JPH09274722A - Information recording device and method for optical disk - Google Patents

Abstract

PROBLEM TO BE SOLVED: To record a bit having pleural information parameters on a master disk by zigzaging an electronic beam route with a modulation output signal, deflecting it according to a deflection output signal and further, controlling the movement of the recording surface on the master disk. SOLUTION: An electronic beam emitted from an electronic gun 6 of an electronic beam irradiator 5 passes through an opening part of an aperture 7, and constitutes a beam spot of a minute area on the recording surface 1a by a blanking electrode 9, high speed deflection electrodes 11, 12 and an objective lens 8. At this time, the blanking electrode 9 zigzags the electronic beam route according to a modulation output signal output from a recording system control circuit 10. Further, the high speed deflection electrodes 11, 12 deflect the electronic beam in the respective axial directions according to a deflection output signal from the circuit 10. Then, the recording surface 1a on the master disk 1 is moved in the A direction by control of a feed rotation control circuit 13, and the beam spot records spirally on the recording surface 1a. Thus, the bit having plural information parameters is recorded.

Description

Detailed Description of the Invention

[0001]

[0001]

[0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disk information recording apparatus and information recording method.

[0003]

[0002]

[0004]

2. Description of the Related Art Conventionally, as shown in FIG. 6, an optical disk 92 represented by a compact disk (CD) and a laser disk (LD) is known. In this optical disc, music information and video information are recorded after being converted into a signal having the pit length as a parameter, and each information pit 91 has a constant width on the information recording surface 95 and has a long length. The information tracks are formed by arranging the directions along the spiral or concentric circles with respect to the center of the disc.

[0005]

In these optical disks 92, information pits are recorded on a master disk, a disk stamper is formed from the recorded master disk, and a synthetic resin or the like is heat-pressed or injection-molded by using the obtained disk stamper to form the pits 91. After the metal deposition process is performed on the recording layer 94 formed by being transferred from the master, the translucent substrate 93 and the like are formed and formed.
The recording of the information pits on the master is performed by an information recording device, and while the recording surface of the master is rotated, the irradiation spot of the recording beam can be made almost uniform by sending a header for irradiating a recording beam such as a laser beam in a radial direction as appropriate. Control so as to draw a spiral or concentric track locus at equal pitches, and turn the laser light ON / OFF according to the rotation speed of the recording master and the information content on that locus to make an information pit on the master. Was recorded.

[0006]

During reproduction of the optical disc 92, the information pit 91 is irradiated with laser light of a pickup so as to form a beam spot having a predetermined diameter, and the optical disc is rotated at a predetermined speed to scan the information pit 91. , The diffracted and reflected light from the pit to be scanned is detected by a photodetector composed of a photodiode and output as an electric signal, and the music information and video information recorded from the electric signal are recorded in the opposite manner from those at the time of recording. It was extracted by performing signal conversion.

[0007]

The conventional optical disc is configured as described above, and the information recorded by the recording device is reproduced by using the reproducing device. However, only the length of the pit carried by the disc is the parameter of the recorded information. Therefore, there is a limit in information recording density.

[0008]

In recent years, in an optical disk carrying information pits arranged spirally or concentrically, the information recording density of the disk is made such that the pit shape not only extends in the length direction along the track but also two-dimensionally. Studies have been conducted to reproduce more information by increasing.

[0009]

This is a method for detecting pits by utilizing the fact that the polarization characteristics of the reflected light change depending on the shape of the surface-deformed portion (for example, pits). If this method is used, it is about the same as the wavelength or When a reading laser beam is applied to a diffraction grating having the following period, the reflected light changes the light amounts of two polarization components, p-polarized light and s-polarized light, which are orthogonal to each other due to the groove shape. Can be regarded as a two-dimensional loop array, and each pit can carry more information by having a different shape for each pit and detecting the shape of the pit by the polarization characteristic of the reflected light.

[0010]

FIG. 7 shows an example thereof, in which the information pits arranged spirally or concentrically on the optical disk have the same shape in width, height and length, and the longitudinal directions of the pits are three directions. That is, with respect to the direction along the spiral or the concentric circle, the same direction and the direction of +45 degrees and -45 degrees.
When three kinds of pits are mixedly arranged so as to be in either direction of degrees, when a light beam of circularly polarized laser light is incident on these information pits, the polarization state of the obtained reflected light is p- When expressed by the light amount distribution in the s-polarization axis coordinate system, the same direction as the pit scanning direction and +45
It becomes an ellipse having a major axis in the direction of degrees and the direction of -45 degrees.

[0011]

Further, on the surface of the optical disc where the information pits are not recorded, the reflected light is reflected as circularly polarized light and its light amount distribution becomes circular. The signals obtained by these reflected lights are the signals Sp and s due to the p polarized light. It is represented by a coordinate system using the signal Ss by polarization, but if digital conversion is performed at each predetermined threshold value of Sp and Ss, four types of digital outputs can be obtained in a disc using pits of the same shape.

[0012]

Therefore, if these pits are formed on the optical disk, it is possible to have not only information parameters in the longitudinal direction of the pits, but also more information parameters depending on the deviation angle in the longitudinal direction. Compared with, the information density of the disc can be dramatically increased.

