JP4545986B2 - Optical disc master creation apparatus and optical disc master creation method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical disc master creation apparatus and an optical disc master creation method, and more particularly to an optical disc master creation device and an optical disc master creation method for recording predetermined information by irradiating an optical disc master with a laser beam.
[0002]
[Prior art]
In general, information recording methods for producing an optical disc master include a CAV (Constant Angular Velocity) method with a constant angular velocity and a CLV method with a constant linear velocity. In the CAV method, cutting is performed while rotating an optical disk master at a constant angular velocity. On the other hand, in the CLV method, in order to make the linear velocity constant, cutting is performed while controlling the rotation so that the master of the optical disk has a rotational speed proportional to the radius. Current optical disks, such as CD (Compact Disk), MD (Mini Disk), DVD (Digital Versatile Disk), and future new format (Blue-disc), are recorded on the master by the CLV method. .
[0003]
An optical disk master producing apparatus using the CLV method will be described. FIG. 9 is a block diagram of a conventional optical disc master producing apparatus.
The optical disk master creating apparatus includes an EFM signal sending apparatus 400 that reads information on the master optical disk 300 and generates an EFM signal, and a laser beam that performs cutting by controlling the laser light applied to the glass master 530 according to the EFM signal. And a recorder 500.
[0004]
The EFM signal transmission apparatus 400 reads information data recorded on the master optical disc 300 into the CPU 420 by the reading drive 410. The CPU 420 performs necessary signal processing and sends the modulated signal to the EFM output circuit 430. The EFM output circuit 430 outputs an EFM signal to the laser beam recorder 500 in synchronization with the clock supplied by the reference channel clock 440.
[0005]
The laser beam recorder 500 performs electro-optical conversion on the EFM signal input by the EL conversion 510. The signal pattern converted into light is output from the laser 520, and the signal pattern is recorded on the glass master 530 in CLV. In order to record with CLV, the motor 540 needs to be rotationally controlled from the radial position of the laser 520, and the control block 550 controls the rotation of the motor 540 along with the feed control of the laser 520.
[0006]
[Problems to be solved by the invention]
However, the conventional optical disk master producing apparatus that performs CLV recording has a problem that the structure of the laser beam recorder becomes complicated in order to increase the accuracy of rotation control.
[0007]
In conventional CLV recording, the control block 550 controls rotation by the motor 540 in order to keep the linear velocity of the glass master 530 constant. FIG. 10 is a diagram showing the relationship between the conventional CLV EFM signal and the number of rotations of the master.
[0008]
As shown in the figure, in the recording by CLV, the signal pattern has a constant frequency, and the rotational speed is decreased from the inner periphery to the outer periphery according to the radius. In the case of CD 1 × speed, the number of rotations is about 600 rpm at the maximum in the inner periphery (diameter 50 mm) and about 200 rpm at the minimum in the outer periphery (diameter 116 mm).
[0009]
However, in order to increase the accuracy of the rotation control, the structure of the laser beam recorder 500 is complicated such that a circuit for that purpose is added or a motor with a better response than the rotation inertia of the glass master 530 is required. Was the cause. In addition, the cost required for this has become enormous.
[0010]
In addition, when the rotational speed is sequentially decreased from the inner periphery toward the outer periphery in the rotation control, there is a problem that a resonance point is generated.
The present invention has been made in view of these points, and an object of the present invention is to provide an optical disc master creation apparatus and an optical disc master creation method that can perform recording control with a simple configuration and high accuracy.
[0011]
[Means for Solving the Problems]
In the present invention, in order to solve the above-mentioned problem, an optical disc master producing apparatus for recording predetermined information by irradiating an optical disc master with laser light. , Place Is a master that records certain information data? Place Modulation means for reading a predetermined information data and generating a recording modulation signal; ,Record Recording modulation signal The Modulation signal output means for outputting a generated signal generated according to the channel clock; ,light Move in the radial direction of the master disc , According to generated signal The Laser light On the surface of the optical disc master Irradiation Do Head and , A recording means comprising a motor for rotating the optical disc master, and , F Feed control When, Optical disc master Constant rotation speed Rotation control to rotate with ,light To the radial direction of the master disc Ruhe Record position And Necessary for rotating the optical disc master. Tamo Recording control means for generating position information having a tacho pulse obtained by measuring the number of rotation pulses of the motor; Head Recording position and Head Depending on recording position Tachi Conversion information in association with frequency setting information for setting the frequency of the channel clock; , Ta Copulse And ta Copulse Based on the rotation speed of the optical disc master According Head recording position Corresponding to the correction value of Attached With tacho pulse radius conversion information ,Record Recording control means The place Position information , Ta Refer to copulse radius conversion information. T According to copulse The recording position of the head Calculate the correction value The With correction value Set the recording position of the head Correct , Supplement Corrected Head recording position According to Corresponds to the frequency of the channel clock Frequency setting information Is obtained by referring to the conversion information, and Channel clock Generation Channel clock Generation And an optical disc master creating apparatus.
