JPH09198660A - Optical disk device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To set a value M so as to prevent the advance of the deterioration of a laser diode by setting an optical recording power value M when a β value first obtained by a double speed is within a specified range during power correction and performing correction again by reducing a rotational linear speed to a constant speed when the β value is not within the range. SOLUTION: The rotational linear speed of an optical disk 1 is first set to a double speed and data is recorded in the test area of a power calibration area(PCA) by the recording power values of a plurality of levels. Then, the peak value A1 and the bottom value A2 of the reproducing signal of the recording data are detected and a β value is calculated based on (A1+A2)/(A1-A2)=β. A center value 4% is set as an optimal recording power M when a β value is 0 to 8% and when the β value is not within this range, the rotational linear speed is reduced to one speed and then a βvalue is similarly obtained again so as to set a value M. Thus, a value M for preventing the advance of the deterioration of a laser diode is set and a time for its setting processing is shortened.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a CD-R device,
The present invention relates to a data writing type optical disk device such as a CD-E device.

[0002]

2. Description of the Related Art A data writing type optical disk device (hereinafter, referred to as
In the case of simply writing “optical disk device”), setting the optimum recording power value of laser light (referred to as “optimum recording power value”) at the time of writing data to the optical disk is to improve data recording and reproduction quality. Important to maintain.

Conventionally, in the optical disk device, the optimum recording power value is set as described above based on the setting method in which the optimum power control (OPC) is specified as the power calibration in the orange book part 2. (For example, JP-A-7-12996
No. 1).

According to this method, when the recording power value (laser power) of the laser beam is changed step by step in a power calibration area (PCA) of the optical disk to record predetermined data and the data is reproduced. The peak value: A1 and the bottom value: A2 of the RF signal are detected, and β = (A1 + A2) / (A1 based on those values.
The recording power value when the β value obtained from −A2) is a predetermined value is set as the optimum recording power value. The predetermined value of the β value is defined as 0 to 8% in Orange Book.

[0005]

However, in the method of setting the optimum recording power value as described above, the optimum recording power value varies depending on the usage environment of the drive of the optical disk device, the type of the optical disk, and the like.

Particularly, when the temperature in the drive is low or the sensitivity of the optical disk is low, even if the recording power value is changed within a certain range to record predetermined data, the β value is predetermined due to insufficient recording power. In some cases, the allowable range may not be reached, and when recording data with the optimum recording power value, a high output recording power value is required for the laser diode (LD) that outputs laser light.

As described above, when the optimum recording power value exceeds the maximum allowable emission power of the laser diode or is set to a high output recording power value even if it is a value below the limit value, deterioration of the laser diode is caused. There has been a problem that the data cannot be recorded on the optical disc rapidly.

Further, if the power calibration is performed every time the recording of the data on the optical disk is interrupted, there is a problem that the power calibration takes time. Further, the power calibration area (PCA) of the optical disc is divided into a test area and a count area. The test area is an area for performing power calibration. The count area is an area indicating that the test area has been used, and is used to search for an unused test area.

Therefore, when the optimum recording power value cannot be calculated by performing the calibration at a certain line linear velocity, the data is recorded in the count area with the recording power value which cannot compensate the recording quality, and the power calibration is performed again. In addition, the data in the count area cannot be reproduced correctly, and power calibration is performed again in the recorded test area.
There is also the problem of overwriting.

The present invention has been made in view of the above points, and it is a first object of the present invention to set an optimum recording power value at the time of data recording with a recording power value which does not cause deterioration of a laser diode. To do. A second object is to be able to shorten the power calibration process of the optical disc. A third object is to prevent the power calibration from being performed again on the recorded test area.

[0011]

To achieve the above object, the present invention rotates an optical disc having a power calibration area at a predetermined rotational linear velocity to record and reproduce data in the recording area of the optical disc. In the optical disc device, data is recorded in the power calibration area with a plurality of levels of recording power values,
The peak value and the bottom value of the reproduced signal when the recorded data is reproduced is detected, the β value which is the signal ratio between the detected peak value and the bottom value is obtained, and the above-mentioned data is calculated based on the β value. Power calibration means for setting the optimum recording power value at the time of recording, and when the β value obtained by the means does not reach a predetermined allowable range, the power calibration means reduces the rotational linear velocity of the optical disk. And a means for performing power calibration again.

