medium characterized by being a possible area .