[0012]
In the optical disk master producing apparatus having such a configuration, the modulation means reads the information data from the master on which the predetermined information data is recorded, generates a recording modulation signal from the read information data, and outputs it to the modulation signal output means. . Modulation signal output means The A recording modulation signal is output in accordance with the channel clock. The output signal is output to the recording means as a generation signal for generating 1/0 based on the channel clock and the recording modulation signal. In accordance with the recording control means, the recording means records the information data by causing the motor to rotate the optical disk master and the head to irradiate the optical disk master surface with laser light according to the generated signal. At this time, the recording control means performs feed control for controlling the position of the head and also records the head in the radial direction of the optical disk master. And Generating position information having a tachometer pulse that measures the number of rotation pulses of the motor required to rotate the optical disc master, Channel clock generation Send to means. Also, the optical disc master Constant rotation speed Rotation control is performed to control the motor to rotate at. Channel clock generation Means Head Recording position and Head Conversion information that associates frequency setting information for setting the frequency of the channel clock according to the recording position, tacho pulse, and tacho pulse Based on the rotation speed of the optical disc master According Head recording position Corresponding to the correction value of Attached And tacho pulse radius conversion information. Then, the position information is obtained from the recording control means, and the tacho pulse radius conversion information is referred to. , Ta According to copulse The recording position of the head Calculate the correction value The With correction value Set the recording position of the head to correct. further , Supplement Corrected Head recording position According to Frequency setting information corresponding to the channel clock frequency The See conversion information Acquired, Of the frequency A channel clock is generated and supplied to the modulation signal output means.
[0013]
In order to solve the above problems, Execute the same processing procedure as each processing means of the above optical disk master production apparatus An optical disc master creation method is provided.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. The embodiments described below are preferable specific examples of the present invention, and thus various technically preferable limitations are given. However, the scope of the present invention is not particularly limited in the following description. As long as it is not limited to these forms.
[0016]
FIG. 1 is a configuration diagram of an optical disc master creating apparatus according to an embodiment of the present invention. This is an example of creating a master CD for EFM modulation.
An optical disc master producing apparatus according to the present invention reads an information data recorded on a master optical disc 300 and sends an EFM signal (8-14 modulation signal, Eight to Fourteen modulation code), and an EFM signal. And a laser beam recorder 200 for recording information data on an optical disc master.
[0017]
The EFM signal transmission apparatus 100 includes a reading drive 110 that acquires information data from a master optical disc 300, a CPU 120 that is a modulation unit that generates a recording modulation signal, an EFM output circuit 130 that is a modulation signal output unit that outputs a generation signal, and a generation It comprises channel clock generation means 140 for generating a channel clock for outputting a signal. The laser beam recorder 200 includes: an EL conversion 210 that converts an EFM signal into an optical signal; a head 220 that emits laser light; a glass master 230 that is an optical disk master; a motor 240 that rotates the glass master 230; The control block 250 is a recording control unit that controls the rotation of the glass master 230 and generates position information related to the position of the head 220.
[0018]
The reading drive 110 sequentially reproduces predetermined information data recorded on the master optical disc 300 over the entire area and sends it to the CPU 120. The master optical disk 300 is a master medium (information source) such as a CD-R, on which predetermined information data to be recorded on the glass master 230 is recorded. The predetermined information data is arbitrary information data such as music data, video data, or a program.
[0019]
The CPU 120 reads out the modulation processing program and performs EFM modulation signal processing on the information data reproduced by the reading drive 110 in accordance with the modulation processing program. An EFM modulation signal data stream (hereinafter referred to as a data stream) generated by the modulation signal processing is output to the EFM output circuit 130.
[0020]
The EFM output circuit 130 generates an EFM signal by outputting a data stream output from the CPU 120 at a predetermined clock. The EFM signal is a signal that generates 1/0 of the data stream according to the channel clock. The EFM signal is sent to the laser beam recorder 200.
