JPH09212866A - Power calibration method for write-once optical disk and optical disk recording and reproducing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power calibration method for write-once optical disk and a recording/reproducing device which can acquire the optimum recording laser power in consideration of the necessary conditions of the device constitution. SOLUTION: A storage part stores the laser power acquired when the trial writing is previously given to a prescribed write-once optical disk and the time width of 3T pits set when the optical disk undergone the optimum recording is reproduced. When the recording laser power optimization (OPC) is carried out to write the information into the optical disk in an information recording mode, a single partition of the test area of a power calibration area (PCA) is divided into the 1st to 4th areas ER1 to ER4 consisting of plural frames respectively, and a single trial writing operation is carried out in a single area. At the same time, the laser power and the recording pulse time width are corrected based on the value stored in the storage part.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power calibration method and an optical disc recording / reproducing apparatus for optimizing a recording laser power when recording information on a write-once optical disc.

[0002]

2. Description of the Related Art Conventionally, a write-once optical disc (CD-WO) has been used.
When recording information on the recording laser power optimization (OP
C: Optimun Power Control, hereinafter referred to as OPC). The OPC records predetermined information in a power calibration area (PCA: Power Calibration Area, hereinafter referred to as PCA) of the optical disc, and
This is done by reproducing the recorded information. P
The CA is divided into a test area and a count area, and each is divided into 100 partitions.

One partition in the test area is composed of 15 frames, and one partition is used in one trial writing. As an example of use, the Orange Book, which is the standard for write-once optical discs, was used for trial writing with 15 stages of laser power for 15 frames, and the laser power with the best recording condition was selected. The method of recording information is described.

According to the above-mentioned method, when the optimum laser power cannot be found by one trial writing when OPC is performed, or when it is desired to obtain a more appropriate laser power, the one-time trial writing is performed. It becomes necessary to perform trial writing on a plurality of partitions in PCA by OPC. However, according to the above-mentioned standard, the write-once optical disc can record up to 99 songs, so that the OPC must be performed up to 99 times to record the songs, which requires 99 partitions. . Further, in order to complete a compact disc (hereinafter referred to as a CD), it is necessary to record in the lead-in area and the lead-out area of the optical disc, and therefore, the remaining one partition is used as the OPC.

Therefore, since a maximum of 100 partitions are used to make a CD having 99 songs recorded, if a plurality of partitions are used in one OPC, 99 songs can be recorded. You will not be able to do it, and it will be against the standard.

Therefore, the applicant of the present invention has filed Japanese Patent Application No. 7-3405.
Japanese Patent Laid-Open No. 7-287847 proposes a method of using a power calibration area of a write-once optical disc that can obtain an optimum recording laser power in OPC performed using one partition of PCA.

This method will be described below. That is, as shown in FIG. 2, the PCA has 100 partitions P001 to
Each partition P001 to P100 is composed of 15 frames F01 to F15.

When obtaining the optimum recording laser power, P
When trial writing is performed on the CA, in the first embodiment, one partition is divided into first to third areas ER1 of 5 frames each.
~ Divide into ER3 and perform trial writing three times.

As write information for trial writing, a well-known EFM (Eight to Fourteen Modu) which is a pulse train having a time width 3 to 11 times the reference time width T is used.
lation) signal and the EFM signal is used to modulate the laser power for trial writing.

FIG. 3 is a schematic block diagram showing an optical disk recording / reproducing apparatus according to the present invention. In the figure, reference numeral 1 denotes an encoder, which converts information to be written into an EFM signal and outputs it. A recording control circuit 2 inputs an EFM signal and a control signal from a CPU described later, and outputs a drive control signal to the servo circuit 3 and the laser drive circuit 4. The servo circuit 3 sets the position of the optical pickup 5 and the position of the objective lens (not shown) to proper positions. The laser drive circuit 4 energizes a laser diode (not shown) in the optical pickup 5 based on the drive control signal input from the recording control circuit 2, and causes the laser diode to emit laser light to the optical disc 6.

Reference numeral 7 denotes an RF amplifier circuit, which inputs an RF signal corresponding to the reflected light from the optical disk 6 received by the optical pickup 5, amplifies the RF signal, and supplies it to a jitter detection circuit 8 and a β detection circuit 9. Output. Jitter detection circuit 8
Generates an EFM signal by binarizing the input RF signal, measures the time width of a pulse having a time width three times the reference time width T (hereinafter, referred to as 3T time width), and measures each measured time width. The time width data is output to the CPU 10. The β detection circuit 9 receives the peak value of the input RF signal, that is, the maximum value A
And the minimum value B are measured, and the β value calculated by the following equation (1) is output to the CPU 10.

