JPH1040548A - Running opc method for optical disk and optical disk recording/reproducing apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical disk running OPC method and an optical disk recording/reproducing apparatus whereby a laser light intensity can be accurately corrected when information is recorded. SOLUTION: Reflected light form a pit part of an optical disk 1 during recording of information is detected by a photodetector 21b. The maximum value of the intensity of the reflected light from the pit part and the intensity of the reflected light after a reference time lasts from a front end of the pit part are detected via a peak detection circuit 25 and a sample-hold circuit 26. A maximum value of the intensity of the reflected light of a plurality of pit parts and the intensity of sample reflected light are detected for several frames in an actual recording area when information is started to be recorded on the optical disk. Based on the detection result, a reference maximum value of the intensity of the reflected light and a reference intensity of the sample reflected light are obtained. After the information is started to be recorded, the maximum value of the intensity of the reflected light from the pit part and the intensity of the sample reflected light are detected, and compared with reference values. The intensity of laser light is corrected on the basis of the comparison result according to the running OPC.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention mainly relates to EFM (E
The present invention relates to an optical disc running OPC method and an optical disc recording / reproducing apparatus when information is recorded on the optical disc using a "ight to fourteen modulation" method.

[0002]

2. Description of the Related Art In recent years, a technique for recording large-capacity information on an optical information recording medium, for example, an optical disk such as a WO disk has become popular. When recording, for example, an audio signal on an optical disc, a method of digitizing and recording the audio signal at the time of recording is generally performed in order to eliminate distortion, noise, and the like at the time of reproduction. In addition, a CIRC (Cross Interleaved Reed-Solomon Code) is applied to a digitized audio signal (hereinafter, referred to as a reference digital signal).
With the addition of parity for error correction,
Further, by modulating this by the EFM method, the reproduction characteristics are improved.

[0003] By performing the above-mentioned EFM modulation, nine time widths (hereinafter, 3T to 11T), which are 3 to 11 times the predetermined reference time width T, are set as the high-level and low-level time widths of the reference digital signal. Time span). The optical disk is irradiated with laser light based on the reference digital signal, and a pit portion is formed on the recording layer. For example, pulsed laser light having an intensity capable of forming a pit portion is irradiated during the high level period of the reference digital signal.

[0004] Conventionally, a write-once optical disc (CD-W
When information is recorded in O), the recording laser beam intensity is optimized (OPC: Optimun Power Control, hereinafter referred to as OPC). OPC is the power calibration area (PCA) of the optical disc.
a, hereinafter referred to as PCA), and by reproducing the recorded information. The PCA is divided into a test area and a count area, each of which is divided into 100 partitions.

[0005] One partition in the test area is composed of 15 frames, and one partition is used in one trial writing. In the Orange Book, which is the standard for write-once optical discs, as an example of use, test writing is performed with 15 levels of laser light intensity in 15 frames, and the laser light intensity with the best recording state is selected. This method describes that the subsequent information recording is performed.

Furthermore, the Orange Book states that running OPC is performed at the time of recording information.
The running OPC is a comparison between the intensity of the reflected light from the pit during the OPC and the intensity of the reflected light from the pit during the information recording, and based on the comparison result, the intensity of the laser light obtained during the OPC. The information is recorded while making corrections as needed. Here, a pit having a time width of 11T is used as the pit for obtaining the reflected light intensity, and the intensity of the reflected light from the rear end of the pit is used.

[0007]

However, as described above, when the laser beam intensity is corrected based on the intensity of the reflected light from the rear end of the pit portion having an 11T time width during information recording, depending on the type of optical disc, When the laser beam intensity is increased, the laser beam is saturated at a certain point, and it becomes impossible to detect that the laser beam intensity has increased.

That is, as shown in FIG. 2, when compared with the reflected light intensity V from the pit portion Pa having a 3T time width, the reflected light intensity V from the rear end portion of the pit portion Pa having an 11T time width is somewhat pitted. Since the portion has been formed, the intensity is lowered, and even if the laser beam intensity is increased, the amount of change is small because the intensity of the original reflected light is low. For this reason, depending on the type of the optical disk used, the detection sensitivity may be greatly reduced, and the fluctuation of the laser beam intensity may not be detected or may be erroneously detected.

Furthermore, since the correction at the time of running OPC is performed using the measured value in the initial OPC using the PCA as a reference value, it is susceptible to eccentricity, and accurate laser beam intensity correction may not be possible. Was.