Further, the power calibration means may be means for setting the optimum recording power value to a recording power value obtained by linear approximation of the plurality of β values and their respective recording power values. Further, it is preferable to provide a means for recording the data of the used area of the power calibration area in the count area of the optical disc with the optimum recording power value set based on the β value that has reached the predetermined allowable range.

The optical disk device according to the present invention records data at a plurality of levels of recording power values in the power calibration area of the optical disk, and detects the peak value and the bottom value of the reproduction signal when the recorded data is reproduced. , The β value which is the signal ratio between the detected peak value and the bottom value is obtained, and the optimum recording power value at the time of recording the above data is set based on the β value, and the obtained β value is set to a predetermined value. When the allowable range is not reached, the rotational linear velocity of the optical disk is reduced and power calibration is performed again, so the optimum recording power value exceeds the maximum allowable emission power of the laser diode or is below the limit value. However, it is possible to prevent the recording power value from being set to a high output.

Further, if the optimum recording power value is set to a recording power value obtained by linear approximation of the plurality of β values and the respective recording power values, each time the recording of data on the optical disk is interrupted. The optimum recording power value can be set without performing power calibration.

Further, according to the optimum recording power value set on the basis of the β value which has reached the predetermined allowable range,
By recording the data of the used area of the power calibration area in the count area of the optical disc, the data of the count area can be correctly reproduced, and the power calibration can always be performed in the unused test area. it can.

[0016]

Embodiments of the present invention will be specifically described below with reference to the drawings. FIG. 2 is a diagram showing a schematic configuration of an optical disc device according to an embodiment of the present invention. This optical disk device includes a spindle motor 1 for rotating an optical disk 4 at a predetermined rotational linear velocity, an optical pickup 3 for mounting a laser diode (LD) and irradiating a recording area of the optical disk 4 with a laser beam L, and its optical pickup. There is provided a coarse movement motor 2 for moving the optical disc 3 in the radial direction of the optical disk 4 in cooperation with a seek motor provided therein.

A rotation control system 5 for controlling the rotation of the spindle motor 1, a coarse movement motor control system 6 for controlling the drive of the coarse movement motor 2, a pickup control system 7 for controlling the optical pickup 3, and an optical system. Also provided is a signal processing system 8 for transmitting and receiving a signal of data read by the pickup 3 and a signal of data to be written in the recording area of the optical disc 4, a drive controller 9 for performing the processing according to the present invention together with the control of the control system and the processing system. ing.

Further, the drive controller 9 is connected to the host computer via the external interface 10, and performs a process of sending the data read from the optical disk 4 to the host computer and receiving the data to be written on the optical disk 4 from the host computer.

Further, the optical disk 4 is connected to the spindle motor 1
Control for recording or reproducing data by rotating the optical pickup 3 in the radial direction of the optical disc 4 and rotating the optical pickup 3 to irradiate the recording area on the recording surface of the optical disc 4 with the laser light L from the laser diode of the optical pickup 3. Then, the setting process of the optimum recording laser power value by the power calibration according to the present invention is performed.

When recording data, this optical disc apparatus sets the optimum recording laser power value by performing power calibration using the power calibration area on the optical disc according to the present invention under the control of the drive controller 9. The optical pickup 3 irradiates the recording area (1) with the laser beam L at the optimum recording laser power value to record various data on the optical disc 4.

Further, at the time of reproducing information, the recording area of the optical disk 4 is irradiated with the laser light L at the reproduction laser power value by the control of the drive controller 9 and is recorded in the recording area based on the reflected light. Read and play the data that is stored.