Β = (A + B) / (A−B) (1) The CPU 10 collects the statistics of the 3T time width data input from the jitter detection circuit 8 and based on the statistical result, the time width of the writing EFM signal. The correction value is calculated, the optimum laser power is obtained based on the β value, and these data and a control signal for instructing the correction based on these data are output to the recording control circuit 2.

Next, the operation of the optical disk recording / reproducing apparatus having the above-mentioned structure will be described in detail with reference to the flowchart shown in FIG. At the start of writing information to the optical disc, OPC is performed. When performing OPC, C
The PU 10 sets the time width correction value of the writing EFM signal and the laser power to initial values (SA1). After this,
The PCA test area is searched (SA2), and one partition to be used is divided into first to third areas ER1 to ER3 of 5 frames as shown in FIG. 2 (SA).
3).

Next, the CPU 10 writes with the first laser power in the first frame of the first area ER1 (SA4). The laser power at this time is the minimum value of the five types of laser power corresponding to the five types of voltages obtained by dividing the minimum value and the maximum value of the voltage applied to the laser diode into five. After that, the laser power is set to different values in the second frame to the fifth frame of the first area ER1 and writing is performed (SA5 to SA
8).

After writing in all the frames of the first area ER1, the written information is reproduced (SA
9) Find the β value in each frame (SA10).
Based on these five β values, as shown in FIG. 5, the β values are interpolated to obtain the laser power at which β = a (the best value), that is, the voltage Vb applied to the laser diode (SA1
1).

Next, the CPU 10 instructs the recording control circuit 2 to set the laser power at which β = a, and writes to the second area ER2 by this laser power (SA12).
After that, the information written in the second area ER2 is reproduced (SA13), and one of the 5 frames, for example, 4
The jitter data at the frame, that is, the time width of a plurality of 3T pits is read (SA14).

Next, the average value of the time width of the read 3T pits is obtained (SA15). Here, as shown in FIG. 6, ± 118 ns is divided into four equal parts with the accurate 3T time width as the center, and the number of 3T pits included in each of these four regions is set to N _{1 to} N ₄ in each region. center value t ₁ ~t ₄ calculates the sum of the multiplied value by the average value t _m division to the time width by the number of all the 3T pit included this value into four regions of
Seeking. These are expressed by the following formula (2).

T _m = (t ₁ N ₁ + t ₂ N ₂ + t ₃ N ₃ + t ₄ N ₄ ) / (N ₁ + N ₂ + N ₃ + N ₄ ) ... (2) Due to the above, the initial correction amount in the time width is x ′. It was possible to find the deviation y'of the time width at the time. Further, it has been found from a preliminary experiment that the relationship between the correction amount x of the time width and the deviation y of the time width is expressed by a straight line having a constant inclination k in various optical disks. Therefore, as shown in FIG. 7, an optimum 3T value is obtained by obtaining an x value (correction value) when a straight line passing through (x ', y') with an inclination of k intersects with y = 0.
It is possible to obtain a correction value x of a time width capable of forming pits, that is, minimizing jitter (SA1
6).

The correction value x thus obtained is instructed from the CPU 10 to the recording control circuit 2 to correct the time width of the recording EFM signal (SA17).

Next, the CPU 10 writes with the first laser power in the first frame of the third area ER3 (SA18). The laser power at this time is the minimum value of the five types of laser power corresponding to the five types of voltages obtained by dividing the minimum value and the maximum value of the voltage applied to the laser diode into five, as described above. It After that, the laser power is set to different values in the second frame to the fifth frame of the third region ER3 and writing is performed (SA19 to SA22).

After writing in all the frames of the third area ER3, the written information is reproduced (SA
23), the β value in each frame is calculated (SA2
4). Based on these five β-values, the β-values are interpolated in the same manner as described above to obtain the laser power at which β = a (best value) (SA25), and the OPC is ended.

Next, the CPU 10 gives an instruction to the recording control circuit 2 about the optimum laser power obtained by OPC, and the information is written by this laser power (SA2).
6).

As described above, according to the first embodiment, P
When performing test writing on CA, one partition is divided into first to third regions ER1 to ER3 of 5 frames each, and test writing is performed three times to obtain the optimum recording laser power. 1 using one partition
The optimum recording laser power can be obtained in one OPC.

