KR20040108338A - Method and apparatus for recording optical disc - Google Patents

Abstract

PURPOSE: An optical disk recording device and a recording method are provided to compensate for a measured modulation degree based on a stored compensation value, and to compare the compensated modulation degree with a preset modulation degree, thereby suppressing the deterioration of the recording property of a signal overwritten on a phase change-type optical disk. CONSTITUTION: A CPU confirms a current address and a recording area address, and performs a seek operation by moving an objective lens in tracking direction while moving a carriage(S101). When a recording area is reached, a modulation degree measuring circuit measures a modulation degree by reproducing a previously recorded signal(S102). A comparator compares the modulation degree with a preset modulation degree(S103). If the measured modulation degree is out of a predetermined range, a recording power is set to be bigger than an optimum power(S104). An overwriting operation is carried out(S105).

Description

Optical disc recording apparatus and recording method {Method and apparatus for recording optical disc}

The present invention relates to an optical disc recording apparatus and a recording method for recording information onto a phase change type optical disc.

In recent years, a phase change type optical disc capable of responding to the demand for miniaturization and sex space of a media medium and rewriting information any number of times has been widely used for recording and preserving information.

By the way, when overwriting on a phase change type optical disk, if the laser power when the information was previously recorded is too high, there is a tendency that the recording characteristics of the overwritten signal thereafter remarkably deteriorate. Fig. 16 shows the characteristics of the signal overwritten by changing the laser power of recording in the first and second cases when a signal is written at 16 times the speed of the CD-RW which is a phase change type optical disk. In Fig. 16, the horizontal axis is the difference between the first recording power and the second recording power (Delta Pw), and the left vertical axis is the difference between the modulation degree (1m11) at the first recording power and the modulation degree (2m11) at the second recording power ( 1m11-2m11: Delta m11), and the vertical axis on the right side shows the C1 error value after overwriting.

As a result, as the value of Delta Pw on the horizontal axis becomes negative, that is, the higher the first recording power, the difference in modulation degree Delta m11 tends to be larger, and the C1 error after the second recording also tends to increase. In addition, when the first write power is 5 mW or more larger than the second write power, the C1 error value after overwriting becomes hundreds, and there is a high risk of a read error. This problem is especially noticeable when overwriting is performed between different models.

Accordingly, the present invention has been made in view of the above-described problems, and an object thereof is to provide an optical disc recording apparatus and a recording method for suppressing deterioration in recording characteristics of signals overwritten on a phase change type optical disc.

1 is a configuration diagram of an optical disk recording apparatus in this embodiment.

2 is a configuration diagram of a modulation degree measurement circuit in the present embodiment.

3 is a diagram illustrating a modulation degree of an RF signal.

4 is a configuration diagram of an APC in the present embodiment.

5 is a conceptual diagram of recording waveforms.

Fig. 6 is a diagram showing the correlation between the number of recordings and the C1 error or jitter value by the magnitude of the recording power.

7 is a processing flowchart of the first example in the present embodiment.

8 is a processing flowchart of a second example of the present embodiment.

9 is a processing flowchart of a third example of the present embodiment.

10 is a processing flowchart of a fourth example in the present embodiment.

11 is a processing flowchart of a fifth example in the present embodiment.

12 is a processing flowchart of a sixth example in the present embodiment.

13 is a processing flowchart of the seventh example in the present embodiment.

14 is a processing flowchart of the eighth example in the present embodiment.

15 is a processing flowchart of a ninth example in the present embodiment.

Fig. 16 is a diagram showing a change of modulation degree or C1 error based on the difference in recording power.

* Explanation of the sign

1 optical disc 2 pickup

3 ?? APC 4 ?? RF Amplifier

5 Servo circuit 6 Signal processing circuit

7, 30 ?? CPU 11 ?? Peakhold Circuit

12 ?? Bottom Hold Circuit 13 ??

14 ?? Memory 15 ??

21 ?? semiconductor laser (LD) 22 ?? front monitor diode

23a, 23b ?? Current Voltage Conversion Resistance

24a, 24b, 24c, 24d amplifier 25a, 25b sample-hold circuit (S / H) 26 driver

27a, 27b, 27c, 27d, 27e ?? switch

28 ?? Encoder 29a, 29b ?? A / D Converter

31a, 31b, 31c, 31d, 31e ?? D / A converter

32 ?? lead / light changeover switch

33 ?? Temperature Detection Unit

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, this invention proposes the following means.