That is, according to the description of the Orange Book, P
A series of operations of the initial OPC using CA is to be performed within 15 frames as described above.
Thirteen of the frames are used. Therefore, the remaining two frames can be used for the reference value measurement of the running OPC, and these two frames are about 26.7 ms. Also, since OPC is performed on the inner circumference of the optical disc,
In order to average the eccentricity component, it is necessary to take in data for at least one rotation, but in the OPC region, it takes about 120 ms for one rotation at the standard speed. Will be greatly affected.

SUMMARY OF THE INVENTION An object of the present invention is to provide an optical disk running OPC method and an optical disk recording / reproducing apparatus capable of accurately correcting the intensity of laser light during information recording.

[0012]

In order to achieve the above object, according to the present invention, there is provided a laser irradiation apparatus which emits laser light having an intensity corresponding to information to be recorded and capable of forming a pit portion. And a second signal level indicating a period during which laser light of a predetermined intensity lower than the intensity is applied, wherein the first and second signal levels are equal to a predetermined reference time. Based on a reference digital signal having a time width of 3 to 11 times the width, the optical disk is irradiated with pulsed laser light having a predetermined intensity to form pits, and the optical disk runs when information is recorded. In the OPC method,
At the start of information recording on the optical disk, the maximum value of the reflected light intensity of the plurality of pits and the sample reflected light intensity after a predetermined time from the tip of the pit portion are detected over a plurality of frames in the actual recording area. Based on the above, while determining the maximum reflected light intensity and the sample reflected light intensity as a reference value, the difference between the value obtained by multiplying the maximum reflected light intensity at the reference value by a predetermined constant and the sample reflected light intensity is calculated. Determined as a correction reference value, after the start of the information recording, the maximum reflected light intensity from the pit portion and the sample reflected light intensity are detected, and the maximum reflected light intensity detected during the information recording and the sample are detected. From the reflected light intensity, similarly, a difference between a value obtained by multiplying the reflected light intensity maximum value by a predetermined constant and the sample reflected light intensity is obtained as a detection value, and the detected value and the correction reference value are calculated. And compare the difference between the correction reference value and the detected value to be within a predetermined range, it proposes a running OPC method of the optical disc for correcting the laser beam intensity.

According to the optical disc running OPC method, the maximum value of the intensity of the reflected light from the plurality of pits and the lapse of a predetermined time from the tip of the pit over a plurality of frames in the actual recording area at the start of recording information on the optical disc. The subsequent sample reflected light intensity is detected, and based on the detection result, a reflected light intensity maximum value and a sample reflected light intensity serving as a reference value are obtained, and a predetermined constant is set to the reflected light intensity maximum value at the reference value. Is obtained as a correction reference value.

Further, after the start of the information recording, the maximum value of the reflected light intensity from the pit portion and the sample reflected light intensity are detected, and the maximum value of the reflected light intensity and the sample reflected light intensity are similarly determined. The difference between the value obtained by multiplying the reflected light intensity maximum value by a predetermined constant and the sample reflected light intensity is determined as a detection value, and thereafter, the detected value is compared with the correction reference value, and the detected value is compared with the detected value. The laser beam intensity is corrected so that a difference from the correction reference value falls within a predetermined range. The maximum value of the reflected light intensity of the pit portion is at the tip of the pit portion, and since the point of saturation with respect to the laser light intensity used for information recording is high, it is possible to detect even higher light intensity. Becomes Thus, for example, even if there is a disturbance or an increase in the ambient temperature, the apparent recording laser beam intensity decreases, and the intensity of the reflected light from the pit portion during recording increases, information can be recorded in an optimal state.

According to a second aspect of the present invention, in the optical disk running OPC method according to the first aspect, the constant is:
An optical disk running OPC method that is preset for each type of optical disk on which information is to be recorded is proposed.

According to the optical disk running OPC method, a constant used for comparing the detection result with a reference value is set in advance for each type of optical disk on which information is to be recorded, and correction is performed using the constant. Therefore, even if the type of the optical disk changes, the laser beam intensity can be corrected correspondingly.

According to a third aspect of the present invention, in the optical disc running OPC method according to any one of the first and second aspects, the sample reflected light intensity is detected after the elapse of the reference time width from the tip of the pit portion. A running OPC method is proposed.