[0024]

However, the above-mentioned configuration has the following problems. That is, in the above-mentioned conventional method, the laser power to be recorded in the first area ER1 is set in a plurality of stages, and is fixedly set without considering the wavelength of the optical pickup 5. However, as the wavelength of the laser light becomes longer, the laser power required for recording becomes more necessary. Therefore, considering the wavelength variation of the optical pickup, the interval of one step becomes large, and at the same time, the recording power is considerably high depending on the wavelength. You can also create a frame that will end up. Further, if the interval of one step becomes large, the error becomes large because the optimum power value is obtained by linear approximation.

Furthermore, when recording at a considerably high power, A
The TIP data (time information) cannot be read, and the rotation control of the disk and the microcomputer control cannot be performed accurately.

Further, in the above-mentioned conventional example, the time width of the 3T pit is measured in order to determine the optimum recording, and if the time width of the 3T pit is 694 ns (in the case of x1 recording), the optimum recording is performed. It is judged that it is in a state. However, if all the optical characteristics of the optical pickup 5 are complete, there is no problem, but the time width of the 3T pit is greatly affected by the optical characteristics of the optical pickup 5 and the initial adjustment of focus. Therefore, it was not possible to realize optimum recording simply by correcting the recording pulse so that the time width of the 3T pit is around 694 ns as in the conventional case.

In view of the above problems, an object of the present invention is to provide a power calibration method for a write-once type optical disc and an optical disc recording / reproducing apparatus capable of obtaining the optimum recording laser power and recording pulse in consideration of the constitutional requirements of the apparatus. To do.

[0028]

In order to achieve the above object, the present invention provides, in claim 1, three to one times the reference time width.
In a power calibration method of a write-once optical disc in which information is recorded by an EFM signal composed of a pulse signal having a time width of 1 time, a laser power at the time of trial writing on a predetermined write-once optical disc and optimum recording are performed. And a time width of a pulse signal having a time width that is a predetermined multiple of the reference time width when the optical disk is reproduced, and the power calibration of the write-once optical disk to be the information recording target during information recording. One partition in the area is divided into a plurality of parts, and in the first divided area of the one partition divided into the plurality of parts, the first division is performed by at least two laser powers changed with reference to the laser power stored in the storage device. Power calibration of the first
The optimum power is calculated, the test information is written by the first optimum power in the second divided area of the one partition divided into a plurality of pieces, and then the write information to the second divided area is reproduced. Then, the difference amount between the time width stored in the storage device and the time width of the pulse signal having the time width stored in the storage device in the reproduction pulse is detected, and the difference amount is set to a predetermined reference value. When within the range, the first optimum power is used for information recording. When the difference amount is outside the reference range, a time width correction value is obtained based on the difference amount, and the time width correction value is used for the recording. By correcting the time width of the pulse signal, at least 2 in the third divided area of one partition divided into the plurality of pieces.
A power calibration method for a write-once optical disc is proposed in which the second optimum power is obtained by two laser powers to obtain a second optimum power and the second optimum power and the time width correction value are used for information recording.

According to the power calibration method for the write-once type optical disc, the laser power when a predetermined write-once type optical disc is preliminarily written, and the predetermined reference time width when the optimum recorded optical disc is reproduced. The time width of the pulse signal having the double time width is stored in the storage device. Further, at the time of information recording, one partition in the power calibration area of the write-once optical disc to be the information recording target is divided into a plurality of partitions, and the storage device is stored in the first divided area of the plurality of divided one partitions. A first optimum power calibration is performed by using at least two laser powers changed with the stored laser power as a reference, and a first optimum power is obtained. Then, after writing the test information by the first optimum power in the second divided area of the one divided into the plurality of pieces, the information written in the second divided area is reproduced to store the test information. When the difference amount between the time width stored in the device and the time width of the pulse signal having the time width stored in the storage device in the reproduction pulse is detected, and the difference amount is within a predetermined reference range Uses the first optimum power for information recording. Further, when the difference amount is outside the reference range, a time width correction value is obtained based on the difference amount, and the time width of the recording pulse signal is corrected by the time width correction value, and the time width correction value is divided into the plurality of divisions. The second optimum power is obtained by performing the second power calibration with the at least two laser powers in the third divided region of the created one partition, and the second optimum power and the time width correction value. Is used for information recording.