[0021]
The channel clock generation unit 140 acquires position information indicating the position of the head 220 from the control block 250, sets the frequency of the channel clock based on the position information, generates a channel clock based on the setting, and generates an EFM output circuit. To 130.
[0022]
The EL converter 210 converts an EFM signal, which is an electrical signal, into an optical signal and outputs it to a laser mounted on the head 220.
The head 220 moves in the radial direction of the glass master 230 according to the control block 250 and irradiates the surface of the glass master 230 with laser light based on the optical signal input from the EL conversion 210 from the mounted laser.
[0023]
The motor 240 operates according to the control block 250 so that the glass master 230 rotates at a constant rotational speed.
The control block 250 performs feed control of the head 220 and rotation control of the glass master disk 230 by the motor 240. Further, radius information is generated as position information related to the position of the head 230 with respect to the radial direction of the glass master 230, and is sent to the channel clock generating means 140. Further, if necessary, in order to calculate the exact position of the head 220, a tacho pulse obtained by measuring the number of rotation pulses of the motor 240 required for the glass master 230 to rotate is acquired and sent to the channel clock generation means 140.
[0024]
The operation of the optical disc master producing apparatus having such a configuration and the optical disc master producing method will be described.
The read drive 110 of the EFM signal transmitting apparatus 100 reads information data to be recorded from the master optical disc 300 and sends it to the CPU 120. The CPU 120 modulates the information data into an EFM data stream and sends it to the EFM output circuit 130. The EFM output circuit 130 outputs an EFM data stream in accordance with the channel clock supplied by the channel clock generation unit 140 and outputs the EFM data stream to the laser beam recorder 200 as an EFM signal. The EL conversion 210 of the laser beam recorder 200 converts the EFM signal into an optical signal. The control block 250 controls the motor 240 to perform rotation control so that the glass master 230 rotates at a constant rotation speed, and performs feed control of the head 220. The head 220 irradiates the glass master 230 with laser light according to the optical signal, and records information data on the surface of the glass master 230. At this time, the control block 250 sends radius information indicating the position of the head 220 in the radial direction of the glass master 230 and, if necessary, a tacho pulse as position information of the head 220 to the channel clock generator 140.
[0025]
The channel clock generation means 140 acquires radius information and, if necessary, an tacho pulse, calculates an accurate position in the radial direction of the glass master 230 on which recording is performed (hereinafter referred to as a recording radius), and performs recording. Generate a channel clock according to the radius. For example, when performing CLV recording, the recording radius of the glass master 230 is calculated and proportional to the recording radius. T Increase the frequency of the channel clock.
[0026]
The recording radius and the frequency of the channel clock will be described with reference to the drawings. FIG. 2 is a diagram showing the relationship between the CLV EFM signal and the number of revolutions of the master disk in the optical disk master production apparatus according to one embodiment of the present invention. As can be seen from the figure, the optical disk master production apparatus of the present invention keeps the rotational speed constant and increases the frequency of the signal pattern from the inner periphery to the outer periphery according to the radius. That is, it is proportional to the recording radius of the glass master 230. T Increase the frequency of the channel clock. For example, when recording a CD at 1 × speed, if the reference channel clock in the innermost periphery is 4.3218 MHz, the radius ratio between the outermost periphery and the innermost periphery is 2.32 times (the outermost periphery radius is 116 mm). Therefore, the channel clock at the outermost peripheral portion is 10.065 Mhz. The signal pattern of the glass master 230 created in this way is the same as the signal pattern recorded by the conventional CLV method shown in FIG.
[0027]
Thus, according to the present invention, CLV recording can be performed at a constant rotation speed of the glass master (CAV method). For this reason, the control block only needs to control the motor so as to maintain a constant rotation, and there is no need to provide a complicated rotation control mechanism. In general, frequency control using only an electric system is simpler and less expensive than rotation control including a mechanical system. Thus, by simplifying the rotation control, the price of the laser beam recorder can be reduced. Furthermore, a conventional laser beam recorder can be applied as it is.
[0028]
Further, when the optical disk master producing apparatus of the present invention is operated at the rotational speed at the innermost peripheral portion of the conventional CLV method, cutting can be performed ((n + 1) / 2) times faster than the conventional one. Here, n is a radius ratio between the inner periphery and the outer periphery. Thus, even when a conventional laser beam recorder is applied, the cutting time can be shortened, so that the efficiency of creating an optical disc master can be increased.
[0029]
Of course, CAV recording can also be performed using the optical disk master production apparatus of the present invention. Furthermore, it is possible to easily create a partial CAV optical disc master.