According to the optical disc running OPC method, the reflected light intensity detected after the elapse of the reference time width from the tip of the pit portion is used as the sample reflected light intensity. As described above, the reflected light intensity at the position after the elapse of the reference time width from the tip of the pit portion is determined for the pit portion having a time width 3 to 11 times the reference time width since the formation state of the pit portion is not determined. In each case, they are almost the same.

According to a fourth aspect of the present invention, a first signal level corresponding to information to be recorded and indicating a period of irradiating laser light having an intensity capable of forming a pit portion, and a predetermined signal intensity lower than the intensity. And a second signal level representing a period for irradiating the laser light. The first and second signal levels correspond to a reference digital signal having a time width of 3 to 11 times a predetermined reference time width. An optical information recording apparatus for irradiating an optical disk with pulsed laser light of a predetermined intensity to form pits, wherein at least the intensity of reflected light from the optical disk is detected at the time of forming the pit portion; Detecting means, based on a detection result of the light intensity detecting means, a maximum reflected light intensity detecting means for detecting the maximum value of the reflected light intensity of the pit portion, based on a detection result of the light intensity detecting means,
Sample reflected light intensity detecting means for detecting the reflected light intensity after a predetermined time has elapsed from the tip of the pit portion; and a value obtained by multiplying the reflected light intensity maximum value at the start of information recording by a predetermined constant and the sample reflected light intensity. A first calculating means for calculating a difference between the reflected light intensity as a correction reference value, a storage means for storing the correction reference value, and a maximum reflected light intensity detected by the maximum reflected light intensity detecting means after the start of information recording. Second calculating means for calculating, as a detection value, a difference between a value obtained by multiplying the value by a predetermined constant and the sample reflected light intensity detected by the sample reflected light intensity detecting means, and the detection value, the correction reference value, And an optical disk recording / reproducing apparatus comprising: a laser light intensity correcting unit that corrects the laser light intensity so that a difference between the detection value and the correction reference value is within a predetermined range. .

According to the optical disk recording / reproducing apparatus, the intensity of the reflected light from the optical disk is detected by the light intensity detecting means when the pit is formed, and the maximum reflected light intensity is detected based on the detection result of the light intensity detecting means. The means detects the maximum value of the reflected light intensity from the pit portion,
The reflected light intensity after a predetermined time has passed from the tip of the pit portion is detected by the sample reflected light intensity detecting means. Further, a difference between a value obtained by multiplying the maximum value of the reflected light intensity at the start of information recording by a predetermined constant and the sample reflected light intensity is calculated as a correction reference value by the first calculating means, and the correction reference value is calculated. Is stored in the storage means.

Further, after the start of information recording, the second calculating means multiplies the maximum value of the reflected light intensity detected by the maximum reflected light intensity detecting means by a predetermined constant and the sample reflected light intensity. After the difference between the sample reflected light intensity detected by the detection means is calculated as a detection value, the detection value is compared with the correction reference value by the laser light intensity correction means, and the detection value and the correction reference value are compared. The laser beam intensity is corrected so that the difference between the two falls within a predetermined range. The maximum value of the reflected light intensity at the pit portion is at the tip of the pit portion, and since the point where the laser light intensity used for information recording is saturated is high, it is possible to detect even higher light intensity. This allows
For example, even if there is disturbance such as eccentricity or an increase in ambient temperature, even if the apparent recording laser beam intensity decreases and the reflected light intensity from the pit portion during recording increases, it is possible to record information in an optimal state. Become.

According to a fifth aspect of the present invention, there is provided an optical disk recording / reproducing apparatus according to the fourth aspect, wherein the constant is set in advance for each type of optical disk on which information is to be recorded.

According to the optical disk recording / reproducing apparatus, the constant is set in advance for each type of the optical disk on which information is to be recorded, and the constant is used in the laser light intensity correction.

According to a sixth aspect of the present invention, in the optical disk recording / reproducing apparatus according to any one of the fourth to fifth aspects, the sample reflected light intensity detecting means is configured to detect the intensity of the pit after the elapse of the reference time width from the tip of the pit. We propose an optical disk recording / reproducing device that detects the intensity of light reflected from a unit.