According to a second aspect of the present invention, in the power calibration method for a write-once optical disc in which information is recorded by an EFM signal composed of a pulse signal having a time width that is 3 to 11 times the reference time width, a predetermined additional write is performed in advance. Power when trial writing was performed on the optical disc,
The time width of a pulse signal having a time width that is a predetermined multiple of the reference time width when an optimally recorded optical disk is reproduced is stored in a storage device, and at the time of information recording, a write-once optical disk to be the information recording target is recorded. One partition in the power calibration area is divided into a plurality of parts, and at least two laser powers changed based on the laser power stored in the storage device are used in the first divided area of the one partition. The first power calibration is performed to obtain the first optimum power, and the test information is written by the first optimum power in the second divided area of the one partition divided into the plurality of areas. The time stored in the storage device by reproducing the write information to the two divided areas. And a first difference amount between the reproduction pulse and the time width of the pulse signal having the time width stored in the storage device, and when the first difference amount is within a predetermined reference range, When the first optimum power is used for information recording and the first difference amount is outside the reference range,
A first time width correction value is obtained based on the first difference amount, the time width of the recording pulse signal is corrected by the first time width correction value, and the third partition is divided into the plurality of partitions. In the divided area of, the second optimum power is obtained by performing the second power calibration with at least two laser powers, and the second optimum power is obtained.
In the fourth divided area of the partition, after writing the test information by the second optimum power, the write information in the fourth divided area is reproduced, and the time width stored in the storage device is reproduced. And a second difference amount between the reproduction pulse and the time width of the pulse signal having the time width stored in the storage device, and when the second difference amount is within a predetermined reference range, the second difference amount is detected. When the second optimum power and the first time width correction value are used for information recording and the second difference amount is outside the reference range, the second time width correction value is based on the second difference amount. Then, a power calibration method for a write-once optical disc is proposed in which the second optimum power and the second time width correction value are used for information recording.

According to the power calibration method for the write-once optical disc, the laser power when the test writing is performed on the predetermined write-once optical disc and the predetermined reference time width when the optimum recorded optical disc is reproduced. The time width of the pulse signal having the double time width is stored in the storage device. Further, at the time of information recording, one partition in the power calibration area of the write-once optical disc to be the information recording target is divided into a plurality of partitions, and the storage device is stored in the first divided area of the plurality of divided one partitions. A first optimum power calibration is performed by using at least two laser powers changed with the stored laser power as a reference, and a first optimum power is obtained. Then, after writing the test information by the first optimum power in the second divided area of the one divided into the plurality of pieces, the information written in the second divided area is reproduced to store the test information. When the difference amount between the time width stored in the device and the time width of the pulse signal having the time width stored in the storage device in the reproduction pulse is detected, and the difference amount is within a predetermined reference range Uses the first optimum power for information recording. Further, when the difference amount is outside the reference range, a time width correction value is obtained based on the difference amount, and the time width of the recording pulse signal is corrected by the time width correction value, and the time width correction value is divided into the plurality of divisions. The second optimum power is obtained by performing the second power calibration with the at least two laser powers in the third divided region of the one partition. Furthermore, after writing the test information by the second optimum power in the fourth divided area of one partition divided into the plurality of pieces, the write information in the fourth divided area is reproduced and the storage is performed. A second difference amount between the time width stored in the device and the time width of the pulse signal having the time width stored in the storage device in the reproduction pulse is detected, and the second difference amount is predetermined. Within the reference range of, the second optimum power and the first time width correction value are used for information recording. When the second difference amount is outside the reference range, the second difference amount is determined based on the second difference amount.
Is obtained, and the second optimum power and the second time width correction value are used for information recording.

According to a third aspect of the present invention, in the power calibration method for the write-once optical disc according to the first or second aspect, the storage device has a time width of a pulse signal having a time width three times the reference time width. A power calibration method for a write-once optical disc is proposed, which is stored and detects a difference amount in a time width three times the reference time width when the difference amount is detected.

According to the power calibration method for the write-once optical disc, the storage device stores the time width of the pulse signal having a time width three times the reference time width which causes a slight change, and stores the difference amount. At the time of detection, a difference amount in a time width three times the reference time width is detected, the first and second difference amounts are obtained based on the time width, and the time width of the recording pulse is corrected.

Further, in claim 4, the input digital data is subjected to eight-to-four modulation (EFM).
And an EFM encoder that outputs an EFM signal that is a pulse signal having a time width that is 3 to 11 times the reference time width, and an optical pickup that has a laser that emits laser light to an optical disk that is a target for recording and reproducing information. , The EF
In an optical disk recording / reproducing apparatus equipped with a laser driving means for driving the laser on the basis of the M signal, a laser power when trial writing is performed on a predetermined write-once type optical disk and an optimum recorded optical disk is reproduced. The storage means for storing the time width of the pulse signal having a time width which is a predetermined multiple of the reference time width of, An optical disk recording / reproducing device provided with a power calibration means for adjusting is proposed.

