JP2004273049A - Optical information recording device and optical information recording method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To form a precise recording mark, without being influenced by delay time of a recording system when performing the recording at a high-speed, or without raising the time resolution of the irradiation time and the cooling time. <P>SOLUTION: A digital LSI 21 modulates an LD 24 at the irradiation intensity such that a recording mark is not formed by the recording data, holds the delay time of the output of an AFE 29 or the like for monitoring the LD 24 and the recording data, and controls the light intensity of the LD 24, by sampling the output of the AFE 29 or the like, with the delay corresponding to the delay time. Thus, the influence of the delay time from the light source modulation timing to the optical output monitor output in the recording at a high-speed can be eliminated. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a light source driving device mounted on an information recording device such as a CD-R drive device, a CD-RW drive device, a DVD-R drive device, a DVD-RW drive device, a DVD + RW drive device, and a DVD-RAM drive device. And an optical information recording method in the optical information recording apparatus.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in an optical disk device, recording is performed by irradiating a recording medium (optical disk) with light modulated by a semiconductor laser (Laser Diode: LD) as a light source.
For example, in a phase-change type optical disk represented by a CD-RW disk or a DVD + RW disk, the medium is heated to a temperature equal to or higher than its melting point and rapidly cooled so as not to exceed the crystallization time of the medium. That is, a recording mark is formed.
Therefore, in order to accurately control the mark shape and position, it is necessary to precisely control the irradiation energy and time to the medium, and it is necessary to generate an accurate optical waveform and perform accurate energy irradiation.
[0003]
In high-speed recording, the rising / falling characteristics of the optical waveform are particularly important items. In a dye-based write-once optical disk represented by a CD-R disk, a DVD + R disk, and the like, a recording mark is formed by causing thermal decomposition due to light irradiation and an optical change due to substrate deformation accompanying the thermal decomposition.
Therefore, it is necessary for such a dye-based write-once optical disk to generate an accurate optical waveform in order to accurately control the mark shape and position.
The same applies to magneto-optical media typified by MOs and MDs, which use the reversal of magnetization near the Curie point.
That is, in any of the recording media, recording data is recorded by irradiating the recording layer with light to raise the temperature to a predetermined critical temperature or higher, thereby causing a physical or chemical change.
Therefore, it is important to accurately control the irradiation energy to the recording medium, that is, the irradiation power and the irradiation time.
[0004]
In many optical disk recording methods such as CDs and DVDs, mark edge recording in which the length of a mark suitable for high-density carries information is adopted. In order to accurately reproduce data, the mark edge recording is performed. Accurate control of shapes and edge positions is required.
Furthermore, a multi-pulse recording method in which a recording mark is formed by a pulse train divided into a plurality of recording pulses is widely used in order to make the mark shape uniform even if the mark length is different.
That is, a recording mark having a uniform length is formed by connecting and forming marks by repeating a heating and cooling cycle. This method is also applied to a dye-based write-once recording medium.
[0005]
In the following description, a pulse for irradiating with a high power for raising the temperature of a recording medium is referred to as a heating pulse, and a pulse for irradiating with a low power so as not to raise the temperature (so as to rapidly cool) is referred to as a cooling pulse. Called.
For this reason, in the conventional optical information recording device, the mark position control is performed by improving the time resolution of the irradiation light. For example, a phase change medium requires not only the accuracy of irradiation energy but also the accuracy of cooling time for performing rapid cooling, and recording is performed so that the irradiation time and cooling time are corrected (for example, see Patent Document 1).
[0006]
[Patent Document 1]
JP-A-8-287465
[0007]
[Problems to be solved by the invention]
However, with the recent demand for high-speed recording, high-speed optical modulation is required, and in order to achieve high-speed recording while maintaining the recording quality, the time resolution of the irradiation time and the cooling time must be further improved.
For example, in order to record a DVD at 10 × speed by a conventional method, a resolution of about 100 ps is required.
Therefore, if high-speed recording is performed by the conventional method, it is difficult to realize the high-speed recording or the cost is greatly increased.
Further, as described below, there is also a problem that proper heating / cooling is not performed due to the delay (rounding) of the rise / fall of the light waveform of the irradiation light, and the accuracy of the mark shape and the mark position is impaired. .
[0008]
FIG. 10 is a diagram illustrating a problem in driving a light source in a conventional light source driving device. FIG. 11 is a diagram showing an example of an optical waveform at this time.