[0013]

However, when these information pits are recorded on the master, it is necessary to record them while swinging each pit at a corresponding angle with respect to the scanning direction, and the recording method by the conventional recording device described above should be used. I can't
The recording method was not established.

[0014]

[0012]

[0015]

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide an optical disk information recording apparatus capable of high density recording and an information recording method therefor.

[0016]

[0013]

[0017]

According to the first aspect of the present invention,
An information recording apparatus for an optical disc, which is formed by arranging a plurality of pits carrying information on a recording surface of a recording medium,
A rotating means for rotating a recording surface of a recording medium, a rotating means for rotating the recording surface at a predetermined speed around the rotating shaft, and a recording beam irradiating means for irradiating a recording area with a recording beam. A deflection means for deflecting the irradiation direction of the recording beam in a predetermined direction, a moving means for relatively moving the recording beam irradiation means and the rotating means along a recording surface rotated by the rotating means, and a rotating means. A rotation control unit that controls the rotation speed, a detection unit that detects the irradiation position of the recording beam on the recording surface, a movement control unit that controls the movement amount of the movement unit according to the detection result of the detection unit, and a rotation unit Control means for turning on / off the irradiation of the recording beam of the recording beam irradiation means and controlling the irradiation direction of the recording beam deflected by the deflecting means according to the rotation speed. That.

[0018]

According to a second aspect of the invention, in the optical disc information recording apparatus according to the first aspect, the recording beam emitted by the recording beam irradiating means is constituted by a laser beam.

[0019]

According to a third aspect of the present invention, in the optical disc information recording apparatus according to the first aspect, the recording beam emitted by the recording beam irradiating means is composed of an electron beam.

[0020]

According to a fourth aspect of the present invention, there is provided an optical disc information recording apparatus according to the first, second or third aspect,
The deflection means is characterized in that the recording beam can be deflected by two deflection axes orthogonal to each other.

[0021]

According to a fifth aspect of the present invention, there is provided an information recording method for an optical disc, wherein a plurality of pits carrying information are arranged on the recording surface of the recording medium to form the information recording method. The recording surface of the recording medium is rotated. Rotating means having a rotation axis for rotating the recording surface at a predetermined speed around the rotation axis, recording beam irradiating means having a recording beam for irradiating the recording surface in a fine area, and irradiation direction of the recording beam Deflection means for deflecting in a predetermined direction, moving means for relatively moving the recording beam irradiation means and the rotation means along a recording surface rotated by the rotation means, and rotation control means for controlling the rotation speed of the rotation means. The rotation control means uses the rotation control means to detect the irradiation position of the recording beam on the recording surface and the movement control means to control the movement amount of the movement means according to the detection result of the detection means. And the amount of movement of the moving means are controlled by the movement control means, and the irradiation of the recording beam of the recording beam irradiating means is turned ON / OFF and the deflecting means deflects according to the rotating speed of the rotating means. It is characterized in that the irradiation direction of the recording beam is controlled.

[0022]

According to a sixth aspect of the present invention, in the information recording method of the optical disc according to the fifth aspect, the recording beam emitted by the recording beam irradiating means is composed of laser light.
The pit is characterized in that it is formed in a region on the recording surface of the recording medium which is irradiated with the laser beam.

[0023]

According to a seventh aspect of the invention, in the information recording method of the optical disc according to the fifth aspect, the beam irradiated by the recording beam irradiation means is composed of an electron beam, and the pit is irradiated with the electron beam. It is characterized in that it is formed in an area on the recording surface of the recording medium.

[0024]

The invention according to claim 8 is the information recording method for an optical disc according to claim 5, 6 or 7,
The deflection means is configured to be capable of deflecting the recording beam by two deflection axes which are orthogonal to each other, and the pits are formed on the recording surface by controlling the drive of the recording beam corresponding to the two deflection axes. Is characterized by.

[0025]

[0021]

[0026]

Since the present invention is configured as described above, a two-dimensional deflector for displacing the recording beam of the information recording device in two axes is used, and the deflection amount and the deflection speed of the deflector are controlled independently in two axes.
In addition, by synchronizing with the modulation signal of the information data to be recorded and the rotation speed of the master, it is possible to record the information pits on the master by changing the deflection angle in the longitudinal direction of each pit with respect to the recording pit row. A pit having a plurality of information parameters can be recorded on the master disc of the optical disc.

[0027]

[0022]

[0028]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, an embodiment of an information recording apparatus and an information recording method for an optical disc according to the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the schematic arrangement of an information recording apparatus for an optical disc according to an embodiment of the present invention. In the figure, reference numeral 1 denotes a master used for forming an optical disc, which is installed on a rotary shaft (not shown) of the spindle motor 2 and is configured to be rotatable integrally with the rotary shaft.
Further, the spindle motor 2 is attached to the feed mechanism 3 and is configured to be able to move the recording surface 1a of the master 1 in the horizontal direction (arrow A).