According to the optical disk recording / reproducing apparatus, the reflected light intensity detected by the sample reflected light intensity detecting means after a lapse of the reference time width from the tip of the pit portion is used as the sample reflected light intensity. As described above, the reflected light intensity at the position after the elapse of the reference time width from the tip of the pit portion is three to one times the reference time width since the formation state of the pit portion is not determined.
It is almost the same in any of the pit portions having the time width of 1 time.

[0026]

FIG. 1 is a block diagram showing an embodiment of the present invention. In the figure, reference numeral 1 denotes an optical disk as an optical information recording medium, and reference numeral 2 denotes an optical information recording device (hereinafter, referred to as a recording device). As is well known, during information recording, the optical disc 1 is rotated by a spindle motor (not shown) or the like.

The recording device 2 includes an optical pickup 21, an RF
An amplifier 22, a low-pass filter 23, a timing pulse generation circuit 24, a peak detection circuit 25, a sample hold circuit 26, an arithmetic circuit 27, an optical disk encoder 28,
A high-intensity laser beam which is constituted by a laser driving circuit 29 and an ATIP decoder 30 and receives a well-known EFM-modulated reference digital signal A and can form a pit when the reference digital signal A is at a high level. Is emitted to the optical disk 1, and when the reference digital signal A is at a low level, a low-intensity laser beam capable of forming a non-pit portion and reproducing information is emitted to the optical disk 1.

The optical pickup 21 includes a laser diode 21a, a photodetector 21b, and a half mirror 21.
c, a lens 21d and the like. The laser diode 21a emits laser light having an intensity corresponding to the current input from the laser drive circuit 29, and this laser light is
Optical disc 1 via humila-21c and lens 21d
Is irradiated.

Thus, a pit portion is formed on the optical disc 1 when the intensity of the laser light is high, and a non-pit portion is formed when the intensity of the laser light is low. The light reflected from the optical disk 1 is transmitted through the lens 21d and the half mirror 21c.
, And is converted into an electric signal B having a voltage proportional to the intensity of the reflected light by the photodetector 21 b and input to the RF amplifier 22.

The signal B input to the RF amplifier is converted into a signal B1 amplified at a predetermined amplification degree, and then a signal B2 from which a high-frequency component of a predetermined frequency or more has been removed by a low-pass filter 23, is subjected to peak detection. The signal is input to the circuit 25 and the sample hold circuit 26. Thereby, a noise component due to a scratch or the like formed on the optical disc 1 is removed.

The sample pulse generating circuit 24 receives the read / write control signal G from the arithmetic circuit 27 and the recording control signal A 'from the optical disk encoder 28. When the read / write control signal G indicates writing, As shown in FIG. 3, a pulse signal D having the reference time width T is output to the sample and hold circuit 26 after a lapse of the reference time width T from the rise of the recording control signal A '.

The peak detection circuit 25 detects the maximum value of the voltage level of the pulse in the signal B2 and outputs a signal E having this voltage.

When the sample hold circuit 26 receives the pulse signal D from the sample pulse generation circuit 24,
The voltage level of the signal B2 is detected and held, and the signal F having the held voltage is output.

As a result, as shown in FIG. 4, the peak detection circuit 25 holds the voltage VF corresponding to the intensity of the light reflected from the tip of the pit Pa, and the sample hold circuit 26 holds the voltage VF. The voltage VS corresponding to the intensity of the reflected light at the position after the elapse of the reference time width T from the leading end of the line is held.

The arithmetic circuit 27 is mainly composed of a well-known CPU 27a. The CPU 27a has a ROM 27b in which a program for the arithmetic processing operation is stored, and an EEPR for storing data necessary for the arithmetic processing, data during the arithmetic processing, and the like.
The OM 27c and the RAM 27d are connected.

The CPU 27a of the arithmetic circuit 27 includes:
The ATIP sync pulse C and signals E and F output from the ATIP decoder 30 are input, and the peak detection circuit 25
The signals E and F output from the sample hold circuit 26 are taken into the CPU 27a every two ATIP frames using the ATIP sync pulse C as a timing pulse.

As a result, the CPU 27a has the pit portion P
The value of the voltage VF corresponding to the maximum reflected light intensity at the leading end of a and the value of the voltage VS corresponding to the reflected light intensity (sample reflected light intensity) at a position after the reference time width T from the leading end of the pit portion Pa are obtained. , As digital data.

Further, the CPU 27a determines the received voltage V
An operation described later is performed based on the values of F and VS to calculate voltage value data K for controlling the intensity of light emitted from the laser diode 21a, and output this to the laser drive circuit 29.