[0030]
Next, details of the channel clock generation means will be described. FIG. 3 is a configuration diagram of a first configuration example of the channel clock generation means in the optical disc master producing apparatus according to the embodiment of the present invention.
[0031]
The channel clock generation means 140a according to the present invention obtains radius information and converts it into a radius information conversion 1410 which is a radius frequency conversion means for converting it into a voltage value corresponding to the frequency of the channel clock, and a D / It comprises an A conversion 1420 and a VCO 1430 that generates a clock according to the voltage.
[0032]
The radius information conversion 1410 has conversion information in which a voltage value necessary for generating a channel clock frequency corresponding to the recording radius is registered corresponding to the recording radius, and is acquired from the laser beam recorder 200. The voltage value corresponding to the radius information is output. The voltage value is sent to the D / A conversion 1420.
[0033]
The D / A converter 1420 converts a digitally input voltage value into an analog voltage value and sends it to the VCO 1430.
The VCO 1430 oscillates a clock having a frequency corresponding to the voltage. As a result, a channel clock having a frequency corresponding to the recording radius is output.
[0034]
In the channel clock generation unit 140a having such a configuration, the radius information conversion 1410 receives the radius information from the laser beam recorder 200, and acquires a voltage value corresponding to the recording radius of the glass master 230 based on the conversion information. The voltage value is sent to the D / A converter 1420 and converted into an analog voltage value. The VCO 1430 generates a channel clock having a frequency corresponding to the voltage, that is, the recording radius, and supplies the channel clock to the EFM output circuit 130.
[0035]
Next, a configuration for obtaining a more accurate recording radius will be described. FIG. 4 is a block diagram of a second configuration example of the channel clock generation means according to the present invention. The same parts as those in FIG.
[0036]
The channel clock generation means 140b according to the present invention has the configuration of the channel clock generation means 140a of FIG. 3 further, a tacho pulse radius information conversion 1440 for converting a tacho pulse into a radius information correction value, and a VCO linear correction for correcting the VCO. 1450 has been added.
[0037]
The tacho pulse radius information conversion 1440 has tacho pulse radius conversion information that associates the tacho pulse with the correction value of the radius information corresponding to the tacho pulse, calculates the correction value according to the tacho pulse acquired from the recording control means 250, Send to radius information conversion 1410. Depending on the laser beam recorder 200, the radius information may not be updated at any time (for example, the radius information is updated every 10 tracks). For such radius information, correction according to the information from the tacho pulse is performed. Need to do. The VCO linear correction 1450 performs correction when the relationship between the voltage output from the VCO 1430 and the oscillation frequency is not linear.
[0038]
In such a channel clock generation unit 140b, the tacho pulse radius information conversion 1440 acquires the tacho pulse, calculates a correction value of the radius information, and sends the correction value to the radius information conversion 1410. The radius information conversion 1410 acquires radius information and a correction value, corrects the radius information, and then acquires a voltage value corresponding to the recording radius based on the conversion information. The voltage value is corrected by the VCO linear correction 1450 and then converted to an analog voltage by the D / A conversion 1420. The VCO 1430 generates a channel clock having a frequency corresponding to the voltage, that is, the recording radius, and supplies the channel clock to the EFM output circuit 130.
[0039]
Next, a configuration in which the VCO 1430 is converted into a digital synthesizer will be described. FIG. 5 is a block diagram of a third configuration example of the channel clock generation means according to the present invention. The same components as those in FIGS. 3 and 4 are denoted by the same reference numerals, and description thereof is omitted.
[0040]
The channel clock generation unit 140c according to the present invention replaces the VCO linear correction 1450, the D / A conversion 1420, and the VCO 1430 of the channel clock generation unit 140b of FIG. 4 with a digital synthesizer 1460. Here, the radius information conversion 1410 directly outputs the frequency of the channel clock instead of the voltage value as an output.
[0041]
The digital synthesizer 1460 receives the frequency of the output channel clock and outputs a channel clock having a set frequency. The digital synthesizer 1460 does not require correction.
[0042]
Next, a configuration when the frequency of the channel clock is widened will be described. FIG. 6 is a block diagram of a fourth configuration example of the channel clock generation means according to the present invention. The same parts as those in FIG.
[0043]
The channel clock generation unit 140d according to the present invention replaces the digital synthesizer 1460 of the channel clock generation unit 140c of FIG. 5 with a digital synthesizer A (1461), a digital synthesizer B (1462), and a synthesis 1463 that synthesizes output signals. ing.