The feed mechanism 3 is installed in the vacuum chamber 4 together with the master disk 1 and the spindle motor 2, and an electron beam irradiator 5 is provided vertically above the recording surface 1a and has a predetermined distance from the recording surface 1a. And is installed in the vacuum chamber 4. An electron beam is emitted from an electron gun 6 included in the electron beam irradiator 5, passes through the opening of the aperture 7, and then enters the recording surface 1a by the objective lens 8 to irradiate the recording surface 1a in a fine area. It is configured to form a beam spot.

[0031]

A blanking electrode 9 is provided in the path of the electron beam emitted by the electron gun 6, and the blanking electrode 9 is emitted according to the output of the modulation output signal L (t) from the recording system control circuit 10. A switch is configured to turn on / off the irradiation of the electron beam on the recording surface 1a by making the path of the electron beam go straight or bent, and passing or blocking the electron beam at the opening of the aperture 7.

[0032]

Further, high-speed deflection electrodes 11 and 12 are provided in the path of the electron beam emitted by the electron gun 6. The high-speed deflection electrodes 11 and 12 are composed of electrodes that are orthogonal to each other, and are provided so that the emitted electron beams can be independently deflected in two axial directions that are orthogonal to each other in a plane parallel to the recording surface 1a, and each recording is performed. A deflection unit that deflects the emitted electron beam in each axial direction according to the deflection output signals X (t) and Y (t) output from the system control circuit 10 is configured.

[0033]

A feed rotation control circuit 13 has a predetermined linear velocity information V, a predetermined track pitch information P, and
The rotation speed (V / 2πR) of the spindle motor 2 and the feed speed (PV / 2πR) of the feed mechanism 3 are controlled by the recording radius R detected by the radius sensor 26, and the spindle motor 2 rotates in a pair with the rotation shaft. By moving the recording surface 1a of the master 1 in the horizontal direction (arrow A), spiral recording is performed on the rotating recording surface 1a by the beam spot irradiated on the recording surface 1a described above. The feed rotation control circuit 13 further outputs the linear velocity information V to the recording system control circuit 10.
Output to

[0034]

FIG. 2 is a block diagram showing the main structure of the recording system control circuit 10.

In the figure, the recording system control circuit 10 is provided with a clock synchronization means 14 for generating a synchronization clock,
The pit length information of the sequentially supplied information data is synchronized with the linear velocity information V supplied from the rotation control circuit 13 at the same time, and the storage unit 15 (memory 1), the storage unit 16 (memory 2), and the storage unit 17 are synchronized. (Memory 3).

[0036]

Further, in the recording system control circuit 10, the data modulating section 18 extracts the data L (n) and the data L (n) concerning the length in the longitudinal direction from the pit information sequentially supplied as the information data among the information parameters of the pits. Data about the angle of the pits with respect to the arrangement direction θ (n)
Are modulated and output to the storage unit 17 (memory 3) and the coordinate conversion unit 19, respectively.

[0037]

Further, the storage means 17 stores data L (n) regarding the length of the pit in the longitudinal direction, and the modulated output signal is generated by the clock signal synchronized with V in the linear velocity information supplied from the clock synchronization means 14. It is supplied to the blanking electrode 9 as L (t), and ON / OFF control of the electron beam is performed. This modulation output signal L (t) is a modulation signal for the ON / OFF time of electron beam irradiation when recording the corresponding pit.

[0038]

Further, the coordinate conversion section 19 includes the data modulation section 1
Data θ (n) regarding the angle of the pits with respect to the array direction is coordinate-converted with reference to two mutually orthogonal deflection axes x and y corresponding to the high-speed deflection electrodes 11 and 12, and the corresponding deflection displacement data is obtained. X (n) and Y (n) are output to the storage means 15 (memory 1) and the storage means 16 (memory 2), respectively.

[0039]

Storage means 15 (memory 1) and storage means 1
6 (memory 2) stores deflection displacement data X (n),
Y (n) is stored in the high-speed deflection electrodes 11 and 12 as deflection output signals X (t) and Y (t) by a clock signal synchronized with V in accordance with the linear velocity information supplied from the clock synchronization means 14. It is supplied and the electron beam is deflected in each axial direction. These deflection output signals represent the electron beam spot when recording the corresponding pits on the recording surface 1.
This is a signal for displacing on a.

[0040]

The optical disk information recording apparatus according to one embodiment of the present invention is constructed as described above, and has a rotating recording surface 1.
A pit is formed by the irradiation trajectory of the beam spot irradiated on a.

The recording system control circuit 10 synchronizes with the linear velocity information supplied from the feed rotation control circuit 13 and the information data supplied for recording on the master, and the modulated output signal L.
(T) and the deflection output signals X (t) and Y (t) are supplied to the blanking electrode 9 and the high-speed deflection electrodes 11 and 12, respectively, to control the irradiation position of the beam spot on the recording surface 1a, A pit corresponding to the information data is formed on the recording surface 1a by the irradiation trajectory drawn by.

[0042]

Next, by using the information recording apparatus for the optical disc in one embodiment of the present invention, the pits are spirally arranged on the recording surface of the rotating master, and the longitudinal direction of each pit is the pit arrangement direction. The method of recording at various angles will be described in detail below. FIG. 3 is a diagram showing a recording position and a shape of a pit to be recorded on the recording surface. As shown in FIG. 3A, the pit has a longitudinal length d and an angle with respect to the arrangement direction. It is assumed that the beam spot is irradiated along the shape represented by the θ deviation, and the beam spot forms a recording locus having a width equal to the width of the pit on the recording surface.