According to the optical disk recording / reproducing apparatus, the laser power when the test writing is performed on the predetermined write-once optical disk in advance, and the time width which is the predetermined times the reference time width when the optimum recorded optical disk is reproduced. The time width of the pulse signal having is stored in the storage means. Thereby, the laser power and the time width corresponding to the optical characteristics of the optical pickup are stored. Further, at the time of recording information, the power calibration means adjusts the power and pulse width of the laser light based on the stored contents of the storage means. After this, the digital data to be recorded is sent by the EFM encoder to
Two-to-teen modulation (EFM) is performed and output as an EFM signal, the laser is driven by the recording control circuit and the laser driving means, and laser light is emitted to the optical disk to be recorded and reproduced. As a result, information is recorded with the optimum power and time width in consideration of the optical characteristics of the optical pickup.

According to a fifth aspect, in the optical disc recording / reproducing apparatus according to the fourth aspect, the optical disc in which the time width of the pulse signal having a time width three times the reference time width is stored in the storage means. A recording / reproducing device is proposed.

According to the optical disk recording / reproducing apparatus, the time width of the pulse signal having a time width that is three times the reference time width is stored in the storage means, and when the recording pulse width of the power calibration is adjusted, Reference time width 3
The difference amount in the doubled time width is detected, and the time width of the recording pulse is corrected.

[0038]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. As shown in FIG. 1, the PCA is divided into 100 partitions P001 to P100, and each partition P001 to P100 has 15 frames F01 to F15.
It is composed of

When obtaining the optimum recording laser power, P
When trial writing is performed on the CA, in the first embodiment, one partition is divided into the first to fourth areas ER1 to ER4, and 8, 2, 3, and 2 frames are allocated to each, and 4
I am writing trial writings.

The write information for the trial writing is a well-known EFM (Eight to Fourteen Modu) which is a pulse train having a time width 3 to 11 times the reference time width T.
lation) signal and the EFM signal is used to modulate the laser power for trial writing.

FIG. 8 is a schematic block diagram showing an optical disk recording / reproducing apparatus according to the present invention. In the figure, the same components as those of the above-described conventional example are denoted by the same reference numerals. Further, the difference between the conventional example and this embodiment is that a storage unit 11 is provided, and the optimum laser power and the time width of the 3T pulse are stored in advance in this storage unit 11, and power calibration is performed based on these. I have decided to do it.

That is, in FIG. 8, 1 is an encoder,
The information to be written is converted into an EFM signal and output. Reference numeral 2 is a recording control circuit, which is an EFM signal and a CP described later.
The control signal from U is input, and the drive control signal is output to the servo circuit 3 and the laser drive circuit 4. The servo circuit 3
The positions of the optical pickup 5 and the objective lens (not shown) are set to appropriate positions. The laser drive circuit 4 energizes a laser diode (not shown) in the optical pickup 5 based on the drive control signal input from the recording control circuit 2, and causes the laser diode to emit laser light to the optical disc 6.

Reference numeral 7 denotes an RF amplifier circuit, which inputs an RF signal corresponding to the reflected light from the optical disc 6 received by the optical pickup 5, amplifies the RF signal, and supplies it to the jitter detection circuit 8 and the β detection circuit 9. Output. Jitter detection circuit 8
Generates an EFM signal by binarizing the input RF signal, measures the time width of a pulse having a time width three times the reference time width T (hereinafter, referred to as 3T time width), and measures each measured time width. The time width data is output to the CPU 10. The β detection circuit 9 receives the peak value of the input RF signal, that is, the maximum value A
And the minimum value B are measured, and the β value calculated by the equation (1) is output to the CPU 10.

The CPU 10 collects the statistics of the 3T time width data input from the jitter detection circuit 8, and based on the statistical result and the 3T time width stored in the storage unit 11, the time width correction value of the writing EFM signal. And calculate β
The optimum laser power is obtained based on the value and the laser power stored in the storage unit 11, and these data and a control signal for instructing correction based on these data are output to the recording control circuit 2.

The storage section 11 is composed of a rewritable memory such as an EEPROM.
The optimum laser power when trial writing is performed on a predetermined write-once type optical disk at the time of initial adjustment of the apparatus and the time width of 3T pits when the optimum recorded optical disk is reproduced are recorded.

Next, the operation of this embodiment having the above-mentioned structure will be described in detail with reference to the flow charts shown in FIGS. 9 and 10. At the start of writing information to the optical disc, OPC is performed. CPU when performing OPC
Reference numeral 10 sets the time width correction value of the writing EFM signal and the laser power to initial values (SB1). Here, the initial value is set based on the laser power and the time width stored in the storage unit 11.