The optical disk encoder 28 receives the reference digital signal A and the read / write control signal G,
A recording control signal A ′ corresponding to the reference digital signal A is output to the sample pulse generation circuit 24 and a control signal J for controlling the operation of the laser drive circuit 29 is output.

The laser drive circuit 29 generates a recording signal M based on the signal G and the voltage value data K. The laser diode 21a is driven by the recording signal M, and information is recorded on the optical disk 1.

In this case, as the optical disk 1, for example, a recording layer is formed by a cyanine dye on a substrate on which a tracking group is formed, and a gold reflective layer and an ultraviolet curable resin are further formed on this recording layer. An optical disk having a protective layer formed thereon is used.

Further, as shown in FIG. 5, when the reference digital signal A is at the high level H, the optical disc is irradiated with high intensity laser light capable of forming the pit Pa, and when the reference digital signal A is at the low level L, the laser light is irradiated. The intensity becomes the reproduction power level, and the pit becomes a non-pit Pb without forming a pit.

Next, the operation of the present embodiment having the above configuration will be described. In the optical disk recording / reproducing apparatus according to the present embodiment, constants N to be used in calculations to be described later for each type of optical disk are obtained in advance by experiments.
Is stored in the EEPROM 27c corresponding to the type of the disk.

When recording information, OPC is performed in the same manner as in the related art.
C is going. In this running OPC, at the start of information recording on the optical disc 1, over several frames in the actual recording area, the tip of a plurality of pits and the reflected light intensity at a position after a reference time width T from the tip are detected. Based on this, the reflected light intensity maximum value and the sample reflected light intensity, which are reference values, are obtained, and these are stored in the RAM 27d.

Further, after the start of information recording, the pit P
a, and the intensity of the reflected light at the position where the reference time width T has elapsed from the tip and the detected value is compared with a reference value stored in the RAM 27d, and a calculation described later is performed. Thus, information is recorded while correcting the laser beam intensity as needed.

These OPC processes are performed based on the control flow shown in FIGS. That is, when recording information on the optical disk 1, the CPU 27a reads the optical disk type recorded in the ATIP of the optical disk 1 (S1), and selects an operation constant N corresponding to the type (S2).

Next, as in the conventional case, the OPC
(S3), a pulse width correction value is determined (S4), and a correction value of the laser beam intensity is determined (S5).
It is stored in the AM 27d (S6).

Thereafter, the pulse width and the laser beam intensity are corrected based on these correction values (S7), and the information to be recorded is written in a predetermined area on the optical disk 1 (S7).
8).

Next, the CPU 27a determines whether or not information is being recorded on the optical disk (S9).
It is determined whether or not the information recording for the frame has been performed (S10). If the result of this determination is that the information for one frame has not been recorded, the process proceeds to step S9. If the information for one frame has been recorded, the information for the next one frame is recorded. parallel reproduction of information recorded on the optical disc 1 is performed, the intensity of reflected light has passed the position of the reflected light intensity (reflected light intensity maximum value) a ₀ and distal from the reference time width T from the tip of the pit portion Pa and (Sample reflected light intensity) _B0 is detected and stored (S11).

Thereafter, the CPU 27a determines whether or not the detected data for 15 times has been obtained (S12). If the detected time has not been reached for 15 times, the CPU 27a shifts to the process of S9 and obtains the detected data for 15 times. when I calculates respective average values a _m, a B _m of the reflection of the 15 detected light intensity maximum value a ₀ and the sample reflected light intensity B ₀ (S13).

Next, the CPU 27a determines whether or not the detected data used in the arithmetic processing in S13 is for the 15 times immediately after the start of the information recording (S14). Is the average value of these
_m, using the B _m, and stores the RAM27d calculates the value SB ₀ shown in the following equation (1) (S15).

SB ₀ = A _m × (1 / N) −B _m (1) where N is a constant corresponding to the type of the optical disk, which is obtained in advance by an experiment as described above and stored in the EEPROM 27c. It is.

Thereafter, the flow shifts to the processing of S9.

If the result of determination in S14 is that the detected data used in the arithmetic processing in S13 is not immediately after the start of recording, the average value A _m and B _m are used to express the following equation (2). stored in RAM27d calculates the value SB ₁ (S16).