[0043]

Further, FIG. 3 (b) shows that the master is rotated and
FIG. 9A is a diagram showing a moving state after a lapse of time t ₀ when the recording surface showing the recording position and the shape of the pit of FIG.

As can be seen from the figure, the recording positions and shapes of the pits in FIG. 3A are such that the beam spot from the position A to the position B is recorded on the recording surface which is moving during the time t ₀ at the time t.
By irradiating while displacing by ₀ (= d / V), pits are recorded in the shape shown in FIG.

[0045]

Therefore, in FIG. 3B, the x-axis of the deflection axis of the electron beam is arranged in the moving direction of the recording surface, that is, the pit arrangement direction, and the beam spot is dsin θ in the x-axis direction and in the y-axis direction. It can be seen that irradiation may be performed for the time t ₀ while displacing d (1-cos θ). Therefore, the modulated output signal L (t) output in this case has an ON / OFF time of electron beam irradiation t ₀ (= d / V)
The output should be as follows.

[0046]

FIG. 4 shows the shape of pits when the pits are continuously recorded in various directions in this way.
Each deflection output signal X (t), Y (t) and modulation output signal L
It is shown in comparison with (t). As can be seen from the figure, ON / OFF of the irradiation of the beam spot is switched by a modulation signal according to the length of the pit in the longitudinal direction and the linear velocity V of the recording surface, and the recording position of the beam spot is deflected by each deflection axis. By moving with a displacement amount corresponding to the direction, it is possible to freely change and record the length of the pits in the longitudinal direction and the deflection angle with respect to the arrangement direction.

[0047]

In this embodiment, the electron beam irradiator 5 is used.
The pit was formed by irradiating the recording surface of the master with an electron beam in the vacuum chamber 4 by using the laser. As shown in FIG. Deflector 22, mirror 23, objective lens 24
The pits may be recorded by spot-irradiating the laser beam on the recording surface by the laser irradiator 25 provided with.

[0048]

In this case, the modulator 21 is the laser generator 2
Recording system control circuit 1
0 is supplied to the two-dimensional deflector 22 according to the modulation output signal L (t), and the two-dimensional deflector 22 supplies the deflection output signals X (t), Y (t) supplied from the recording system control circuit 10. )
In accordance with the above, the displacement of the laser beam spot irradiated on the recording surface is controlled while deflecting the laser beam. The two-dimensional deflector is a commonly used A / O deflector (or E / O deflector).
Two O deflectors are used with their deflection directions orthogonal to each other.

[0049]

[0038]

[0050]

Since the present invention is configured as described above, a two-dimensional deflector for displacing the recording beam of the information recording apparatus in two axes is used, and the deflection amount and the deflection speed of the deflector are independently controlled in two axes. In addition, by synchronizing with the modulation signal of the information data to be recorded and the rotation speed of the master, it is possible to record the information pits on the master by changing the deflection angle in the longitudinal direction of each pit with respect to the recording pit row. A pit having a plurality of information parameters can be recorded on the master disc of the optical disc.

[Brief description of drawings]

FIG. 1 is a block diagram showing a schematic configuration of an information recording apparatus for an optical disc in an embodiment of the present invention.

FIG. 2 is a block diagram showing a main configuration of a recording system control circuit included in an optical disc information recording apparatus according to an embodiment of the present invention.

FIG. 3 is a diagram showing a recording position and a shape on a recording surface of a pit to be recorded on a master disc by using the optical disc information recording device in the embodiment of the present invention.

FIG. 4 shows the shape of a pit in the case where pits are continuously recorded in various directions on a recording surface of a master using an information recording apparatus for an optical disc according to an embodiment of the present invention. This is expressed in comparison with the modulated output signal.

FIG. 5 is a block diagram showing a schematic configuration of an information recording apparatus for an optical disc according to another embodiment of the present invention.

FIG. 6 is a diagram showing a structure of a conventional optical disc.

FIG. 7 shows a method for detecting a pit, which is performed by utilizing the fact that the polarization characteristic of reflected light changes depending on the shape of a surface-deformed portion (for example, pit), corresponding to the shape of the pit.

[Explanation of symbols]

 1 master disk 1a recording surface 2 spindle motor 3 feeding mechanism 4 vacuum chamber 5 electron beam irradiator 6・ ・ ・ ・ Electron gun 7 ・ ・ ・ Aperture 8 ・ ・ ・ Objective lens 9 ・ ・ ・ Blanking electrode 10 ・ ・ ・ ・ Recording system control circuit 11 ・ ・ ・ ・ ・ ・ High-speed deflection electrode 12 ・ ・.. High-speed deflection electrode 13 ... Feed rotation control circuit 14 ... Clock synchronization means 15 ... Storage means 16 ... Storage means 17 ... Storage means 18 ... Data modulation Part 19 ... Coordinate converter 20 ... Laser generator 21 ... Modulator 22 ... Two-dimensional deflector 23 ... Mirror 24 ... Objective lens 25 ...・ Laser beam irradiator 25 26 ・ ・ ・ ・ Radius sensor

[Procedure amendment]

[Submission date] February 18, 1997

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Detailed description of the invention

[Correction method] Change

[Correction contents]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disk information recording apparatus and information recording method.