After that, the PCA test area is searched (SB2), and one partition to be used is divided into the first to fourth areas ER1 to ER4 as shown in FIG. 1 (SB3).

Next, as shown in FIG. 11, the CPU 10 writes with the first laser power in the first frame of the first area ER1 (SA4). The laser power at this time is (LP-2) mW to (LP + 3.5) with respect to the laser power LP stored in the storage unit 11, for example.
The minimum value PW1 of the eight types of laser power obtained by dividing the mW range into eight is set. After that, the laser power is set to stepwise different values (PW2 to PW8) and writing is performed for the second to eighth frames of the first area ER1 (SB5 to SB11).

After writing in all the frames in the first area ER1, the written information is reproduced (SB
12), find the β value in each frame (SB1
3). Based on these eight β-values, as shown in FIG. 5, the β-values are interpolated to obtain the laser power at which β = a (the best value), that is, the voltage Vb applied to the laser diode (SB14).

Next, the CPU 10 instructs the recording control circuit 2 to set the laser power PW9 at which β = a, and writes to the second area ER2 by this laser power PW9 (SB15). Thereafter, the information written in the second area ER2 is reproduced (SB16), the jitter data in the last half frame, that is, the time width of a plurality of 3T pits is read (SB17), and the β value is determined in the same manner as described above. Ask (SB18).

Next, the average value of the time width of the read 3T pits is obtained (SB19). Here, as shown in FIG. 6, ± 118 ns is equally divided into four with the time width of the 3T pits stored in the storage unit 11 as the center, and the number of 3T pits included in each of these four regions is divided. N ₁ to N ₄ to determine the sum of the central values t ₁ ~t ₄ values obtained by multiplying the respective regions by the average division to the time width by the number of all the 3T pit included this value into four regions The value t _m is sought. These are expressed by the formula (2) described above.

As described above, the time width deviation y'when the initial correction amount in the time width is x'can be obtained.
In addition, the relationship between the correction amount x of the time width and the deviation y of the time width in various types of optical discs has been determined by a preliminary experiment.
It is known to be represented by a straight line. Therefore, as shown in FIG. 7, a straight line passing through (x ', y') with an inclination of k is
By obtaining the x value (correction value) when y = 0 intersects, it is possible to obtain the correction value x of the time width capable of forming the optimum 3T pit, that is, minimizing the jitter (SB20).

It is determined whether or not the β value and the time width of the 3T pit obtained here are in the optimum recording state (SB21).
The value stored in the storage unit 11 is referred to for this determination. If the result of this determination is that it is in the optimum recording state, information is written using the aforementioned laser power PW9 and time width correction value (SB22).

If the result of determination in SB21 is that the optimum recording state is not reached, the CPU 10 instructs the recording control circuit 2 to indicate the value of the correction value x thus obtained, and the time width of the recording EFM signal is corrected (SB23).

Next, the CPU 10 has the minimum value PW of the laser powers (PW10, PW11, PW12) which are changed in three steps around the obtained laser power PW9.
Writing is performed in the first frame of the third area ER3 using 10 (SB24).

After that, the laser power is set to different values (PW11, PW12) in the second frame and the third frame of the third area ER3 and writing is performed (SB25, SB26).

After writing in all the frames of the third area ER3, the written information is reproduced (SB
27), β value in each frame is obtained (SB2
8). Based on these three β values, in the same manner as described above, the β values are interpolated to obtain the laser power PW13 that gives β = a (the best value) (SB28), and the laser power PW13 is used to determine the fourth value. The writing is performed in the two frames of the area ER4, and this is reproduced to confirm the optimum value (SB29), and the OPC is ended.

Next, the CPU 10 instructs the optimum laser power obtained by OPC to the recording control circuit 2 and writes information by this laser power (SB3).
0).

As described above, according to this embodiment, the PCA
When performing a trial writing in, a partition is divided into first to fourth regions ER1 to ER4 of a plurality of frames,
Since the optimum recording laser power is obtained by performing trial writing four times, the optimum recording laser power can be obtained in one OPC performed using one partition.

As a result, the laser power and pulse time width can be set in consideration of the optical characteristics of the optical pickup 5 (variation of the laser light wavelength, etc.) and the degree of initial focus adjustment. Therefore, the ATIP data (time information) cannot be read out and the disk rotation control and microcomputer control can be accurately performed. In this embodiment, one partition in the PCA test area is divided into four areas. ER
1 to ER4, and 1 in each area ER1 to ER4
I've written it a few times, but it's not limited to this.