The present invention relates to an optical disc recording apparatus for recording a signal on a changeable optical disc using a semiconductor laser, comprising: modulation degree measuring means for measuring a modulation degree of a signal recorded on an optical disc, storage means for storing a preset modulation degree, and the modulation; Comparison means for comparing the modulation degree measured by the figure measuring means and the modulation degree stored in the storage means, and when the degree of modulation of the recorded signal is larger than the preset modulation degree as a result of the comparison by the comparing means, recording on the optical disc An optical disc recording apparatus having a control means for changing a waveform or a recording method is proposed.

The present invention provides an optical disk recording method for recording a signal on a phase change type optical disk using a semiconductor laser, comprising: measuring a modulation degree of a signal recorded on an optical disk, comparing the measured modulation degree with a preset modulation degree, As a result of the comparison, when the degree of modulation of the recorded signal is larger than the preset degree of modulation, an optical disc recording method is proposed which changes the recording waveform or the recording order to the optical disc.

According to this invention, by the operation of the modulation degree measuring means, the modulation degree of the signal already recorded on the optical disc is measured, and the measured value is stored in the storage means. The measured modulation degree is compared with the value of the preset modulation degree by the operation of the comparing means, and as a result of the comparison, when the modulation degree of the signal already recorded is larger than the preset modulation degree, the recording waveform or recording on the optical disc by the operation of the control means. The method is changed.

The present invention has correction value storage means for storing a correction value relating to a modulation degree measured in the modulation degree measuring means, and wherein the comparing means stores the modulation degree measured by the modulation degree measuring means in the correction value storing means. There is proposed an optical disc recording apparatus characterized by comparing the preset modulation degree after correction based on the correction value.

In the present invention, the modulation degree of the reproduced signal causes individual differences due to the characteristics of the optical system constituting the optical disk device. However, according to the present invention, the modulation degree measured by the modulation degree measuring means is corrected based on the stored correction value. By comparing the modulation degree preset by the means, it is possible to eliminate the influence of the individual difference of such a device.

The present invention relates to an optical disc recording apparatus for recording a signal on a phase change type optical disc using a semiconductor laser. A modulation degree measuring means for measuring a signal, a comparison means for comparing the modulation degree measured by the modulation degree measuring means, and a result of the comparison by the comparing means, wherein the modulation degree of the already recorded signal is not recorded. There is proposed an optical disc recording apparatus having a control means for changing a recording waveform or a recording method to the optical disc when the modulation degree of the signal recorded in the area is larger.

The present invention relates to an optical disc recording method for recording a signal on a phase change type optical disc using a semiconductor laser, comprising the steps of: recording a signal in an area in which the signal of the optical disc is not recorded; measuring a modulation degree of the signal; A step of measuring a modulation degree of an already recorded signal, a step of comparing each measured modulation degree, and as a result of the comparison, a modulation degree of a signal recorded in an area in which the signal is not recorded; When larger, the optical disk recording method has been proposed, wherein the recording waveform or the recording order of the optical disk is changed.

According to this invention, the modulation degree of the signal recorded in the area where the signal of the optical disc is not recorded and the degree of modulation of the signal already recorded are measured by the operation of the modulation degree measuring means. When the modulation degrees measured in the modulation degree measuring means are compared by the operation of the comparing means, and when the comparison results, the modulation degree of the signal already recorded is greater than the modulation degree of the signal recorded in the area where no signal is recorded. The operation of the control means changes the recording waveform or the recording method on the optical disc.

The present invention is characterized in that the control means changes the laser power for recording on the optical disc to an optimal value determined by a signal recorded in an area in which no signal of the optical disc is recorded or higher than a predetermined value. An optical disc recording apparatus is proposed.

According to the present invention, since the operation of the control means changes the laser power for recording higher than the optimum value or the predetermined value determined by the signal recorded in the area in which the signal of the optical disc is not recorded, accordingly, The influence of the recorded signal can be mitigated.