The illustration of the LD drive unit 201 is omitted except for a current source that supplies a drive current.
A laser diode (LD) as a light source usually has a junction capacitance between an anode (Anode) and a cathode (Cathode) (in addition, a parasitic capacitance is also generated). Reference numeral 203 denotes a simple LD equivalent model that takes this junction capacitance into consideration. CLD is a junction capacitance (including a parasitic capacitance), r is an on-resistance, and LDi is an ideal LD.
[0009]
With this junction capacitance, even if a predetermined drive current ILD flows through the LD at a steep rise / fall (see FIG. 11A), a part of the current flows as the charge / discharge current Ic of the junction capacitance. During charging / discharging, the ideal LD (LDi) suffers from excess or deficiency of current, so that the rise / fall time of the current flowing through LDi is delayed, and the rise / fall time of the actual optical output waveform is delayed ( This makes it impossible to emit light with a desired light waveform (see FIG. 11B).
As a result, the accuracy of the mark shape and the position of the mark is deteriorated, resulting in a data error.
[0010]
In particular, high-speed recording requires a high-output LD. However, this problem is remarkable because a high-output LD generally has a large junction capacitance and requires high-speed rising / falling.
Further, when the recording speed increases, the timing of sampling the monitor signal due to the time delay between the signal indicating the data to be recorded and the monitor signal for monitoring the light intensity emitted by the laser is shifted, and the sampling cannot be performed correctly. . Similarly, the time delay from the irradiation of the laser beam to the medium surface to the reflection from the disk surface to detection by the detection system cannot be ignored compared to the minimum mark size.
This is because, for example, when additional recording is performed when a clock representing a mark interval is a channel clock, it is necessary to record a mark to be additionally recorded with an accuracy of at least 5 channel clocks. The mark is deviated from the recording mark by the delay time of the recording system, and recording must be performed.
[0011]
The present invention has been made in order to solve the above-mentioned problem, and is not affected by the delay time of the recording system even during high-speed recording and without increasing the time resolution of the irradiation time and the cooling time. An object of the present invention is to enable formation of a recording mark.
It is another object of the present invention to suppress a delay (rounding) of a rise / fall of an optical waveform due to a junction capacitance of an LD and emit light with a desired optical waveform so that a recording mark can be formed with higher accuracy. I do.
[0012]
[Means for Solving the Problems]
The present invention provides the following optical information recording devices (1) to (7) to achieve the above object.
(1) A light source emits light at a predetermined light intensity based on recording data to generate light of a plurality of pulse trains, and the generated light is irradiated on a recording medium to form a recording mark corresponding to the recording data. In the optical information recording apparatus, a monitor unit that modulates light emitted from the light source with a light intensity based on the recording data, monitors the light intensity, and outputs a monitor result, and outputs a monitor result from the monitor unit. Delay time detecting means for detecting a delay time between the output of the print data and the output of the recording data; sampling the output of the monitoring result from the monitor means by delaying the output by the delay time detected by the delay time detecting means; An optical information recording device provided with a light intensity control means for controlling the light intensity of the light emitted from the light source based on the result.
[0013]
(2) A light source emits light at a predetermined light intensity based on the recording data to generate a plurality of pulse trains of light, and the generated light is applied to a recording medium to form a recording mark corresponding to the recording data. In the optical information recording apparatus, a monitor unit that modulates light emitted from the light source with a light intensity based on the recording data, monitors the light intensity, and outputs a monitor result, and outputs a monitor result from the monitor unit. A minimum delay time detecting means for detecting a minimum delay time between the data and the output of the recording data; and sampling by delaying the output of the monitoring result from the monitoring means by the minimum delay time detected by the minimum delay time detecting means. And an optical information recording device provided with light intensity control means for controlling the light intensity of the light emitted from the light source based on the sampling result.
[0014]
(3) A light source emits light at a predetermined light intensity based on the recording data to generate a plurality of pulse trains of light, and the generated light is irradiated on a recording medium to form a recording mark corresponding to the recording data. In the optical information recording device, the light emitted from the light source is modulated at a light intensity based on the recording data, and the modulated light is irradiated on the recording medium, and the reflected light is reflected light from the recording medium. Reflected light intensity detecting means for detecting light intensity; delay time detecting means for detecting a delay time between the output of the detection result by the reflected light intensity detecting means and the output of the recording data; and An optical information recording apparatus provided with a control means for outputting the output earlier by the delay time detected by the time detecting means.