[0061]

As described above, according to the power calibration method for the write-once optical disc according to the first aspect of the present invention, one partition is divided into a plurality of areas, and one of the divided areas is divided. Since the trial writing is performed once, even if the optimum recording laser power cannot be obtained by one trial writing, the trial writing can be performed again in another area in the partition.
Since the optimum recording laser power can be obtained by using one partition in one OPC,
Even if you are making a CD with songs recorded,
It is possible to produce a CD conforming to the standard without using a plurality of partitions on a PC.

Furthermore, since the laser power and the time width of the pulse used for information recording are set based on the laser power and the time width stored in advance in the storage device, the optical characteristics of the optical pickup and the initial adjustment of the focus. Since the laser power and the pulse time width are set in consideration of the condition, it is possible to prevent the ATIP data (time information) from being read without recording at a high power more than necessary, and to control the rotation of the disk and the microcomputer. This has an extremely excellent effect that the control can be accurately performed.

Further, according to the power calibration method for the write-once optical disc of the second aspect, one partition is divided into a plurality of regions, and the power calibration is performed twice using the plurality of regions to converge. The optimum recording laser power and time width correction amount can be obtained. Therefore, even when producing a CD in which 99 songs are recorded, it is not necessary to use a plurality of partitions in one OPC, and a CD conforming to the standard can be produced.

Furthermore, since the laser power and the time width of the pulse used for information recording are set based on the laser power and the time width previously stored in the storage device, the optical characteristics of the optical pickup and the initial adjustment of the focus are adjusted. Since the laser power and pulse time width are set in consideration of the condition, it is possible to record at a considerably high power, and to prevent the ATIP data (time information) from being read out. It has an extremely excellent effect that can be performed accurately.

According to the power calibration method of the write-once optical disc of the third aspect, in addition to the above effects, the storage device is provided with a time width three times as long as the reference time width which causes a slight change. The time width of the pulse signal is stored, the difference amount in the time width three times the reference time width is detected when the difference amount is detected, and the first and second difference amounts are obtained based on the time width. Since the time width is corrected, the information can be recorded with the pulse time width most suitable for the optical disc to be recorded.

Further, according to the optical disc recording / reproducing apparatus of the fourth aspect, the laser power at the time of performing the trial writing on the predetermined write-once type optical disc and the reference time width at the time of reproducing the optimally recorded optical disc. The time width of the pulse signal having a time width of a predetermined time is stored by the storage means, and the laser power and the time width corresponding to the optical characteristics of the optical pickup are stored. Since the power calibration means adjusts the power of the laser light and the recording pulse width based on the stored contents, the laser power and the pulse time width are considered in consideration of the optical characteristics of the optical pickup and the initial adjustment of the focus. Since it is set, recording at a considerably high power is eliminated and ATIP data (time information) can be read. Without being not put out, in which exhibits the excellent effect that the rotation control and microcomputer control of the disk can be performed accurately.

Further, according to the optical disc recording / reproducing apparatus of the fifth aspect, in addition to the above-mentioned effect, the pulse signal having a time width three times as long as the reference time width which causes a subtle fluctuation is stored in the storage device. Since the time width is stored and the pulse time width at the time of recording is corrected based on the time width, it is possible to perform information recording with the recording pulse time width most suitable for the optical disc to be recorded.

[Brief description of drawings]

FIG. 1 is a diagram showing a relationship between PCA partitions and frames and an example of partition division according to an embodiment of the present invention.

FIG. 2 is a diagram showing a relationship between PCA partitions and frames and an example of partition division in a conventional example.

FIG. 3 is a schematic configuration diagram showing a conventional optical disc recording / reproducing apparatus.

FIG. 4 is a flowchart showing a procedure of OPC in a conventional example.

FIG. 5 is a diagram illustrating a method for calculating an optimum β value in a conventional example.

FIG. 6 is a diagram illustrating a method of calculating a time width correction value in a conventional example.

FIG. 7 is a diagram illustrating a method of calculating a time width correction value in a conventional example.

FIG. 8 is a schematic configuration diagram showing an optical disc recording / reproducing apparatus according to an embodiment of the present invention.

FIG. 9 is a flowchart showing an OPC procedure according to an embodiment of the present invention.

FIG. 10 is a flowchart showing the procedure of OPC in one embodiment of the present invention.

FIG. 11 is a diagram showing a relationship between a partition and a frame of a PCA and a recording laser power in one embodiment of the present invention.

[Explanation of symbols]

1 ... Encoder, 2 ... Recording control circuit, 3 ... Servo circuit,
4 ... Laser drive circuit, 5 ... Optical pickup, 6 ... Optical disk, 7 ... RF amplification circuit, 8 ... Jitter detection circuit, 9 ... β
Detection circuit, 10 ... CPU, 11 ... Storage unit.