According to the present invention, the control means has a value higher than an optimal recording laser power or a predetermined recording laser power determined by a signal in which the laser power for erasing on the optical disk is recorded in an area in which a signal of the optical disk is not recorded. There is proposed an optical disk recording apparatus characterized by changing.

According to the present invention, since the operation of the control means changes the erasing power to an optimal value determined by a signal recorded in an area in which no signal of the optical disc is recorded or a laser power higher than a preset value, therefore, The effects of previously recorded signals can be mitigated.

The present invention proposes an optical disc recording apparatus characterized by changing the control means so as to widen the pulse width of the head of the recording waveform with respect to a predetermined recording waveform.

According to the present invention, since the recording waveform is changed so that the pulse width of the head of the recording waveform becomes wider with respect to the predetermined recording waveform by the operation of the control means, the same effect as in the case of raising the recording power can be expected.

The present invention proposes an optical disk recording apparatus characterized by changing the control means so that the last pulse width of the recording waveform becomes wider with respect to the predetermined recording waveform.

According to the present invention, since the recording waveform is changed so that the final pulse width of the recording waveform becomes wider with respect to the predetermined recording waveform by the operation of the control means, the same effect as in the case of raising the recording power can be expected.

The present invention proposes an optical disc recording apparatus characterized by changing the control means so that the last off pulse width of the recording waveform becomes narrower with respect to the predetermined recording waveform.

According to the present invention, since the recording waveform is changed so that the last off pulse width of the recording waveform is narrower with respect to the predetermined recording waveform by the operation of the control means, as a result, the final pulse width of the recording waveform is widened. You can expect the effect of.

The present invention proposes an optical disc recording apparatus characterized in that the control means changes the recording method to a method of performing a recording operation with a predetermined recording waveform after the erasing operation of an already recorded signal is performed.

According to the present invention, since the recording operation is performed with a predetermined recording waveform after the erasing operation of the recorded signal is performed by the operation of the control means, the influence of the previously recorded signal can be alleviated.

The present invention proposes an optical disc recording apparatus in which the control means changes the recording method to a method of recording the same signal more than once in the same area.

According to the present invention, the influence of a previously recorded signal can be alleviated by recording the same signal more than once in the same area by the operation of the control means.

The present invention proposes an optical disc recording apparatus in which the first recording laser power is made highest and the recording laser power is gradually lowered when the same signal is recorded two or more times in the same area.

According to the present invention, when the same signal is recorded two or more times in the same area, the first recording laser power is made highest, and the recording laser power is gradually lowered to record, thereby mitigating the influence of the previously recorded signal and moving forward. It is possible to minimize the deterioration of recording characteristics even if it is corrected many times.

EMBODIMENT OF THE INVENTION Hereinafter, the optical disc recording apparatus in embodiment of this invention is demonstrated in detail with reference to FIG.

As shown in FIG. 1, the optical disk recording apparatus in the embodiment of the present invention includes an optical disk 1, a pickup 2, an APC (Auto Power Control) 3, an RF amplifier 4, a servo circuit ( 5) A signal processing circuit 6 and a CPU (Central Processing Unit) 7 are provided.

The optical disc 1 is a recording medium capable of recording, reproducing and erasing information by a semiconductor laser, for example, a CD-RW, a DVD-RW, or the like. The pickup 2 is an optical unit for recording information on the optical disc, reproducing and erasing the information, and focusing or tracking elements and objects constituting an optical system such as a semiconductor laser, an objective lens, a photo detector, a front monitor diode, APC 3 is a control block for monitoring the current from the front monitor diode in the pickup 2 and controlling the output power of the semiconductor laser to a desired value.

The RF amplifier 4 calculates a current from the photo detector in the pickup, generates an RF signal, and generates a focus error signal or tracking error signal for controlling the objective lens. In this embodiment, a circuit block for measuring the modulation degree of the RF signal is also incorporated. Specifically, as shown in FIG. 2, the modulation degree measurement circuit includes a peak hold circuit 11, a bottom hold circuit 12, a calculation unit 13, a storage unit 14, and a comparison unit. It consists of 15.

The peak hold circuit 11 inputs the generated RF signal, holds the bottom level of the RF signal, and the bottom hold circuit 12 inputs the RF signal to hold the bottom level of the RF signal. The obtained peak hold value and the bottom hold value are output to the calculation unit 13, and Itop and Ibot shown in Fig. 3 are calculated in the calculation unit 13, and then the modulation degree is calculated based on the following expression (1).