SB ₁ = A _m × (1 / N) −B _m (2) where N is a constant corresponding to the type of the optical disk, which is obtained in advance by an experiment as described above and stored in the EEPROM 27c. It is.

Next, CPU 27a, after calculating the value Wp which subtracts the value of SB ₁ from the value of SB ₀ based on the following equation (3) _{(S17), Wp = SB 0} -SB 1 ... (3 It is determined whether the value of Wp is greater than 0 (S1).
8).

[0057] As a result of the determination, when the value of Wp is larger than 0, the value of SB ₁ performs laser beam intensity correction to increase the laser light intensity to approximate the value of SB ₀ (S19), If the value of Wp is equal to or less than 0, it is determined whether the value of Wp is smaller than -ΔWp (S20).
Here, -ΔWp is a set value of the allowable range.

As a result of the determination in S20, the value of Wp is -Δ
When less than Wp is, performs laser light intensity correction to reduce the laser beam intensity to approximate the value of SB ₁ to the value of SB ₀ (S21), when the value of Wp is equal to or greater than -ΔWp is SB ₁ Is substantially equal to the value of SB ₀ (laser light intensity is set to an appropriate value), and laser light intensity correction is not performed.

Here, the specific meaning of the processing of S13 to S17 will be described. At the start of information recording,
As shown in FIG. 8A, since the pits Pa are formed with an appropriate laser beam intensity, the pits Pa
The reflected light intensities A ₀ and B ₀ at the end of the reference time and at the position where the reference time width T has passed from the end can be considered to be in the optimum state. The value SB ₀ obtained by the above equation (1)
Is a value corresponding to the difference SA ₀ between the reflected light intensity maximum value A ₀ and the sample reflected light intensity B ₀ at this time.

If the formation state of the pit portion Pa is not optimal due to disturbance such as eccentricity or a change in ambient temperature,
The reflected light intensities A ₀ and B ₀ at the tip of the pit Pa and at the position where the reference time width T has passed from the tip also change. It has been confirmed by an experiment that this change appears more remarkably in a pit portion having a 3T time width than in a pit portion having an 11T time width.

That is, in the same state as the increase in the laser light intensity, as shown in FIG. 8B, the pits Pa are formed deep and wide, and the reflected light intensities A ₀ ′ and B ₀ ′ decrease. When the laser light intensity is reduced, the pits Pa are formed to be shallow and narrow, and the reflected light intensities A ₀ ′ and B ₀ ′ increase, as shown in FIG. 8C. At this time, the pit portion Pa is usually formed in a tear shape due to the influence of heat conduction, so that the rear end portion is formed deeper and wider than the front end portion, and the reflectance at each portion slightly changes.

Therefore, the A ₀ -B ₀ curve does not move in parallel, and by maintaining this curve in the optimum recording state, that is, by maintaining the above-mentioned SB ₀ value, the optimum recording state is obtained. Can be maintained.

As a result of the determination in S20, the value of Wp is-
If ΔWp or more, it is determined whether the writing (recording) of the information has been completed (S22). If the result of this determination is that information writing has not been completed, the flow shifts to the process of S9.

As described above, according to the present embodiment, the running OPC is performed in the information recording area and the optical disc 1
The formation state of the pit Pa, whose formation state changes significantly due to the change in the properties of the recording layer of the optical disk 1 or the eccentricity of the optical disk 1 or the like, is detected by the reflected light, and the intensity of the laser light is increased or decreased to reduce the heat applied to the optical disk 1. Since the supply amount is corrected, a pit having a shape corresponding to the reference digital signal A can always be formed, and the recording characteristics can be improved.

Further, even when the ambient temperature changes and the intensity or oscillation wavelength of the laser beam changes, the laser beam intensity is corrected to increase or decrease as described above, and the amount of heat supplied to the optical disk 1 is corrected. Therefore, jitter and the like can be reduced, and a pit having a shape corresponding to the reference digital signal A can be always formed, so that recording characteristics can be improved.

Further, in the correction of increase / decrease of the laser beam intensity, it is determined that the laser beam intensity is appropriate when Wp is in the range of 0>Wp> −ΔWp. Since the laser beam intensity does not needlessly increase or decrease, the pit formation state after information recording does not become unstable.

The calculation and the like in this embodiment are merely examples, and the present invention is not limited to this.