[0044]
The digital synthesizer A (1461) and the digital synthesizer B (1462) have different oscillating frequency bands, and the synthesizing unit 1463 selects the channel clock from the side suitable for the frequency of the channel clock according to the radius information. Is output.
[0045]
Next, another configuration for widening the frequency of the channel clock will be described. FIG. 7 is a block diagram of a fifth configuration example of the channel clock generation means according to the present invention. The same parts as those in FIG.
[0046]
The channel clock generating unit 140e according to the present invention converts the frequency output from the digital synthesizer 1460 of the channel clock generating unit 140c of FIG.
[0047]
The PLL 1470 includes a phase comparator 1471, a low-pass filter 1472, a VCO 1473, and a frequency divider 1474.
For example, when a higher frequency than the oscillation frequency of the digital synthesizer 1460 is required, the VCO 1473 selects one that oscillates at a higher frequency. The output of the VCO 1473 is divided by a frequency divider 1474, and the phase comparator 1471 matches the phase with the digital synthesizer 1460, thereby generating a channel clock having a desired frequency.
[0048]
Next, a configuration for obtaining a channel clock having a desired frequency by changing the VCO frequency division ratio will be described. FIG. 8 is a block diagram of a sixth configuration example of the channel clock generation means according to the present invention. The same parts as those in FIG.
[0049]
The channel clock generation unit 140f according to the present invention replaces the digital synthesizer 1460 of the channel clock generation unit 140c of FIG.
[0050]
The PLL 1480 includes a phase comparator 1481, a reference clock 1482, a low-pass filter 1483, a VCO 1484, and a frequency divider 1485.
Here, the radius information conversion 1410 outputs a frequency division ratio for obtaining the frequency of the channel clock corresponding to the radius information.
[0051]
The radius information conversion 1410 sets the frequency division ratio so that the frequency division ratio of the frequency divider 1485 decreases as the radius information recording radius increases. The output of the VCO 1484 is divided by a frequency divider 1485 to generate a channel clock having a desired frequency.
[0052]
【The invention's effect】
As described above, the optical disk master production apparatus of the present invention converts information data read from the master into a recording modulation signal and generates a generation signal according to the channel clock. The optical disc master is controlled to rotate at a constant rotational speed, and recording is performed by irradiating a laser beam in accordance with a generated signal from a head moving on the optical disc master. A channel clock for determining the generated signal is generated at a frequency corresponding to the position of the head.
[0053]
In this way, by generating a channel clock having a frequency according to the position of the head and changing the generated signal, it is possible to perform CLV cutting with a constant rotational speed of the optical disc master, for example, a constant linear speed. Since the CLV cutting is not performed by rotation control including a mechanical system but by electrical frequency control, a simple and inexpensive optical disk master production apparatus can be provided.
[0054]
Further, since the frequency control of the channel clock is performed according to the rotation speed of the optical disc master, it is possible to easily perform the cutting with the increased number of rotations and to shorten the cutting time.
[0055]
Further, in the optical disk master production method of the present invention, a recording modulation signal is generated from information data acquired from the master. A predetermined channel clock is generated, and a recording modulation signal is generated according to the predetermined channel clock. Recording on the optical disc master is performed by rotating the optical disc master at a constant rotational speed and irradiating the surface of the optical disc with a laser beam corresponding to the generated signal. Position information relating to the position of the head at this time is generated, and a frequency of a predetermined channel clock is set based on the position information. The frequency of the channel clock is changed based on the setting.
[0056]
Thus, the frequency of the channel clock is set according to the position of the head, and a suitable generation signal is output according to this, so that the rotation speed of the optical disc master is constant, for example, CLV cutting with constant linear speed. Can be performed. Further, since the frequency control of the channel clock is performed according to the rotation speed of the optical disc master, it is possible to easily perform the cutting with the increased number of rotations and to shorten the cutting time.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of an optical disc master creating apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram showing a relationship between a CLV EFM signal and the number of rotations of the master in the optical disk master creating apparatus according to an embodiment of the present invention.
FIG. 3 is a block diagram of a first configuration example of channel clock generation means in the optical disk master production apparatus according to an embodiment of the present invention.
FIG. 4 is a block diagram of a second configuration example of the channel clock generation means according to the present invention.
FIG. 5 is a block diagram of a third configuration example of the channel clock generation means according to the present invention.
FIG. 6 is a block diagram of a fourth configuration example of the channel clock generation means according to the present invention.