[0015]
(4) A light source emits light at a predetermined light intensity based on the recording data to generate a plurality of pulse trains of light, and the generated light is irradiated on a recording medium to form a recording mark corresponding to the recording data. In the optical information recording device, the light emitted from the light source is modulated at a light intensity based on the recording data, and the modulated light is irradiated on the recording medium, and the reflected light is reflected light from the recording medium. Reflected light intensity detecting means for detecting light intensity, and minimum delay time detection for detecting the minimum delay time between the output of the detection result by the reflected light intensity detecting means and the output of delayed data obtained by sequentially delaying the recording data An optical information recording apparatus comprising: means for outputting the recording data by a minimum delay time detected by the minimum delay time detection means.
[0016]
(5) The optical information recording device according to any one of (1) to (4), wherein the increment of the delay time is a timing pulse for causing the light source to emit a pulse train.
(6) In the optical information recording apparatus according to any one of (1) to (5), a pulse of a predetermined power is added for a predetermined time after the rise of at least a part of the pulse train, and the width of the added pulse is adjusted. An optical information recording apparatus provided with means for controlling the formation of the recording mark by performing the above.
(7) The optical information recording apparatus according to (2) or (4), wherein the detection of the minimum delay time by the minimum delay time detecting means is performed before recording the recording mark on the recording medium.
[0017]
Also, the following optical information recording methods (8) to (14) are provided.
(8) A light source emits light at a predetermined light intensity based on the recording data to generate light of a plurality of pulse trains, and the generated light is applied to a recording medium to form a recording mark corresponding to the recording data. In the optical information recording method, the light emitted from the light source is modulated by the light intensity based on the recording data to monitor the light intensity, the monitoring result is output, and the monitoring result output and the recording data output are output. An optical information recording method of detecting the delay time between the two, sampling the output of the monitoring result with a delay of the delay time, and controlling the light intensity of the light emitted from the light source based on the sampling result.
[0018]
(9) The light source emits light at a predetermined light intensity based on the recording data to generate light of a plurality of pulse trains, and the generated light is irradiated on a recording medium to form a recording mark corresponding to the recording data. In the optical information recording method, the light emitted from the light source is modulated by the light intensity based on the recording data to monitor the light intensity, the monitoring result is output, and the monitoring result output and the recording data output are output. An optical information recording method for detecting the minimum delay time between the above, sampling the output of the monitoring result with a delay by the minimum delay time, and controlling the light intensity of the light emitted from the light source based on the sampling result.
[0019]
(10) The light source emits light at a predetermined light intensity based on the recording data to generate light of a plurality of pulse trains, and the generated light is applied to a recording medium to form a recording mark corresponding to the recording data. In the optical information recording method, the light emitted from the light source is modulated at a light intensity based on the recording data, and the modulated light is irradiated on the recording medium, and the reflected light is reflected light from the recording medium. An optical information recording method for detecting light intensity, detecting a delay time between the output of the detection result and the output of the recording data, and outputting the recording data earlier by the delay time.
[0020]
(11) The light source emits light at a predetermined light intensity based on the recording data to generate light of a plurality of pulse trains, and the generated light is applied to a recording medium to form a recording mark corresponding to the recording data. In the optical information recording method, the light emitted from the light source is modulated at a light intensity based on the recording data, and the modulated light is irradiated on the recording medium, and the reflected light is reflected light from the recording medium. Optical information for detecting the light intensity, detecting the minimum delay time between the output of the detection result and the output of the delay data obtained by sequentially delaying the recording data, and outputting the recording data earlier by the minimum delay time Recording method.
[0021]
(12) The optical information recording method according to any one of (8) to (11), wherein the step of the delay time is a timing pulse for causing the light source to emit a pulse train.
(13) In the optical information recording method according to any one of (8) to (12), a pulse of a predetermined power is added for a predetermined time after the rise of at least a part of the pulse train, and the width of the added pulse is adjusted. An optical information recording method for controlling the formation of the recording mark by performing the method.
(14) The optical information recording method according to (9) or (11), wherein the detection of the minimum delay time by the minimum delay time detecting means is performed before the recording mark is recorded on the recording medium.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings.
FIG. 1 is a block diagram showing a configuration of a light source driving device according to a first embodiment of the present invention.
FIG. 2 is an example of a waveform diagram of a signal of each part of the light source driving device shown in FIG. 1, and is a diagram for explaining a recording method of the present embodiment.