[0068]

As described above, according to the optical disk running OPC method according to the first aspect of the present invention, at the start of information recording on the optical disk, the reflection from a plurality of pit portions extends over a plurality of frames in an actual recording area. Light intensity is detected,
Based on the detection result, a correction reference value is obtained, and after the information recording starts, a detection value is obtained from the maximum reflected light intensity from the pit portion and the sample reflected light intensity,
The laser beam intensity is corrected so that the difference between the detected value and the correction reference value falls within a predetermined range. Therefore, the maximum value of the intensity of the reflected light from the pit portion is higher at the point where the intensity is saturated with respect to the intensity of the laser beam used for information recording, so that it is possible to detect even higher light intensity. The laser beam intensity can be accurately corrected without being affected by disturbance or a change in ambient temperature. Thus, for example, when there is a disturbance or an increase in the ambient temperature, even if the apparent recording laser beam intensity decreases and the reflected light intensity from the pit portion during recording increases, information recording is always performed in an optimal state. It can be performed.

According to the optical disc running OPC method of the second aspect, in addition to the above-mentioned effects, the constant used for comparing the detection result with the reference value depends on the type of the optical disc on which information is to be recorded. Since the laser light intensity is set in advance for each time and the constant is used to correct the laser light intensity, the laser light intensity can be corrected even if the type of the optical disk changes.

According to the running OPC method for an optical disk according to the third aspect, in addition to the above effects, the reflected light intensity detected after the elapse of the reference time width from the tip of the pit portion is used as the sample reflected light intensity. As described above, the reflected light intensity at the position after the elapse of the reference time width from the tip of the pit portion is determined by any of the pit portions having a time width of 3 to 11 times the reference time width because the formation state of the pit portion is not determined. Are substantially the same, the point of saturation with respect to the intensity of the laser beam used for information recording is increased, and it is possible to detect even higher light intensity. As a result, the influence of disturbance such as eccentricity and a change in ambient temperature can be further eliminated, and information recording can always be performed in an optimal state.

According to the optical disk recording / reproducing apparatus of the present invention, the maximum value of the reflected light intensity from the pit portion at the start of information recording and the correction reference value based on the sample reflected light intensity are stored in the storage means. After the start of recording, the laser light intensity is adjusted so that the difference between the detection value calculated based on the detection results of the maximum reflected light intensity detecting means and the sample reflected light intensity detecting means and the correction reference value is within a predetermined range. The intensity of the laser beam is corrected by the correction means. Therefore, the maximum value of the reflected light intensity from the pit portion is at the tip of the pit portion, and since the point saturated with the laser light intensity used for information recording is high, it is possible to detect even higher light intensity. Therefore, the laser beam intensity can be accurately corrected without being affected by disturbance such as eccentricity or a change in ambient temperature. Accordingly, even when disturbance such as eccentricity or an increase in ambient temperature occurs, appropriate correction of the laser beam intensity is performed, so that information recording can always be performed in an optimal state.

According to the optical disk recording / reproducing apparatus of the fifth aspect, in addition to the above-mentioned effects, a constant used for laser light intensity correction is set in advance for each type of optical disk on which information is to be recorded. Therefore, even if the type of the optical disk changes, appropriate correction of the laser beam intensity can be performed correspondingly.

According to the optical disk recording / reproducing apparatus of the sixth aspect, in addition to the above effects, the reflected light intensity detected after the elapse of the reference time width from the tip of the pit portion is used as the sample reflected light intensity. The reflected light intensity at the position after the elapse of the reference time width from the tip of the pit portion is three to one times the reference time width because the formation state of the pit portion is not determined.
Since it becomes almost the same in any of the pit portions having a time width of 1 time, the saturation point becomes higher with respect to the intensity of the laser beam used for information recording, and it is possible to detect even higher light intensity. As a result, the influence of disturbances such as eccentricity and changes in ambient temperature can be further eliminated, and accurate laser beam intensity correction can be performed.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing an optical disc recording / reproducing apparatus according to an embodiment of the present invention.

FIG. 2 is a view for explaining a difference in reflected light intensity between a 3T time width pit portion and an 11T time width pit portion in a conventional example.

FIG. 3 is a view for explaining detection timing in one embodiment of the present invention.

FIG. 4 is a view for explaining detection values of a peak detection circuit and a sample hold circuit according to an embodiment of the present invention.

FIG. 5 is a diagram for explaining a relationship between a digital reference signal and a pit according to an embodiment of the present invention.