Claims (5)

[Claims] 1. A power calibration method for a write-once optical disc in which information is recorded by an EFM signal composed of a pulse signal having a time width that is 3 to 11 times as long as a reference time width. The laser power at the time of performing, and the time width of the pulse signal having a time width that is a predetermined multiple of the reference time width at the time of reproducing the optimally recorded optical disc are stored in a storage device. 1 in the power calibration area of the write-once optical disc that is the target of information recording
The partition is divided into a plurality of parts, and in the first divided area of the one partition divided into the plurality of parts, the first power calibration is performed by at least two laser powers changed with reference to the laser power stored in the storage device. Is performed to obtain a first optimum power, and after writing test information by the first optimum power in the second divided area of the one partition divided into the plurality of sections, the test information is written to the second divided area. The write information is reproduced, and a difference amount between the time width stored in the storage device and the time width of the pulse signal having the time width stored in the storage device in the reproduction pulse is detected. When the quantity is within a predetermined reference range, the first optimum power is used for information recording, and when the difference is outside the reference range, A time width correction value is obtained based on the difference amount, the time width of the recording pulse signal is corrected by the time width correction value, and at least two lasers are provided in the third divided area of one partition divided into the plurality of pieces. The second power calibration is performed by the power and the second
The power calibration method for a write-once optical disc, wherein the second optimum power and the time width correction value are used for information recording. 2. A power calibration method for a write-once optical disc in which information is recorded by an EFM signal composed of a pulse signal having a time width which is 3 to 11 times as long as a reference time width. The laser power at the time of performing, and the time width of the pulse signal having a time width that is a predetermined multiple of the reference time width at the time of reproducing the optimally recorded optical disc are stored in a storage device. 1 in the power calibration area of the write-once optical disc that is the target of information recording
The partition is divided into a plurality of parts, and in the first divided area of the one partition divided into the plurality of parts, the first power calibration is performed by at least two laser powers changed with reference to the laser power stored in the storage device. Is performed to obtain the first optimum power, and after writing the test information by the first optimum power in the second divided area of the one partition divided into the plurality of partitions, the test information is written to the second divided area. The write information is reproduced to detect a first difference amount between the time width stored in the storage device and the time width of the pulse signal having the time width stored in the storage device in the reproduction pulse. When the first difference amount is within a predetermined reference range, the first optimum power is used for information recording, and the first difference amount is When the outside quasi range, the first
A first time width correction value is obtained based on the difference amount, and the time width of the recording pulse signal is corrected by the first time width correction value, and the third divided area of one partition is divided into the plurality of divided areas. In the above, the second power calibration is performed with at least two laser powers to obtain the second optimum power, and in the fourth divided area of one partition divided into the plurality of pieces, the test information of the second optimum power is obtained. A pulse having a time width stored in the storage device and a time width stored in the storage device in the reproduction pulse by reproducing the write information to the fourth divided area after writing. A second difference amount from the time width of the signal is detected, and when the second difference amount is within a predetermined reference range, the second optimum power and the first time width correction value are set as information. It is used for information recording, and when the second difference amount is out of the reference range, the second difference amount is
2. A power calibration method for a write-once optical disc, wherein a second time width correction value is obtained based on the difference amount, and the second optimum power and the second time width correction value are used for information recording. 3. A time width of a pulse signal having a time width three times the reference time width is stored in the storage device, and a difference amount in a time width three times the reference time width is detected when the difference amount is detected. The power calibration method for the write-once optical disc according to claim 1, wherein the power calibration method is performed. 4. The input digital data is Eight-to-Fourteen modulated (EFM), and is composed of a pulse signal having a time width of 3 to 11 times the reference time width.
Optical disc recording including an EFM encoder that outputs an FM signal, an optical pickup that has a laser that emits a laser beam to an optical disc that is a target for recording and reproducing information, and a laser drive unit that drives the laser based on the EFM signal In the reproducing apparatus, a laser power when a trial write is performed on a predetermined write-once optical disc in advance, and a time width of a pulse signal having a time width that is a predetermined multiple of the reference time width when reproducing the optimally recorded optical disk, And an optical disc recording / reproducing device for storing information on the optical disc, and a power calibration unit for adjusting the power of the laser beam and the recording pulse width at the time of recording information based on the stored contents of the storing unit. apparatus. 5. The storage unit stores 3 of the reference time width.
The optical disc recording / reproducing apparatus according to claim 4, wherein a time width of the pulse signal having a double time width is stored.