FIG. 7 is a configuration diagram of a fifth configuration example of the channel clock generation means according to the invention.
FIG. 8 is a configuration diagram of a sixth configuration example of the channel clock generation means according to the invention.
FIG. 9 is a configuration diagram of a conventional optical disc master creating apparatus.
FIG. 10 is a diagram showing a relationship between a conventional CLV EFM signal and the number of rotations of a master.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 100 ... EFM signal transmission apparatus, 110 ... Reading drive, 120 ... CPU, 130 ... EFM output circuit, 140 ... Variable channel clock generation means, 200 ... Laser beam recorder, 210 ... EL conversion, 220 ... head, 230 ... glass master, 240 ... motor, 250 ... control block

Claims (5)

In an optical disc master producing apparatus that records predetermined information by irradiating an optical disc master with a laser beam,
Modulation means for reading the predetermined information data from a master on which the predetermined information data is recorded and generating a recording modulation signal;
A modulation signal output means for outputting the generated signal to generate the recording modulation signal according Ji Yan'nerukurokku,
A head for irradiating moved radially of the optical disc master, the laser beam in response to the generated signal to the optical disc master surface, a recording unit and a motor for rotating the optical disc master,
A feed control of the head, performs a rotation control for rotating the optical disc master at a constant rotational speed, the motor taken and recorded position location of said head with respect to the radial direction of the optical disc master, in order to rotate the optical disc master Recording control means for generating position information having a tacho pulse obtained by measuring the number of rotation pulses of;
A conversion information associating the frequency setting information for setting the frequency of the switch Yan'nerukurokku corresponding to the recording position of the recording position of the head head, according to the rotation speed of the optical disc master, based on the tachometer pulse and the tachometer and a tacho pulse radius conversion information was correlated with the correction value of the recording position of the head, obtains the positional information from said recording controlling means, depending on the prior northern Koparusu by referring to the tachometer pulse radius conversion information and calculates a correction value of the recording position of the head, the correction value to correct the recording position of the head, the frequency setting information corresponding to the frequency of the channel clock corresponding to the recording position of the head correct complement, the conversion information And a channel clock generating means for generating a channel clock of the frequency, referring to
An optical disc master producing apparatus characterized by comprising: The channel clock generating means has conversion information for increasing the frequency of the channel clock in proportion to the radius of the optical disc master when recording the optical disc master with a constant linear velocity (CLV) method. 2. The optical disc master producing apparatus according to claim 1, wherein: Said channel clock generating unit converts the recording position of the head to a voltage value corresponding to the channel clock frequency, and the previous SL D / A converter for generating a voltage corresponding to the voltage value, the clock in response to the voltage oscillating a VCO (Voltage Control oscillator) and optical disc mastering apparatus according to claim 1, wherein Rukoto to have a. Said channel clock generating means calculates a frequency of the channel clock corresponding to the recording position of the head, according to claim 1, characterized in that the digital synthesizer to generate a frequency of the channel clock issued calculated Optical disc master creation device. In a method of creating an optical disc master that records predetermined information by irradiating the optical disc master with a laser beam,
An optical disc master producing apparatus having a head that moves in the radial direction of the optical disc master and irradiates the laser beam, and a motor that rotates the optical disc master,
Reading the predetermined information data from the master on which the predetermined information data is recorded to generate a recording modulation signal,
The recorded modulation signal and outputs the generated signal generated according Ji Yan'nerukurokku,
Rotation control for rotating the optical disc master at a constant rotation speed and feed control for moving the head, and irradiating the laser light on the surface of the optical disc according to the generated signal;
Generating location information with the recording position location of said head with respect to the radial direction of the optical disc master, and a tacho pulse to the number of rotation pulses of the motor required for rotating the optical disc master is measured,
A conversion information associating the frequency setting information for setting the frequency of the switch Yan'nerukurokku corresponding to the recording position of the recording position of the head head, according to the rotation speed of the optical disc master, based on the tachometer pulse and the tachometer having a tachometer pulse radius conversion information correlated with the correction value of the recording position of the head, it obtains the position information, the recording position of the head in accordance with the prior northern Koparusu by referring to the tachometer pulse radius conversion information acquisition of calculating a correction value, the correction value to correct the recording position of the head, the frequency setting information corresponding to the frequency of the channel clock corresponding to the recording position of the head correctly complement, referring to the conversion information And
Generating a channel clock of the frequency ;
A method for producing an optical disc master, comprising:

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