<Equation 1>

M11 = (Itop-Ibot) / Itop In the calculating section 13, the calculated modulation degree is stored in the storage section 14, these values are compared in the comparing section 15, and then the comparison result is the CPU 7 Is output.

In addition, from the point of view of recording characteristics, the modulation degree is preferably about 0.6, and it is known that a C1 error increases when a value shifted by 0.1 or more from this value causes a reproduction error. In addition, since the modulation degree is largely irregular due to individual differences in devices, for example, each device reproduces a signal at at least two points of the reference disk, measures the modulation degree at each point, and simultaneously adjusts the reference value (eg, 0.6). In the case where the correction value of each device is measured in advance and stored in the storage device in the CPU 7 and overwritten to the disk, the above-described correction is performed with the measured modulation rate, Appropriate means to maintain this need to be taken.

The servo circuit 5 calculates an appropriate control amount based on the focus error signal and the tracking error signal input from the RF amplifier 4, and then outputs it to a drive circuit (not shown). The servo circuit 5 is provided with an equalizer circuit for each loop to stabilize the control system. The signal processing circuit 6 inputs the EFM signal generated from the RF signal, performs data processing, and includes a PLL circuit (not shown) and controls the rotation of the spindle motor. The CPU 7 performs control of the entire device based on a control program stored in a ROM (Read Only Memory) or the like. In the present embodiment, control such as changing the power of the recording waveform, changing the pulse width or changing the recording method is performed based on the comparison result of the modulation degree.

As shown in Fig. 4, the APC 3 includes a semiconductor laser (LD) 21, a front monitor diode (FPD) 22, current voltage conversion resistors 23a, 23b, amplifiers 24a, 24b, 24c, 24d), the sample hold circuit (S / H) 25a, 25b, the LD driver 26, the switches 27a, 27b, 27c, 27d, 27e and the encoder 28 provided in the LD driver 26, The A / D converters 29a and 29b, the CPU 30, the D / A converters 31a, 31b, 31c, 31d, and 31e, the read / write switch 32, and the temperature detector 33 are provided. In addition, in this embodiment, the laser output control part is provided in two systems.

The semiconductor laser 21 is a semiconductor element that emits a laser by supplying a predetermined current, and is used in the optical disk device to record information on the disk or to reproduce or erase information recorded on the disk. In the optical pickup. The front monitor diode (FPD) 22 is provided in the optical pickup so as to face the semiconductor laser 21, receives the laser light emitted from the semiconductor laser 21, and converts it into a current value. By monitoring this current value, the laser power can be monitored.

The current voltage conversion resistors 23a and 23b are resistors for converting the current into voltage to voltage-amplify the current output from the front monitor diode (FPD) 22 to the amplifiers 24a and 24b of the next stage. The amplifiers 24a and 24b amplify the output from the front monitor diode (FPD) 22 converted to voltage in order to effectively function the sample hold circuit (S / H) 25a and 25b in the next step. The sample hold circuits (S / H) 25a, 25b hold the laser output converted into voltage at predetermined intervals, and output the result. The laser output of the semiconductor laser 1 is controlled by comparatively controlling the output value and the set value. The amplifiers 24c and 24d amplify the difference between the output values of the sample hold circuits (S / H) 25a and 25b and the output values of the D / A converters 31a and 31b.

The LD driver 26 inputs the outputs of the amplifiers 24c and 24d to generate a current for supplying the semiconductor laser 21. In the present embodiment, five LD drivers are provided, and respective outputs are coupled. Therefore, the switches 27a, 27b, 27c, 27d, and 27e described later are controlled by the encoder 28, and the output of the LD driver whose switch is turned ON is added and output to the semiconductor laser 21. The switches 27a, 27b, 27c, 27d, and 27e provided in the LD driver operate in accordance with the ON / OFF signal from the encoder 28. In the present embodiment, the outputs of the LD driver provided with five systems are respectively provided. To control.

The A / D converters 29a and 29b convert the input voltage of the LD driver 26 into digital values and input them to the CPU 30. The CPU 30 stores the control program, controls the entire optical disk device, and stores the input values from the A / D converters 29a and 29b in the laser output control unit, and based on these values, other laser outputs. The current value for controlling is calculated, and the desired value is output to the D / A converters 31a, 31b, 31c, 31d, and 31e while the encoder 28 is controlled.