That is, the drive controller 9 of this optical disk device records data with a plurality of levels of recording power values in the power calibration area of the optical disk by the optical pickup 3, and the signal processing system 8 reproduces the recorded data. At this time, the peak value and the bottom value of the reproduced signal are detected, the β value that is the signal ratio between the detected peak value and the bottom value is obtained, and the optimum recording power value at the time of recording the above data is calculated based on the β value. When the obtained β value does not reach the predetermined allowable range, the rotation control system 5 lowers the rotational linear velocity of the optical disk of the spindle motor 1 to perform the power calibration again. Fulfills the function of means.

It also functions as a means for setting the optimum recording power value to a recording power value obtained by linear approximation of a plurality of β values and their respective recording power values. Further, a function of a means for recording the data of the used area of the power calibration area in the count area of the optical disc by the optical pickup 3 by the optimum recording power value set on the basis of the β value that has reached the predetermined allowable range is provided. Fulfill

Next, the data format of the recording surface on the optical disk will be described. FIG. 3 is a diagram showing a format before data writing on the recording surface of an optical disc conforming to Orange Book Part 2, FIG. 4 is a diagram showing a format after the data writing is finished, and FIG. 5 is a detailed format of the power calibration area. FIG.

As shown in FIG. 3, an area on the recording surface of the optical disk where data can be actually written is an information area. When the data is completely written in the information area, it is formatted into a power calibration area (PCA), a program memory area (PMA), a lead-in area, a program area, and a lead-out area as shown in FIG.

The PMA is a temporary TOC information recording area at the time of intermediate recording in which additional recording is possible. The lead-in area and the lead-out area are areas for recording information on tracks on which data is recorded. The program area is an area for recording data.

The power calibration area is an area used when performing power calibration according to the present invention. As shown in FIG. 5, this power calibration area is composed of a test area for performing trial writing for setting an optimum recording power value prior to data recording and a count area for recording data indicating a used test area. Become.

In the format example shown in FIG. 5, the test area is divided into 100 partitions.
Use one partition for power calibration. The count area is also divided into 100 partitions, and every time one partition of the test area is used, data indicating that the test area is used is recorded in the corresponding partition of the count area. Then, this count area is used when searching for an unused partition in the test area.

In this format example, power calibration can be performed 100 times. Further, since the start position of 100 partition, the start position of count area, and the start position of PMA of the test area are searched, they are not used before and after the test area and after the count area.

Next, the processing at the time of recording data in this optical disk device will be described. FIG. 1 is a flowchart showing a process at the time of recording data in this optical disc device. This process is a step (indicated by "S" in the figure)
Set the linear speed of rotation of the optical disk to double speed with 1 and 2
Calibration is performed by rotating at a double rotational speed.

In the calibration, data is recorded in the test area of the power calibration area with a plurality of levels of recording power values in consideration of variations in the sensitivity of the optical disk, wavelength variations of the laser diode (LD), and the like. For example, in the case of an optical disc defined by Orange Book, there is a variation in sensitivity of 4 to 11 mW (double speed). Therefore, in consideration of wavelength variation and the like, there are 10 recording power values in a range of about 4 to 13 mW. Record the data.

Then, in step 2, the peak value and the bottom value of the reproduced signal when the recorded data is reproduced are detected, and the β value which is the signal ratio between the detected peak value and the bottom value is obtained. That is, the peak value: A1 and the bottom value: A2 of the RF signal when the data recorded in the power calibration area is reproduced are detected, and based on these values, β = (A1 + A2) / (A1-A2) is obtained. The calculated β value is calculated. Then, the recording power value when the β value is a predetermined value is provisionally set as the optimum recording power value.

Then, in step 3, it is judged whether or not the β value is within the range of 0 to 8%. According to the Orange Book, this is because the recording power value corresponding to the β value within the allowable range of 0 to 8% is the optimum recording power value.
This is to set the recording power value closest to% to the optimum recording power value.

If the β value is within the range of 0 to 8% in the judgment of step 3, the process proceeds to step 4, the recording power value corresponding to the β value is set as the optimum recording power value, and the process proceeds to step 5. Data is recorded in the program area or the like of the optical disc with the optimum recording power value, and this processing ends.

