JPH07105563A - Optical disk and optical disk device - Google Patents

Abstract

PURPOSE:To rapidly find an optical recording power value with one time of trial writing by previously recording the power value of a laser beam used for recording and erasing of data and a fluctuation quantity of a recording mark part and non-recording mark part with a fluctuation in the power of the laser beam. CONSTITUTION:A magneto-optical disk 1 is mounted at the device and the device is operated. The power control value of the laser beam for recording and erasing of the data recorded by the laser beam 5 and the fluctuation quantity of the recording mark are read out and these values are stored in a CPU 3. A head 8 is then moved to a condition setting track and the recording region is erased by the laser beam power of the power control value for erasing of the read out data. Recording is executed at the frequency at which the fluctuation quantity is determined by the power control value used for recording of the read out data. The recording is reproduced with a reproducing circuit 7 and the two of the recording mark time and the un-recording mark time are integrated in a time measuring section 10. The optimum power value is determined by prescribed equation from the respective integrated values and the fluctuation-component.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disc and an optical disc device.

[0002]

2. Description of the Related Art Currently, optical recording is performed by utilizing the thermal property of a laser beam. The recording medium (optical disc) is a write-once type optical disc (perforated type) that can be recorded only once, for example, an optical disc having a thin metal film or a cermet film as a recording layer, and recording, reproduction and erasing can be repeated repeatedly. There are optical discs, for example, magneto-optical discs having a magnetic layer as a recording layer, and phase-change optical discs having a recording layer of a metal film or a cermet film that changes phase between a crystalline phase and an amorphous phase.

Tracks for recording information are formed on the optical disk in a spiral or concentric shape. Tens of thousands of tracks are formed with one track as one track. Two types of information units (recently called marks) corresponding to 0 and 1 are formed on this track.
Information is recorded. In fact, the track itself (that is,
The first information unit corresponding to one of 0 or 1 is formed on the track, and the second information unit corresponding to the other of 0 or 1 is formed in dots or islands on the track. in this case,
The presence or absence of marks, the distance between marks, the length of marks, the mark formation start position (that is, the front edge position of the mark), the mark formation end position (that is, the rear edge position of the mark), and the like represent information.

Further, for recording / reproducing of a magneto-optical disk, recording / reproducing is performed by irradiating a laser beam emitted from a laser to about 1 μm and irradiating it on the surface of a perpendicularly magnetized film. Recording is performed by a method called Curie point writing. The laser light is emitted while the intensity is modulated by the information to be recorded. The portion hit by the light spot (laser light) is heated to a temperature above the Curie point (the temperature at which the material used for the optical disc can be made). The temperature of the recording film exceeds (increases) the Curie point.
Then, the recording film in that portion becomes non-magnetic. When irradiating with laser light, heating is performed while applying a magnetic field to the outside. When the optical disk rotates and moves out of the position of the light spot, the temperature of the recording film decreases. When the temperature of the recording film decreases, the recording film is magnetized in the direction of the external magnetic field applied when the temperature further decreases below the Curie point. Recording is performed by changing the direction of magnetization in this way.

Regeneration is carried out by utilizing the Kerr effect. When the recording part is irradiated with a linearly polarized light spot, the polarization direction of the light spot changes depending on the direction of the magnetization of the recording film.Therefore, the change in the polarization direction is converted into intensity modulation using an analyzer and reproduced as a reproduction signal. To detect. If the power of laser light is not recorded on the optical disk at the optimum power for recording data, the size of the mark may be increased or decreased, and accurate data recording may not be possible. Further, the optimum laser beam power varies depending on the optical disc. Therefore, in the conventional optical disc, the power value of the laser beam used for recording and erasing data is recorded in advance.
When such an optical disc is mounted in the optical disc device and started up, the optical disc device reads the power value of the laser beam used for recording and erasing prerecorded data. Then, the power of the laser beam for recording and erasing is controlled based on the recorded value.

[0006]

However, in the above-mentioned optical disc, the state of the optical disc changes with the aging of the recording characteristics due to the fine dust adhering to the entire surface of the optical disc or the storage environment of the optical disc. The optimum power value of the laser light for recording changes according to the change of the state of the optical disk. Therefore, there is a problem that when the state of the optical disc changes, the optical disc cannot be recorded with the optimum laser beam power. That is, the power of the laser light of the optical disk device is determined by the value recorded in advance on the optical disk, and the power of the laser light according to the state of the optical disk at the time of use cannot be recorded, so that the recording cannot be performed accurately.

Further, in an optical disk apparatus configured to optimally record and erase the power of laser light for trial recording at the time of starting the optical disk, the optimum recording power value is found in the optical disk apparatus. Since recording and erasing were repeated several times, there was a problem that it took too long before the user could use it.