The temperature detector 33 is provided near the semiconductor laser 21, and is provided with a temperature sensor composed of a thermistor, a resistor, or the like, for example, to detect the temperature of the semiconductor laser 21.

The recording waveform used in this embodiment is a waveform as shown in FIG. This recording waveform is determined to form a high quality pit in consideration of the composition of the disk and the like, and four different laser outputs Pr, Pe, Pp, and Pb are set. These laser powers and pulse widths of the pulses are specified in the Orange Book. Since there are subtle differences in the composition of the used optical discs, which optical discs were targeted during the development stage of the optical disc recording apparatus and the recording power was set. In some cases, there may be a problem that the recording power is too great for some discs but too large for other discs. In this embodiment, therefore, recording characteristics are maintained by performing the following processing.

Next, the process at the time of overwriting will be described with reference to FIGS. 7 to 15.

The first embodiment has a flowchart as shown in Fig. 7, wherein the CPU 7 first confirms the current address and the address of the recording area, and then moves the objective lens in the pickup 2 in the tracking direction, Alternatively, the seek operation is executed by moving the carriage on which the pickup 2 is mounted (step 101). When the seek operation is completed and the recording area is reached, the already recorded signal is reproduced and the modulation degree m11 is measured by the modulation degree measuring circuit in the RF amplifier 4 (step 102). As described above, the measured modulation degree is corrected by using the device-specific correction value stored in the storage device in the CPU 7.

The corrected modulation degree is once stored in the storage unit 14 and then compared with the preset modulation degree (for example, 0.65) in the comparison unit 15 (step 103). As a result of the comparison, when the corrected measured value is within a predetermined range (for example, within 0.05 of the modulation degree difference) with respect to the set value, the recording power is set to an optimum power (step 106), and the overwrite operation is performed. (Step 105). On the other hand, when the corrected measured value is out of the predetermined range (for example, the modulation degree difference 0.05 or more) with respect to the set value, the overwrite is made to be larger than the optimum power (Pwo + Pw1) (step 104). Perform the operation (step 105). In addition, the optimal recording power is about 25mW when recording on a CD-RW reference disc at 16x speed using a standard recording device.However, the recording power varies with the recording speed. For example, it is necessary to determine an optimal value in advance for each recording speed. Further, in order to increase the recording power, control to increase the value set in the D / A converters 31a to 31e from the CPU 30 is performed in FIG.

In addition, the relationship between the number of writes when the overwrite is repeated and the C1 error or jitter value at that time is as shown in FIG. In other words, if the recording power is low, the first C1 error or jitter value is greatly deteriorated. After that, the characteristic tends to be improved. If the recording power is high, the first C1 error or jitter value is better than when the recording power is low. Each time there is a tendency for the property to deteriorate rapidly. Therefore, as the second and subsequent recording powers, it is not appropriate to increase 3 mW or more with respect to the previous recording power from various experimental data.

8 shows a processing flowchart in the second embodiment. In the second embodiment, the CPU 7 first checks the current address and the address of the test write area, and then moves the objective lens in the pickup 2 in the tracking direction, or carries a carriage on which the pickup 2 is mounted. ), The seek operation is executed (step 201). When the seek operation is completed and the test write area is reached, signal recording is performed at the optimal recording power (step 202). When the signal recording operation is completed, the signal just recorded is reproduced and the modulation degree m11t is measured by the modulation degree measuring circuit in the RF amplifier 4 (step 203). The measured modulation degree is corrected using the device-specific correction value stored in the storage device in the CPU 7 as described above.

Next, the CPU 7 checks the current address and the address of the recording area and then executes the seek operation (step 204). When the seek operation is completed and the recording area is reached, the already recorded signal is reproduced and the modulation degree m11 is measured by the modulation degree measuring circuit in the RF amplifier 4 (step 205). The measured modulation degree is corrected using the device-specific correction value stored in the storage device in the CPU 7 as described above.