[0002]

2. Description of the Related Art Conventionally, as shown in FIG. 6, an optical disk 92 represented by a compact disk (CD) and a laser disk (LD) is known. In this optical disc, music information and video information are recorded after being converted into a signal having the pit length as a parameter, and each information pit 91 has a constant width on the information recording surface 95 and has a long length. The information tracks are formed by arranging the directions along the spiral or concentric circles with respect to the center of the disc.

In these optical disks 92, information pits are recorded on a master disk, a disk stamper is formed from the recorded master disk, and a synthetic resin or the like is heat-pressed or injection-molded by using the obtained disk stamper to form the pits 91. After the metal deposition process is performed on the recording layer 94 formed by being transferred from the master, the translucent substrate 93 and the like are formed and formed.
The recording of the information pits on the master is performed by an information recording device, and while the recording surface of the master is rotated, the irradiation spot of the recording beam can be made almost uniform by sending a header for irradiating a recording beam such as a laser beam in a radial direction as appropriate. Control so as to draw a spiral or concentric track locus at equal pitches, and turn the laser light ON / OFF according to the rotation speed of the recording master and the information content on that locus to make an information pit on the master. Was recorded.

During reproduction of the optical disc 92, the information pit 91 is irradiated with laser light of a pickup so as to form a beam spot having a predetermined diameter, and the optical disc is rotated at a predetermined speed to scan the information pit 91. , The diffracted and reflected light from the pit to be scanned is detected by a photodetector composed of a photodiode and output as an electric signal, and the music information and video information recorded from the electric signal are recorded in the opposite manner from those at the time of recording. It was extracted by performing signal conversion.

The conventional optical disc is configured as described above, and the information recorded by the recording device is reproduced by using the reproducing device. However, only the length of the pit carried by the disc is the parameter of the recorded information. Therefore, there is a limit in information recording density.

In recent years, in an optical disk carrying information pits arranged spirally or concentrically, the information recording density of the disk is made such that the pit shape not only extends in the length direction along the track but also two-dimensionally. Studies have been conducted to reproduce more information by increasing.

This is a method for detecting pits by utilizing the fact that the polarization characteristics of the reflected light change depending on the shape of the surface-deformed portion (for example, pits). If this method is used, it is about the same as the wavelength or When a reading laser beam is applied to a diffraction grating having the following period, the reflected light changes the light amounts of two polarization components, p-polarized light and s-polarized light, which are orthogonal to each other due to the groove shape. Can be regarded as a two-dimensional loop array, and each pit can carry more information by having a different shape for each pit and detecting the shape of the pit by the polarization characteristic of the reflected light.

FIG. 7 shows an example thereof, in which the information pits arranged spirally or concentrically on the optical disk have the same shape in width, height and length, and the longitudinal directions of the pits are three directions. That is, with respect to the direction along the spiral or the concentric circle, the same direction and the direction of +45 degrees and -45 degrees.
When three kinds of pits are mixedly arranged so as to be in either direction of degrees, when a light beam of circularly polarized laser light is incident on these information pits, the polarization state of the obtained reflected light is p- When expressed by the light amount distribution in the s-polarization axis coordinate system, the same direction as the pit scanning direction and +45
It becomes an ellipse having a major axis in the direction of degrees and the direction of -45 degrees.

Further, on the surface of the optical disc where the information pits are not recorded, the reflected light is reflected as circularly polarized light and its light amount distribution becomes circular. The signals obtained by these reflected lights are the signals Sp and s due to the p polarized light. It is represented by a coordinate system using the signal Ss by polarization, but if digital conversion is performed at each predetermined threshold value of Sp and Ss, four types of digital outputs can be obtained in a disc using pits of the same shape.

Therefore, if these pits are formed on the optical disk, it is possible to have not only information parameters in the longitudinal direction of the pits, but also more information parameters depending on the deviation angle in the longitudinal direction. Compared with, the information density of the disc can be dramatically increased.

However, when these information pits are recorded on the master, it is necessary to record them while swinging each pit at a corresponding angle with respect to the scanning direction, and the recording method by the conventional recording device described above should be used. I can't
The recording method was not established.

[0012]

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide an optical disk information recording apparatus capable of high density recording and an information recording method therefor.

[0013]

According to the first aspect of the present invention,
An information recording apparatus for an optical disc, which is formed by arranging a plurality of pits carrying information on a recording surface of a recording medium,
A rotating means for rotating a recording surface of a recording medium, a rotating means for rotating the recording surface at a predetermined speed around the rotating shaft, and a recording beam irradiating means for irradiating a recording area with a recording beam. A deflection means for deflecting the irradiation direction of the recording beam in a predetermined direction, a moving means for relatively moving the recording beam irradiation means and the rotating means along a recording surface rotated by the rotating means, and a rotating means. A rotation control unit that controls the rotation speed, a detection unit that detects the irradiation position of the recording beam on the recording surface, a movement control unit that controls the movement amount of the movement unit according to the detection result of the detection unit, and a rotation unit Control means for turning on / off the irradiation of the recording beam of the recording beam irradiation means and controlling the irradiation direction of the recording beam deflected by the deflecting means according to the rotation speed. That.