However, when the recording power value corresponding to the β value which does not reach the allowable range of 0 to 8% is set to the optimum recording power value, the maximum allowable emission power of the laser diode is exceeded or a value less than the limit value is set. However, the recording power value becomes high, and the deterioration of the laser diode rapidly progresses, making it impossible to record data on the optical disc.

Therefore, when the β value does not reach the predetermined allowable range in the determination in step 3, the process proceeds to step 6 and the linear velocity of rotation is reduced to 1 × speed to rotate the optical disc.
In step 7, another partition in the test area of the power calibration area is calibrated again to obtain the recording power value corresponding to the β value within the allowable range of 0 to 8%, and the process proceeds to step 4 to calibrate the 1 × speed. The recording power value obtained by the operation is set as the optimum recording power value, the process proceeds to step 5, and the data is recorded in the program area or the like of the optical disc with the optimum recording power value, and this process is ended.

In this way, it is possible to prevent the optimum recording power value from exceeding the maximum allowable emission power of the laser diode or being set to a high output recording power value even if it is below the limit value. You can

If the drive controller 9 sets the optimum recording power value to a recording power value obtained by linear approximation of a plurality of β values and their respective recording power values, the power calibration process is shortened. be able to.

FIG. 6 is a diagram showing the relationship between the β value obtained by calibration and the recording power value. This diagram shows each recording power value 6, 7, 8 mW set as OPC in the power calibration area (PCA) of the optical disc 4 and each β value calculated from the reproduction signal of the data calibrated at each recording power value. Shows the relationship with.

Based on the definition of the Orange Book, the optimum recording power value is preferably in the allowable range of β value of 0 to 8%, so that the recording power value with the central value β ₀ = 4% is the optimum recording power value. It is better to set the value to P ₀ . That is, A in the figure
A straight line based on each point of ₁ , A ₂ and A ₃ is obtained, and the recording power value of the point A ₄ corresponding to the center value β ₀ = 4 on the straight line is set as the optimum recording power value P ₀ .

In this way, the optimum recording power value can be set without performing power calibration every time the recording of data on the optical disc is interrupted, and power calibration can be performed in a short time. .

Further, the data of the used area of the power calibration area is recorded in the count area of the optical disk by the optimum recording power value set by the drive controller 9 based on the β value which has reached the predetermined allowable range. By doing so, it is possible to prevent double writing due to power calibration being performed again in the recorded test area.

FIG. 7 is a flowchart showing the processing in that case. In this process, in step (indicated by "S" in the figure) 11, the rotational linear velocity of the optical disc is set to double speed,
The calibration is performed by rotating at the double rotational speed.

In the calibration, data is recorded in the test area of the power calibration area with a plurality of levels of recording power values in consideration of variations in the sensitivity of the optical disc, fluctuations in the wavelength of the laser diode (LD), and the like. For example, in the case of an optical disc defined by Orange Book, there is a variation in sensitivity of 4 to 11 mW (double speed). Therefore, in consideration of wavelength variation and the like, there are 10 recording power values in a range of about 4 to 13 mW. Record the data.

After that, in step 12, the peak value and the bottom value of the reproduced signal when the recorded data is reproduced are detected, and the β value which is the signal ratio between the detected peak value and the bottom value is obtained. That is, the peak value: A1 and the bottom value: A2 of the RF signal when the data recorded in the power calibration area is reproduced are detected, and based on these values, β = (A1 + A2) / (A1-A2) is obtained. The calculated β value is calculated. Then, the recording power value when the β value is a predetermined value is provisionally set as the optimum recording power value.

Then, in step 13, it is judged whether or not the β value is within the range of 0 to 8%. According to the Orange Book, the recording power value corresponding to the β value within the allowable range of 0 to 8% is the optimum recording power value. Therefore, the recording power value closest to 4% of the center value is the optimum recording power value. This is because it is set to.