The corrected modulation degree is once stored in the storage unit 14, and then compared with the modulation degree comparison unit 15 of the signal recorded in the test writing area measured in step 203 (step 206). As a result of the comparison, when the corrected measured value is within a predetermined range (for example, within a modulation degree difference of 0.05 or less) compared to the set value, the recording power is set to an optimum power (step 209), and the overwrite operation is performed (208). step). On the other hand, when the corrected measured value is out of a predetermined range (for example, a modulation degree difference of 0.05 or more) compared to the set value, the overwrite operation is made with the recording power larger than the optimum power (Pwo + Pw1) (step 207). Perform step 208.

9 shows a processing flowchart in the third embodiment. In the third embodiment, the processing from step 301 to step 303 is the same as in the first embodiment, but as a result of the comparison, the corrected measured value is within a predetermined range compared to the set value (for example, within the modulation degree difference of 0.05). , The erase power is set to the optimum power (step 306), the overwrite operation is performed (step 305), and the corrected measured value is out of a predetermined range compared to the set value (for example, a modulation degree difference of 0.05 or more). Is different in that the erase power is set to (Peo + Pe1) larger than the maximum value of the recording power (step 304) and the overwrite operation is performed (step 305). However, this case also works in that it suppresses the influence of a signal recorded at a high recording power last time. In addition, the modulation degree of the signal already recorded may not be compared with the set modulation degree but may be compared with the modulation degree of the signal recorded at the optimum power in the test writing area as in the second embodiment.

10 shows a processing flowchart in the fourth embodiment. In the fourth embodiment, the processing from steps 401 to 403 is the same as in the first embodiment, but as a result of the comparison, the corrected measured value is within a predetermined range (for example, within a modulation degree difference of 0.05 or less) compared to the set value. In this case, the recording power is set to the optimum power (step 403), the overwrite operation is performed (step 405), and the corrected measured value is out of a predetermined range (for example, a modulation degree difference of 0.05 or more) compared to the set value. In this case, the pulse width at the head of the recording waveform is set wide (step 404), and the overwrite operation is performed (step 405). However, setting a wide pulse width of the recording waveform equivalently increases the recording power, and thus has the same effect in that it suppresses the influence of the signal recorded at the previous high recording power. The modulation degree of the signal already recorded may not be compared with the set modulation degree but may be compared with the modulation degree of the signal recorded at the optimum power in the test writing area as in the second embodiment. In order to change the pulse width, the CPU 30 shown in FIG. 4 may control the pulse width of the signal output from the encoder 28.

11 shows a processing flowchart in the fifth embodiment. In the fifth embodiment, the processing from steps 501 to 503 is the same as in the first embodiment, but as a result of the comparison, the corrected measured value is within a predetermined range (for example, within a modulation degree difference of 0.05 or less) compared to the set value. When the recording power is set to the optimum power (step 503), the overwrite operation is performed (step 505). When the recording power is out of a predetermined range (e.g., a modulation degree difference of 0.05 or more) compared to the corrected measured value, the recording waveform is The last pulse width is set wide (step 504), and the overwrite operation is performed (step 505). However, setting a wide pulse width of the recording waveform equivalently increases the recording power, and thus has the same effect in that it suppresses the influence of the signal recorded at the previous high recording power. The modulation degree of the signal already recorded may not be compared with the set modulation degree but may be compared with the modulation degree of the signal recorded at the optimum power in the test writing area as in the second embodiment.

Fig. 12 shows a processing flowchart in the sixth example. In the sixth example, the processing from step 601 to step 603 is the same as in the first embodiment, but as a result of the comparison, the measured measured value is compared with the set value. If it is within a predetermined range (e.g., within a modulation degree difference of 0.05 or less), the recording power is set to an optimum power (step 603), and the overwrite operation is performed (step 605). When it is out of range (for example, modulation degree difference 0.05 or more), the last off pulse width of a recording waveform is set narrow (step 604), and an overwrite operation | movement is performed (step 605). However, setting the last off pulse width narrowly has the same effect in that it suppresses the influence of a signal recorded at a high recording power last time. The modulation degree of the signal already recorded may not be compared with the set modulation degree but may be compared with the modulation degree of the signal recorded at the optimum power in the test writing area as in the second embodiment.