According to a second aspect of the invention, in the optical disc information recording apparatus according to the first aspect, the recording beam emitted by the recording beam irradiating means is constituted by a laser beam.

According to a third aspect of the present invention, in the optical disc information recording apparatus according to the first aspect, the recording beam emitted by the recording beam irradiating means is composed of an electron beam.

According to a fourth aspect of the present invention, there is provided an optical disc information recording apparatus according to the first, second or third aspect,
The deflection means is characterized in that the recording beam can be deflected by two deflection axes orthogonal to each other.

According to a fifth aspect of the present invention, there is provided an information recording method for an optical disc, wherein a plurality of pits carrying information are arranged on the recording surface of the recording medium to form the information recording method. The recording surface of the recording medium is rotated. Rotating means having a rotation axis for rotating the recording surface at a predetermined speed around the rotation axis, recording beam irradiating means having a recording beam for irradiating the recording surface in a fine area, and irradiation direction of the recording beam Deflection means for deflecting in a predetermined direction, moving means for relatively moving the recording beam irradiation means and the rotation means along a recording surface rotated by the rotation means, and rotation control means for controlling the rotation speed of the rotation means. The rotation control means uses the rotation control means to detect the irradiation position of the recording beam on the recording surface and the movement control means to control the movement amount of the movement means according to the detection result of the detection means. And the amount of movement of the moving means are controlled by the movement control means, and the irradiation of the recording beam of the recording beam irradiating means is turned ON / OFF and the deflecting means deflects according to the rotating speed of the rotating means. It is characterized in that the irradiation direction of the recording beam is controlled.

According to a sixth aspect of the present invention, in the information recording method of the optical disc according to the fifth aspect, the recording beam emitted by the recording beam irradiating means is composed of laser light.
The pit is characterized in that it is formed in a region on the recording surface of the recording medium which is irradiated with the laser beam.

According to a seventh aspect of the invention, in the information recording method of the optical disc according to the fifth aspect, the beam irradiated by the recording beam irradiation means is composed of an electron beam, and the pit is irradiated with the electron beam. It is characterized in that it is formed in an area on the recording surface of the recording medium.

The invention according to claim 8 is the information recording method for an optical disc according to claim 5, 6 or 7,
The deflection means is configured to be capable of deflecting the recording beam by two deflection axes which are orthogonal to each other, and the pits are formed on the recording surface by controlling the drive of the recording beam corresponding to the two deflection axes. Is characterized by.

[0021]

Since the present invention is configured as described above, a two-dimensional deflector for displacing the recording beam of the information recording device in two axes is used, and the deflection amount and the deflection speed of the deflector are controlled independently in two axes.
In addition, by synchronizing with the modulation signal of the information data to be recorded and the rotation speed of the master, it is possible to record the information pits on the master by changing the deflection angle in the longitudinal direction of each pit with respect to the recording pit row. A pit having a plurality of information parameters can be recorded on the master disc of the optical disc.

[0022]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, an embodiment of an information recording apparatus and an information recording method for an optical disc according to the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a schematic configuration of an optical disc information recording apparatus according to an embodiment of the present invention. In the figure, reference numeral 1 denotes a master used for forming an optical disc, which is installed on a rotary shaft (not shown) of the spindle motor 2 and is configured to be rotatable integrally with the rotary shaft. Also,
The spindle motor 2 is attached to the feed mechanism 3 and is configured to move the recording surface 1a of the master 1 in the horizontal direction (arrow A). The feed mechanism 3 is installed in the vacuum chamber 4 together with the master disk 1 and the spindle motor 2, and the recording surface 1a
An electron beam irradiator 5 is provided vertically above, and is installed in the vacuum chamber 4 with a predetermined distance from the recording surface 1a. Electron gun 6 of electron beam irradiator 5
The electron beam is emitted from the device, passes through the opening of the aperture 7, and then is incident on the recording surface 1a by the objective lens 8 to form a beam spot for irradiation in a minute area on the recording surface 1a. .

A blanking electrode 9 is provided in the path of the electron beam emitted by the electron gun 6, and the blanking electrode 9 is emitted according to the output of the modulation output signal L (t) from the recording system control circuit 10. A switch is configured to turn on / off the irradiation of the electron beam on the recording surface 1a by making the path of the electron beam go straight or bent, and passing or blocking the electron beam at the opening of the aperture 7.

Further, high-speed deflection electrodes 11 and 12 are provided in the path of the electron beam emitted by the electron gun 6. The high-speed deflection electrodes 11 and 12 are composed of electrodes that are orthogonal to each other, and are provided so that the emitted electron beams can be independently deflected in two axial directions that are orthogonal to each other in a plane parallel to the recording surface 1a, and each recording is performed. A deflection unit that deflects the emitted electron beam in each axial direction according to the deflection output signals X (t) and Y (t) output from the system control circuit 10 is configured.