The present invention has been made in view of the above problems, and even if the optimum power value of a laser beam used for recording data on an optical disk changes due to aging or the like,
An object of the present invention is to provide an optical disk capable of obtaining an optimum power value of laser light of the optical disk in a short time, and an optical disk device capable of recording data with the optimum power of laser light.

[0009]

As a result of earnest research, the inventor of the present invention recorded a variation amount of a recording mark with respect to a variation of a power value of a laser beam on an optical disc, thereby making it possible to obtain a laser beam according to the state of the optical disc in a short time. I realized that I was able to find the optimum power value for light. In view of this, the present invention firstly provides an optical disc as an "optical disc in which a power control value of a laser beam for recording data or erasing recorded data is recorded, in which a recording mark for a change amount of the power of the laser beam is recorded. The amount of fluctuation is recorded ”(Claim 1).

Secondly, the optical disk is preferably composed of "the optical disk is recorded with the power control values for the inner and outer circumferences of the optical disk and the variation of the recording mark" (claim) 2). Thirdly, an optical disc device is used for "recording and erasing recorded on the optical disc at the time of starting the optical disc in an optical disc device for recording, reproducing and erasing data using the optical disc according to claim 1 or 2. Read-out means for reading out the power control value of the laser beam, recording means for recording the recording data of a single frequency on the condition-determining track based on the power control value, and measuring the size of each of recorded marks and unrecorded marks And a power value of the laser beam for optimally recording on the optical disc from the difference between the respective sizes measured by the measuring unit and the variation of the recording marks recorded in advance on the optical disc. And a power value determining means ”(claim 3).

[0011]

As described above, the recording on the optical disk consists of two types of information units, the first and second information units. In the present invention, the first information unit (for example, information of 0) is called an unrecorded mark (part), and the second information unit (for example, information of 1) is called a recording mark (part). The recording mark variation amount is a variation amount of the difference between the size of the recording mark and the erase mark with respect to the variation amount of the power of the recording laser beam.

By simultaneously recording the power value of the laser light used for recording and erasing the data of the optical disk and the fluctuation amount of the laser light of the recorded mark portion and the unrecorded mark portion with respect to the power fluctuation, one trial is performed. When writing, the size (time difference) between recorded and unrecorded marks can be measured at the time of reproduction, and the size (time difference) can be read in advance to obtain the optimum recording power value from the recorded mark fluctuation amount. This allows the optimum recording power value to be found.

Hereinafter, the present invention will be described in more detail with reference to Examples, but the present invention is not limited thereto.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In the magneto-optical disk according to the first embodiment of the present invention, the power control value of the laser light for recording data is set to 5 mW on the inner circumference and 8 mW on the outer circumference, and the laser light for erasing the data is The power control values were 6 mW on the inner circumference and 9 mW on the outer circumference, and the recording mark fluctuation amounts were 2 nS /% on the inner circumference and 2.5 nS /% on the outer circumference.

These values were recorded on information tracks (for example, inner and outer tracks) which the user of the optical disk does not record. The place where these values are recorded is not limited to the information track as described above, but this is preferable when reading these with laser light.
For the power control value of the laser light for recording and erasing, before shipping the disc to the user, the power value of the laser light for optimally recording and erasing data on the disc is measured in advance on the inner and outer circumferences. Then, the value is recorded.

The recording mark fluctuation amount is, for example, 10 from the power value of the laser beam used for optimum recording before shipment.
% The data of the laser beam is changed to record the data on the optical disc, and the marks of the recorded mark part and the unrecorded mark part are formed when the data is recorded at the frequency used by the user to record the data, for example, a single frequency of 5 MHz. The recorded time (size) is measured, and the recorded mark portion time _Ta , the unrecorded mark portion time _Tb, and the variation D (here, the variation D is 10 because the power variation of the laser beam is 10%). The value obtained by the following equation (1) is recorded.

[0017]

## EQU1 ## | T _a −T _b | / D (1) This equation defines the change in the size (time) of the mark formed with respect to the fluctuation of the power of the laser beam. And each disk has its own characteristic.

In the first embodiment, the change in size between the recorded mark and the unrecorded mark is measured with time. However, this is because the magneto-optical disk is rotated and one mark is This is because the size is measured from the time it takes to pass a certain point. Further, any method may be used as long as the sizes of the recorded mark and the unrecorded mark can be measured.

The first embodiment has been described using the magneto-optical disk, but the same can be applied to other optical disks. 1 is a schematic configuration diagram of a magneto-optical disk device according to a second embodiment of the present invention. FIG. 1 shows a magneto-optical disk device for recording, reproducing and erasing data using the magneto-optical disk of the present invention, and its operation will be described below.