In addition, the recording waveforms in the case of recording signals at 16x speed on the CD-RW, which is a phase change optical disk, are shown in FIG. 5, and the leading pulse, middle pulse, middle off pulse, last pulse, and last off pulse are shown in FIG. . According to experimental data for a given disk, the pulse width of each of these pulses is, for example, 1T as a bit clock (14.4 nsec at 16x speed), leading pulse width = (28/32) * T, middle pulse. Width = (20/32) * T, mid-off pulse width = (1-20 / 32) * T = (12/32) * T, final pulse width = (20/32) * T, final off pulse width = (10/32) * T. According to the experimental data, the reference for widening the pulse width is (4/32) * T. Therefore, when this is applied to the above example, the head pulse width = (32/32) * T, and the middle pulse width = (20/32). ) * T, mid-off pulse width = (1-20 / 32) * T = (12/32) * T, final pulse width = (24/32) * T, final off pulse width = (10/32) * It becomes T.

13 shows a processing flowchart in the seventh embodiment. In the seventh example, the processing from step 701 to step 703 is the same as in the first embodiment, but as a result of the comparison, the corrected measured value is within a predetermined range (for example, within a modulation degree difference of 0.05 or less) compared to the set value. When the recording power is set to the optimum power (step 703), the overwrite operation is performed (step 705), and the corrected measured value is out of a predetermined range (for example, a modulation degree difference of 0.05 or more) compared to the set value. In this case, the erase operation is performed (step 704), and the overwrite operation is performed (step 705). However, the same operation is carried out in that the erase operation is performed before the overwrite operation, thereby suppressing the influence of the signal recorded at a high recording power last time. The modulation degree of the signal already recorded may not be compared with the set modulation degree but may be compared with the modulation degree of the signal recorded at the optimum power in the test writing area as in the second embodiment.

14 shows a processing flowchart in the eighth embodiment. In the eighth example, the processing from steps 801 to 803 is the same as in the first embodiment, but as a result of the comparison, the corrected measured value is within a predetermined range (for example, within a modulation degree difference of 0.05 or less) compared to the set value. When the recording power is set to the optimum power (step 803), the overwrite operation is performed (step 805), and the corrected measured value is out of a predetermined range (for example, a modulation degree difference of 0.05 or more) compared to the set value. In this case, the recording operation is performed by setting the recording power to the optimum power (step 804), and the same recording operation is performed once again (step 805). However, the same effect is obtained by suppressing the influence of a signal recorded at a high recording power last time by performing a recording operation twice with a predetermined recording waveform. The modulation degree of the signal already recorded may not be compared with the set modulation degree but may be compared with the modulation degree of the signal recorded at the optimum power in the test writing area as in the second embodiment.

Fig. 15 shows a processing flowchart in the ninth embodiment. In the ninth example, the processing from steps 901 to 903 is the same as in the first embodiment, but as a result of the comparison, the corrected measured value is within a predetermined range (for example, within a modulation degree difference of 0.05 or less) compared to the set value. In this case, the recording power is set to an optimum power (step 909), and the overwrite operation is performed (step 911). On the other hand, when the corrected measured value is larger than a predetermined range (e.g., within a modulation degree difference of 0.05 or less) relative to the set value, it is compared with a second threshold value (e.g., within a modulation degree difference of 0.1 or less) and falls within this range. It is determined whether or not there is (step 904). At this time, when the corrected measured value is within the range of the second threshold value, the recording power is made larger than the optimum power (Pw = Pwo + Pw1) (step 910), and the recording operation is performed (step 911).

On the other hand, when the corrected measured value is not within the range of the second threshold value, the recording power is made larger than the optimum power (step 905), as in step 910, the recording operation is performed (step 906), and the recording power is once again. Is set to an optimum power (step 907), and a recording operation is performed (step 908). In addition, the value of the recording power when the recording operation is performed in multiple stages is, for example, when the recording power of a signal already recorded is assumed to be 5 mW higher than the optimum power, the recording operation is performed once with a recording power of 3 mW higher than the optimum power. Then, the recording operation may be performed once again at the optimum power. The first recording is performed at a recording power of 3 mW higher than the optimum power, and the second recording is performed at a recording power of 1.5 mW higher than the optimum power. How to do it is good. In any case, the same function is performed in that the recording operation is performed while lowering the recording power in several times to suppress the influence of the signal recorded at the high recording power. The modulation degree of the signal already recorded may not be compared with the set modulation degree but may be compared with the modulation degree of the signal recorded at the optimum power in the test writing area as in the second embodiment.