A feed rotation control circuit 13 has a predetermined linear velocity information V, a predetermined track pitch information P, and
The rotation speed (V / 2πR) of the spindle motor 2 and the feed speed (PV / 2πR) of the feed mechanism 3 are controlled by the recording radius R detected by the radius sensor 26, and the spindle motor 2 rotates in a pair with the rotation shaft. By moving the recording surface 1a of the master 1 in the horizontal direction (arrow A), spiral recording is performed on the rotating recording surface 1a by the beam spot irradiated on the recording surface 1a described above. The feed rotation control circuit 13 further outputs the linear velocity information V to the recording system control circuit 10.
Output to

FIG. 2 is a block diagram showing the main structure of the recording system control circuit 10. In the figure, the recording system control circuit 10 is provided with a clock synchronization means 14, generates a synchronization clock, and outputs the pit length information of the sequentially supplied information data to the linear velocity supplied from the rotation control circuit 13 at the same time. The data is supplied to the storage unit 15 (memory 1), the storage unit 16 (memory 2), and the storage unit 17 (memory 3) in synchronization with the information V.

Further, in the recording system control circuit 10, the data modulating section 18 extracts the data L (n) and the data L (n) concerning the length in the longitudinal direction from the pit information sequentially supplied as the information data among the information parameters of the pits. Data about the angle of the pits with respect to the arrangement direction θ (n)
Are modulated and output to the storage unit 17 (memory 3) and the coordinate conversion unit 19, respectively.

Further, the storage means 17 stores data L (n) regarding the length of the pit in the longitudinal direction, and the modulated output signal is generated by the clock signal synchronized with V in the linear velocity information supplied from the clock synchronization means 14. It is supplied to the blanking electrode 9 as L (t), and ON / OFF control of the electron beam is performed. This modulation output signal L (t) is a modulation signal for the ON / OFF time of electron beam irradiation when recording the corresponding pit.

Further, the coordinate conversion section 19 includes the data modulation section 1
Data θ (n) regarding the angle of the pits with respect to the array direction is coordinate-converted with reference to two mutually orthogonal deflection axes x and y corresponding to the high-speed deflection electrodes 11 and 12, and the corresponding deflection displacement data is obtained. X (n) and Y (n) are output to the storage means 15 (memory 1) and the storage means 16 (memory 2), respectively.

Storage means 15 (memory 1) and storage means 1
6 (memory 2) stores deflection displacement data X (n),
Y (n) is stored in the high-speed deflection electrodes 11 and 12 as deflection output signals X (t) and Y (t) by a clock signal synchronized with V in accordance with the linear velocity information supplied from the clock synchronization means 14. It is supplied and the electron beam is deflected in each axial direction. These deflection output signals represent the electron beam spot when recording the corresponding pits on the recording surface 1.
This is a signal for displacing on a.

The optical disk information recording apparatus according to one embodiment of the present invention is constructed as described above, and has a rotating recording surface 1.
A pit is formed by the irradiation trajectory of the beam spot irradiated on a. The recording system control circuit 10 synchronizes with the linear velocity information supplied from the feed rotation control circuit 13 and the information data supplied for recording on the master, the modulation output signal L (t) and the deflection output signal X ( t) and Y (t) are supplied to the blanking electrode 9 and the high-speed deflection electrodes 11 and 12, respectively, and the irradiation position of the beam spot on the recording surface 1a is controlled. The pits corresponding to the information data are formed in the.

Next, by using the information recording apparatus for the optical disc in one embodiment of the present invention, the pits are spirally arranged on the recording surface of the rotating master, and the longitudinal direction of each pit is the pit arrangement direction. The method of recording at various angles will be described in detail below. FIG. 3 is a diagram showing a recording position and a shape of a pit to be recorded on the recording surface. As shown in FIG. 3A, the pit has a longitudinal length d and an angle with respect to the arrangement direction. It is assumed that the beam spot is irradiated along the shape represented by the θ deviation, and the beam spot forms a recording locus having a width equal to the width of the pit on the recording surface.

Further, FIG. 3 (b) shows that the master is rotated and
FIG. 9 is a diagram showing a moving state after a lapse of time t ₀ when the recording surface showing the recording position and the shape of the pit in (a) moves at a linear velocity V. As can be seen from FIG.
Recording the position and shape of the pits (a) has, on a recording surface of moving during the time t _0, is irradiated while displacing only a beam spot time t _{0 (=} d / V) from the position A to the position B As a result, the pits are recorded in the shape shown in FIG.

Therefore, in FIG. 3B, the x-axis of the deflection axis of the electron beam is arranged in the moving direction of the recording surface, that is, the pit arrangement direction, and the beam spot is dsin θ in the x-axis direction and in the y-axis direction. It can be seen that it is sufficient to irradiate for the time t ₀ while displacing d (1-cos θ). Therefore, the modulated output signal L (t) output in this case is the ON / OFF time of the electron beam irradiation t ₀ (= d / v)
The output should be as follows.