FIG. 6 is an OPC processing control flowchart according to an embodiment of the present invention.

FIG. 7 is an OPC processing control flowchart according to an embodiment of the present invention.

FIG. 8 is a diagram illustrating a laser light intensity correction method according to an embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Optical disk, 2 ... Optical information recording device, 21 ... Optical pickup, 21a ... Laser diode, 21b ... Photodetector, 21c ... Half mirror, 21d ... Lens, 2
2 RF amplifier, 23 low-pass filter, 24 sample pulse generation circuit, 25 peak detection circuit, 26 sample hold circuit, 27 arithmetic circuit, 27a CP
U, 27b ROM, 27c EEPROM, 27d
RAM, 28: optical disk encoder, 29: laser drive circuit, 30: ATIP decoder.

Claims (6)

[Claims] 1. A first signal level corresponding to information to be recorded and representing a period of irradiation with laser light having an intensity capable of forming a pit portion, and a laser having a predetermined intensity lower than the intensity.
A second signal level representing a period for irradiating the light,
The first and second signal levels are based on a reference digital signal having a time width of 3 to 11 times the predetermined reference time width, and the optical disk is irradiated with pulsed laser light of a predetermined intensity. In a running OPC method of an optical disc for forming pits and recording information, the maximum value of the reflected light intensity of the plurality of pits and the pits over a plurality of frames in an actual recording area at the start of information recording on the optical disc Detecting the reflected light intensity of the sample after a predetermined time from the tip of, based on the detection result, determining the reflected light intensity maximum value and the sample reflected light intensity that are reference values, and the reflected light intensity maximum value at the reference value The difference between the value obtained by multiplying the pit portion by a predetermined constant and the sample reflected light intensity is obtained as a correction reference value. And the sample reflected light intensity is detected, and a value obtained by similarly multiplying the reflected light intensity maximum value by a predetermined constant from the sampled reflected light intensity and the sample reflected light intensity detected at the time of the information recording is sampled. The difference between the reflected light intensity is determined as a detection value, the detected value is compared with the correction reference value, and the laser light intensity is adjusted so that the difference between the detection value and the correction reference value is within a predetermined range. A running OPC method for an optical disk, wherein the method is corrected. 2. The optical disc running OPC method according to claim 1, wherein the constant is set in advance for each type of optical disc on which information is to be recorded. 3. The running OPC method for an optical disk according to claim 1, wherein the sample reflected light intensity is detected after the elapse of the reference time width from the tip of the pit portion. 4. A first signal level corresponding to information to be recorded and representing a period of irradiating laser light having an intensity capable of forming a pit portion, and a laser having a predetermined intensity lower than said intensity.
A second signal level representing a period for irradiating the light,
The first and second signal levels are based on a reference digital signal having a time width of 3 to 11 times a predetermined reference time width, and irradiate an optical disk with pulsed laser light having a predetermined intensity. An optical information recording apparatus for forming pits, wherein at least at the time of forming the pit portion, light intensity detecting means for detecting the intensity of the reflected light from the optical disk; A maximum reflected light intensity detecting means for detecting a maximum value of the light intensity; and a sample reflected light intensity detecting means for detecting a reflected light intensity after a lapse of a predetermined time from a tip of the pit portion based on a detection result of the light intensity detecting means. First calculating means for calculating a difference between a value obtained by multiplying a maximum value of the reflected light intensity at the start of information recording by a predetermined constant and the sample reflected light intensity as a correction reference value; A storage unit for storing a correction reference value, and after the start of information recording, a value obtained by multiplying a maximum value of the reflected light intensity detected by the maximum reflected light intensity detection unit by a predetermined constant, and the sample reflected light intensity detection unit. Second calculating means for calculating a difference between the detected sample reflected light intensity as a detection value, and comparing the detection value with the correction reference value, wherein a difference between the detection value and the correction reference value is within a predetermined range. An optical disk recording / reproducing apparatus, comprising: a laser light intensity correcting means for correcting the laser light intensity. 5. The optical disk recording / reproducing apparatus according to claim 4, wherein the constant is set in advance for each type of optical disk on which information is to be recorded. 6. The sample reflected light intensity detecting means detects the reflected light intensity from the pit portion after the elapse of the reference time width from the tip of the pit portion. An optical disk recording / reproducing apparatus according to claim 1.