First, the magneto-optical disk 1 is mounted on a motor 2 for rotating the disk by a loading mechanism (not shown). After that, the motor 2 is controlled by the CPU 3 so as to rotate the magneto-optical disk at a specified rotation speed. When the magneto-optical disk reaches the specified rotation speed, the CPU3
Command, the laser 4 is turned on by the laser drive circuit 9 with reproduction power.

After that, the servo control unit 6 controls the laser beam 5 so that the laser beam 5 focuses and tracks the track of the magneto-optical disk.
Controlled by. When the track number on the disk can be read by the reproducing circuit 7, the CPU 3
In response to this command, the servo control unit 6 moves the head 8 to move the laser beam 5 to the information track on the inner circumference where the power control value of the laser beam for recording and erasing and the recording mark variation amount are recorded.

When the movement is completed, the reproducing circuit 7 reads the power control value of the laser beam for recording and erasing data and the recording mark variation amount, and the CPU 3 stores the values. After that, the laser light 5 is moved to the condition setting track on the inner circumference of the magneto-optical disk by the same means, and after the movement is completed, the laser light power of the power control value for erasing the inner circumference data read out above is used. A command is sent from the CPU 3 to the laser drive circuit 9 to erase the recording area, and the recording area is erased. Next, the recording area of the track erased by the laser light power of the power control value used for recording the read inner circumference data is set to the frequency of 5 which is the variation of the disk.
The CPU 3 commands the servo controller 6 and the laser drive circuit 9 to perform the recording operation at MHz.

After the recording is completed, the recorded data is reproduced by the reproducing circuit 7, and the recorded mark time and the unrecorded mark time are measured by the time measuring section 10. The time measuring unit 10 is composed of a general counter circuit, and integrates two times of the recorded mark portion and the unrecorded portion, and calculates the average of each time from the number of the captured mark portion and the unrecorded mark portion. It is configured to output the values T _a1 and T _b1 to the CPU 3.

The CPU 3 corrects and stores the optimum recording power value for the inner circumference based on the output from the measuring section and the read recording mark variation amount. The optimum recording power value is calculated by the following equation (2).

[0025]

(Equation 2) (optimal power value) = (power control value) × (1-100 × (T _a1 −T _b1 ) / D) (2) If the user stores data after that, here Therefore, the optimum recording power value can be obtained in a short time even if the recording characteristics of the disc change due to aging or the like.

As for the outer circumference, an optimum power value is obtained by using the same method as that for the inner circumference, and therefore the explanation is omitted. Further, the optimum power values other than the inner circumference and the outer circumference can be obtained by linear approximation using the radial position as a function based on the optimum power values obtained at the inner circumference and the outer circumference.

[0027]

As described above, according to the present invention, not only the power control value of the laser beam for recording and erasing data but also the recording mark variation amount information is recorded on the disc in advance. In addition to being able to sufficiently correct the recording characteristics that have changed due to dust on the disc, aging, etc., the optimum power value for recording becomes important when the recording capacity will increase in the future, and the present invention is important. It is fully possible to play a role.

Further, the present invention can be used to correct the power (intensity) change of laser light to an appropriate power.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of a magneto-optical disk device according to a second embodiment of the present invention.

[Explanation of symbols]

 1 ... Magneto-optical disk 2 ... Motor 3 ... CPU 4 ... Laser 5 ... Laser light 6 ... Servo control unit 7 ... Reproducing circuit 8 ... Head 9 ... Laser drive circuit 10 ... Time measurement unit

Claims (3)

[Claims] 1. An optical disc in which a power control value of a laser beam for recording data or erasing recorded data is recorded, and a variation amount of a recording mark with respect to a variation amount of the laser beam power is recorded. An optical disc characterized in that 2. The optical disc according to claim 1, wherein the power control values for the inner and outer peripheries of the optical disc and the variation of the recording mark are recorded on the optical disc. 3. An optical disk device for recording, reproducing and erasing data using the optical disk according to claim 1, wherein a laser beam used for recording and erasing recorded on the optical disk at the time of starting the optical disk. Reading means for reading the power control value of the recording medium, recording means for recording the recording data of a single frequency on the condition determining track based on the power control value, and measurement for measuring the size of each of the recorded mark and the unrecorded mark. Means, and a power value that determines the power value of the laser beam for optimum recording on the optical disc from the difference between the respective sizes measured by the measuring means and the variation amount of the recording marks recorded in advance on the optical disc. An optical disk device comprising a determining means.