A light source driving unit 1 in FIG. 1 includes an irradiation level setting unit 2 for setting irradiation levels P0, P1, and P2 of a laser diode (LD) as a light source, and a modulation signal of an LD based on a recording data signal Wdata and a recording clock signal WCK. A modulation signal generator 4 for generating Mod1 and Mod2 is provided.
[0023]
Further, the modulation unit 3 that generates the LD modulation current Imod based on the irradiation level data P0Data, P1Data, P2Data and the modulation signals Mod1 and Mod2 respectively corresponding to the irradiation levels P0, P1 and P2 of the LD, and the modulation signal generation unit 4 Based on the generated modulation timing (corresponding to the rise / fall timing of the modulation signals Mod1 and Mod2 or a part thereof), the overshoot current Ios for superimposing the additional power on the heating pulse and the additional power on the cooling pulse are superimposed. An additional current generating unit 18 that generates an undershoot current Ius (hereinafter, Ios and Ius are collectively referred to as additional currents), and a monitor light receiving signal from a monitor light receiving unit PD that monitors a part of light emitted from the LD; Based on the monitor light receiving signal, the emitted light amount of the LD reaches a desired value. And a LD control unit 7 which controls the scale signal Iscl instructing the scale of the bias current Ibias and the modulation current so that.
[0024]
Further, the LD modulation current Imod and the bias current Ibias are added, and the overshoot current Ios is added to subtract the undershoot current Ius, and the current ILD ′ supplied from the addition / subtraction unit 5 is amplified. A current drive unit 6 for supplying a drive current ILD for the LD, a CD-R drive device, a CD-RW drive device, a DVD-R drive device, a DVD-RW drive device, a DVD + RW drive device on which the light source drive unit 1 is mounted; A control unit 17 is provided that receives a control command supplied from a controller 19 that controls the entire information recording device (or information recording / reproducing device) such as a DVD-RAM drive device and supplies a control signal to each unit.
[0025]
The modulation unit 3 supplies a current source 8 for supplying currents I0, I1, and I2 based on the irradiation level data P0Data, P1Data, and P2Data, and a current I1 according to modulation signals Mod1 and Mod2 (comprising P0DAC8a, P1DAC8b, and P2DAC8c). , I2, and a switch 9 comprising switches 9b and 9c, and an adder 10 for adding each current output from the switch 9 and supplying an LD modulation current Imod.
[0026]
Further, the additional current generator 18 generates additional signals (ModO and ModU, respectively) that specify a period in which the overshoot current Ios and the undershoot current Ius are superimposed based on the modulation timing generated by the modulation signal generator 4. The signal generation unit 11, the additional power setting unit 16 that sets the current values I3 and I4 of the overshoot current Ios and the undershoot current Ius and supplies the setting data P3Data and P4Data, and the overshoot current setting data P3Data or the undershoot. The current sources P3DAC13a and P4DAC13b for respectively supplying the currents I3 and I4 based on the current setting data P4Data, and the currents I3 and I4 are controlled on and off in accordance with the additional signals ModO and ModU, respectively. Switch 14a to generate the s and undershoot current Ius, 14b and consists of overshoot current Ios and undershoot current Ius additional time setting unit 15 for setting an additional time.
[0027]
Since the LD control unit 7 may apply a known technique, a detailed description of its configuration and operation is omitted. However, the bias current Ibias is controlled to be substantially equal to the threshold current Ith of the LD, and the scale signal Iscl is Control is performed according to the differential quantum efficiency of the LD.
[0028]
FIG. 2 is a diagram showing an example of a signal waveform of each main signal in FIG.
Here, the case of recording on a phase change type recording medium is illustrated, and the light waveform shown in FIG. 3C is a desired light waveform, and the light waveform shown in FIG. The recording mark shown in () is formed.
Pb, Pe, and Pw shown in (c) of the figure are the irradiation levels of the bottom power level, the erase power level, and the write power level, respectively, and are the irradiation levels at which the current ILD 'becomes Ibias + I0, Ibias + I0 + I1, and Ibias + I0 + I2, respectively.
[0029]
That is, the irradiation level is determined by the irradiation level data P0Data, P1Data, and P2Data for setting the current values I0, I1, and I2, respectively.
Pw2 is an irradiation level obtained by adding power to the write power level Pw, and the added power (Pw2-Pw) corresponds to I3.
Similarly, Pb2 is the irradiation level obtained by subtracting the power corresponding to I4 from the bottom power level Pb.