As mentioned above, although embodiment of this invention was described above with reference to drawings, a specific structure is not restrict | limited to these embodiment, The design change etc. of the range which do not deviate from this summary are included. For example, in the present embodiment, a CD-RW has been described as an example of a phase change type optical disc. However, the present invention can also be applied to a DVD-RW type if it is a phase change type optical disc. In addition, in this embodiment, although many Example was demonstrated individually, these Example can also be used in combination suitably.

As described above, the present invention has the effect that the deterioration of the recording characteristics of the signal overwritten on the phase change type optical disk can be effectively suppressed without requiring any special circuits or equipment.

Claims (13)

An optical disc recording apparatus for recording signals using a semiconductor laser on a phase change type optical disc, Modulation degree measuring means for measuring a modulation degree of a signal recorded on the optical disc; Storage means for storing a preset modulation degree; Comparison means for comparing the modulation degree measured by said modulation degree measuring means and the modulation degree stored in said storage means; Control means for changing a recording waveform or a recording method on the optical disc when the modulation degree of the recorded signal is larger than a preset modulation degree as a result of the comparison by the comparison means; An optical disc recording apparatus having a. The method of claim 1, The modulation degree measuring means having correction value storage means for storing a correction value with respect to the measured modulation degree, And the comparing means corrects the modulation degree measured by the modulation degree measuring means based on the correction value stored in the correction value storing means, and then compares the preset modulation degree. An optical disc recording apparatus for recording signals using a semiconductor laser on a phase change type optical disc, Modulation degree measuring means for measuring a modulation degree of a signal recorded in an area in which the signal of the optical disc is not recorded, and measuring a modulation degree of a signal already recorded; Comparison means for comparing the modulation degree measured by said modulation degree measuring means; Control means for changing a recording waveform or a recording method on the optical disc when the modulation degree of the signal already recorded is greater than the modulation degree of the signal recorded in the area where the signal is not recorded; An optical disc recording apparatus having a. The method according to any one of claims 1 to 3, And the control means changes the laser power for recording on the optical disc to an optimal value determined by a signal recorded in an area in which the optical disc signal is not recorded or higher than a preset value. The method according to any one of claims 1 to 3, And the control means changes the laser power for erasing on the optical disk to a value higher than an optimal recording laser power or a predetermined recording laser power determined by a signal recorded in an area in which the optical disk signal is not recorded. Optical disc recording device. The method according to any one of claims 1 to 3, And the control means is changed so as to widen the pulse width of the head of the recording waveform with respect to the predetermined recording waveform. The method according to any one of claims 1 to 3, And the control means is changed so as to widen the last pulse width of the recording waveform with respect to the predetermined recording waveform. The method according to any one of claims 1 to 3, And the control means is changed so that the last off pulse width of the recording waveform becomes narrower with respect to the predetermined recording waveform. The method according to any one of claims 1 to 3, wherein the control means changes the recording method to a method of performing a recording operation with a predetermined recording waveform after performing an erase operation of a signal already recorded. Optical disc recording device. The method according to any one of claims 1 to 3, And the control means changes the recording method to a method of recording the same signal two or more times in the same area. The method of claim 9, And when the same signal is recorded two or more times in the same area, the first recording laser power is made highest, and the recording laser power is gradually lowered to record. An optical disc recording method for recording a signal using a semiconductor laser on a phase change type optical disc, Measuring a modulation degree of a signal recorded on the optical disc; Comparing the measured modulation degree with a preset modulation degree; And, as a result of the comparison, when the modulation degree of the recorded signal is larger than the preset modulation degree, the recording waveform or the recording order to the optical disc is changed. An optical disc recording method for recording a signal using a semiconductor laser on a phase change type optical disc, Recording the signal in an area in which the signal of the optical disc is not recorded; Measuring a modulation degree of the signal; Measuring a modulation degree of a signal already recorded; Comparing the measured modulation degrees; And as a result of comparison, when the degree of modulation of the already recorded signal is greater than the degree of modulation of the signal recorded in the area in which the signal is not recorded, the recording waveform or the recording order to the optical disc is changed.