FIG. 4 shows the shape of pits when the pits are continuously recorded in various directions in this way.
Each deflection output signal X (t), Y (t) and modulation output signal L
It is shown in comparison with (t). As can be seen from the figure, ON / OFF of the irradiation of the beam spot is switched by a modulation signal according to the length of the pit in the longitudinal direction and the linear velocity V of the recording surface, and the recording position of the beam spot is deflected by each deflection axis. By moving with a displacement amount corresponding to the direction, the length of the bit in the longitudinal direction and the deflection angle with respect to the arrangement direction can be freely changed and recorded.

In this embodiment, the electron beam irradiator 5 is used.
It is configured to form a bit by irradiating an electron beam on the recording surface of the master in the vacuum chamber 4 by using a laser generator 20, a modulator 21, a two-dimensional shape, as shown in FIG. Deflector 22, mirror 23, objective lens 24
The pits may be recorded by spot-irradiating the laser beam on the recording surface by the laser irradiator 25 provided with.

In this case, the modulator 21 is the laser generator 2
Recording system control circuit 1
0 is supplied to the two-dimensional deflector 22 according to the modulation output signal L (t), and the two-dimensional deflector 22 supplies the deflection output signals X (t), Y (t) supplied from the recording system control circuit 10. )
In accordance with the above, the displacement of the laser beam spot irradiated on the recording surface is controlled while deflecting the laser beam. The two-dimensional deflector is a commonly used A / O deflector (or E / O deflector).
Two O deflectors are used with their deflection directions orthogonal to each other.

[0038]

Since the present invention is configured as described above, a two-dimensional deflector for displacing the recording beam of the information recording apparatus in two axes is used, and the deflection amount and the deflection speed of the deflector are independently controlled in two axes. In addition, by synchronizing with the modulation signal of the information data to be recorded and the rotation speed of the master, it is possible to record the information pits on the master by changing the deflection angle in the longitudinal direction of each pit with respect to the recording pit row. A pit having a plurality of information parameters can be recorded on the master disc of the optical disc.

Claims (8)

[Claims] 1. An information recording apparatus for an optical disc, wherein a plurality of pits carrying information are arranged on a recording surface of a recording medium to be formed, the information recording apparatus having an axis of rotation for rotating the recording surface of the recording medium. Rotating means for rotating the recording surface at a predetermined speed around the rotation axis, recording beam irradiating means having a recording beam for irradiating the recording surface in a fine region, and irradiating the recording beam in a predetermined direction. A deflection means for deflecting the recording beam irradiation means, a moving means for relatively moving the recording beam irradiating means and the rotating means along the recording surface rotated by the rotating means, and a rotating means for controlling a rotation speed of the rotating means. Control means, detection means for detecting the irradiation position of the recording beam on the recording surface, and movement control means for controlling the movement amount of the movement means according to the detection result of the detection means An optical disc comprising: a control means for turning on / off the irradiation of the recording beam by the recording beam irradiation means and controlling an irradiation direction of the recording beam deflected by the deflecting means according to a rotation speed of the rotating means. Information recording device. 2. The information recording apparatus for an optical disc according to claim 1, wherein the recording beam emitted by the recording beam irradiating means is composed of a laser beam. 3. The optical disk information recording apparatus according to claim 1, wherein the recording beam emitted by the recording beam irradiating means is composed of an electron beam. 4. The information recording apparatus for an optical disk according to claim 1, wherein the deflecting means is capable of deflecting the recording beam by two deflection axes which are orthogonal to each other. 5. An information recording method for an optical disc, wherein a plurality of pits carrying information are arranged on a recording surface of a recording medium to form the information recording method, the method having a rotating shaft for rotating the recording surface of the recording medium, Rotating means for rotating the recording surface at a predetermined speed around the rotation axis, recording beam irradiating means having a recording beam for irradiating the recording surface in a fine region, and irradiating the recording beam in a predetermined direction. A deflection means for deflecting the recording beam irradiation means, a moving means for relatively moving the recording beam irradiation means and the rotating means along the recording surface rotated by the rotating means, and a rotation control for controlling a rotation speed of the rotating means. Means, detection means for detecting the irradiation position of the recording beam on the recording surface, and movement control means for controlling the movement amount of the movement means according to the detection result of the detection means. By using the rotation control means to control the rotation speed of the rotation means and the movement control means to control the movement amount of the movement means, respectively, the rotation amount of the recording beam irradiation means is controlled according to the rotation speed of the rotation means. ON / O of irradiation of the recording beam
An information recording method for an optical disc, characterized in that the irradiation direction of the recording beam deflected by the deflection means and deflected by the deflection means is controlled. 6. The recording beam emitted by the recording beam irradiating means is composed of a laser beam, and the pit is formed in an area on the recording surface of the recording medium irradiated with the laser beam. The method for recording information on an optical disc according to claim 5. 7. The beam irradiated by the recording beam irradiation means is composed of an electron beam, and the pit is formed in an area on the recording surface of the recording medium irradiated with the electron beam. The method for recording information on an optical disc according to claim 5. 8. The deflection means is configured to be capable of deflecting the recording beam by two deflection axes orthogonal to each other,
8. The information recording on the optical disc according to claim 5, wherein the pits are formed on the recording surface by driving and controlling the recording beam corresponding to the two deflection axes, respectively. Method.