If the β value is within the range of 0 to 8% in the judgment of step 13, the process proceeds to step 14 and the recording power value corresponding to the β value is set as the optimum recording power value, and the process proceeds to step 15. Data indicating the used partition of the test area is recorded in the count area, the process proceeds to step 16, and the data is recorded in the program area or the like of the optical disc with the optimum recording power value, and this process is ended.

However, when the recording power value corresponding to the β value which does not reach the allowable range of 0 to 8% is set to the optimum recording power value, the maximum allowable emission power of the laser diode is exceeded, or the value is less than the limit value. However, the recording power value becomes high, and the deterioration of the laser diode rapidly progresses, making it impossible to record data on the optical disc.

Therefore, when the β value does not reach the predetermined allowable range in the determination in step 13, the process proceeds to step 17, the linear velocity is reduced to 1 × speed to rotate the optical disc, and in step 18, the power calibration area The calibration is performed again on the other partitions in the test area, the recording power value corresponding to the β value within the allowable range of 0 to 8% is obtained, and the process proceeds to step 14 to obtain the recording power value obtained by the 1 × speed calibration. Is set as the optimum recording power value.

Then, in step 15, the data indicating the used partition of the test area is recorded in the count area, and in step 16, the data is recorded in the program area of the optical disc at the optimum recording power value. This process ends.

In this way, since the data is recorded in the count area with the recording power value capable of compensating the recording quality,
During the power calibration, the data in the count area can be correctly reproduced, and the power calibration can always be performed in the unused test area. Therefore, it is possible to prevent double writing due to power calibration being performed again in the recorded test area.

[0052]

As described above, according to the optical disk device of the first aspect of the present invention, the optimum recording power value at the time of data recording can be set at the recording power value which does not cause the deterioration of the laser diode. . Claim 2
According to the optical disk device of (1), the power calibration process of the optical disk can be shortened. Further, according to the optical disk device of the third aspect, it is possible to prevent the power calibration from being performed again on the recorded test area.

[Brief description of drawings]

FIG. 1 is a flowchart showing a process at the time of recording data in an optical disc device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a schematic configuration of an optical disc device according to an embodiment of the present invention.

FIG. 3 is a diagram showing a format before writing data on a recording surface of an optical disc conforming to Orange Book Part 2.

4 is a diagram showing a format after data writing on the recording surface of the optical disc shown in FIG. 5 is completed.

5 is a diagram showing a detailed format of a power calibration area shown in FIG.

6 is a diagram showing the relationship between β value and recording power value obtained by calibration in the optical disk device shown in FIG.

FIG. 7 is a flowchart showing another data recording process in the optical disc device according to the embodiment of the present invention.

[Explanation of symbols]

 1: Spindle motor 2: Coarse movement motor 3: Optical pickup 4: Optical disk 5: Rotation control system 6: Coarse movement motor control system 7: Pickup control system 8: Signal processing system 9: Drive controller 10: External interface

Claims (3)

[Claims] 1. An optical disc apparatus for recording and reproducing data in a recording area of an optical disc by rotating an optical disc having a power calibration area at a predetermined rotational linear velocity, wherein a plurality of levels of recording power are recorded in the power calibration area. The data is recorded with a value, the peak value and the bottom value of the reproduction signal when the recorded data is reproduced are detected, and the β value that is the signal ratio between the detected peak value and the bottom value is obtained. power calibration means for setting an optimum recording power value at the time of recording the data based on the β value; and when the β value obtained by the means does not reach a predetermined allowable range, the power calibration means Equipped with means for reducing the linear velocity of rotation of the optical disk and performing power calibration again Optical disc apparatus characterized by. 2. The optical disk device according to claim 1, wherein the power calibration means sets the optimum recording power value to a recording power value obtained by linear approximation of the plurality of β values and their respective recording power values. An optical disk device comprising means. 3. The optical disc apparatus according to claim 1, wherein the power calibration area is used in a count area of the optical disc by an optimum recording power value set based on a β value that has reached the predetermined allowable range. An optical disk device comprising means for recording area data.