Then, of the multi-pulse train, the leading edge TP of the recording mark shown in (d) of the figure by the leading pulse TP and the next cooling pulse, and the (d) of the figure by the last pulse LP and the next cooling pulse. The intermediate portion b1, b2 shown in FIG. 3D is formed by the intermediate pulse MP and the next cooling pulse at the trailing edge c of the recording mark shown in FIG. One recording mark corresponding to Wdata is created.
[0030]
The modulation signal Mod1 shown in (e-1) of the figure and the Mod2 shown in (e-2) of the figure are drive waveform information for instructing the modulation timing of a desired optical waveform preset in the modulation signal generation unit 4. Is generated corresponding to the recording data signal Wdata shown in FIG.
The additional signal ModO shown in (f-1) of the figure is added to the additional signal generation unit 11 in synchronization with the rise of the modulation signal Mod1 or Mod2 by the additional time (To1, To2, To3) are generated to be "high (H)".
The additional time (To1, To2, To3) indicates the additional time to TP, MP, and LP, respectively. Thus, an overshoot current Ios is generated and added to the LD drive current.
[0031]
Similarly, the additional signal ModU shown in (f-2) of the figure is the additional time (Tu1, Tu2, Tu3) of the undershoot current specified by the additional time setting unit 15 in synchronization with the fall of the modulation signal Mod2. ) Is generated to be “high (H)”.
A drive current ILD is generated according to the modulation signal and the additional signal, and an optical waveform ((d) in FIG. 4) corresponding to the drive current ILD is obtained.
In other words, an additional power is added at the rise of the heating pulse, and a light waveform is subtracted by the additional power at the fall of the heating pulse (at the beginning of the cooling pulse).
[0032]
FIG. 3 is a waveform diagram showing the relationship between the overheating pulse obtained by adding the additional power described in FIG. 2 and the irradiation energy.
An optical waveform a shown in FIG. 9A is a waveform when the additional power ΔP is not added, and optical waveforms b to e are waveforms in which the additional power width is sequentially increased.
Since the irradiation energy is a value obtained by integrating the irradiation power, the irradiation energy corresponding to each of the light waveforms a to e is as shown in FIG.
The light waveforms c ′ and e ′ are obtained by adjusting the irradiation energy by changing the heating pulse width without applying additional power. Irradiation energy equivalent to the light waveforms c and e is applied to each. As described above, the formation of the recording mark is performed by raising the temperature by the irradiation light. Therefore, by improving the resolution of the irradiation energy, the heat change of the medium can be accurately controlled, and the mark formation control can be accurately performed.
[0033]
That is, as in the present embodiment, by adding the additional power to the heating pulse and adjusting the additional power width, the resolution of the irradiation energy can be improved without improving the pulse width resolution, and the accuracy is high. Mark formation control becomes possible. This works more favorably during high-speed recording where it is difficult to improve the pulse width resolution.
Similarly, by subtracting the additional power from the cooling pulse, the cooling speed can be controlled with higher precision, and more accurate mark formation control can be performed.
Further, by adjusting the additional signal pulse widths (To1, To2, To3 and Tu1, Tu2, Tu3) added to the leading pulse TP, the intermediate pulse MP, and the final pulse LP, respectively, the leading edge portion, the intermediate portion, The shapes of the trailing edge portions can be formed with high accuracy, and recording marks can be uniformly formed with high accuracy.
[0034]
By the way, depending on the recording medium, the thermal conductivity is high, and the formation of the recording mark is affected by heat from the recording marks before and after the recording mark due to the heat storage effect, causing an edge shift, particularly in a dye-based write-once recording medium. .
Therefore, conventionally, the pulse width of the recording pulse is adjusted according to the space length before and after the recording mark.
However, as described above, it is difficult to improve the time resolution of the pulse width adjustment at the time of high-speed recording.
A preferred embodiment in this case will be described again with reference to FIGS. Those that perform the same operations and functions as described above will not be described.
[0035]
The modulation signal generator 4 measures the run length of the input recording data signal Wdata, and supplies the mark length M1, the immediately preceding space length S0, and the immediately succeeding space length S1 to the additional time setting unit 15. At the same time, modulation signals Mod1 and Mod2 are also generated based on M1, S0 and S1.
The additional time setting unit 15 selects the additional time (To1, To2, To3 and Tu1, Tu2, Tu3) corresponding to the supplied M1, S0, S1, and supplies it to the additional signal generation unit 11.
[0036]
With this configuration, the irradiation energy can be adjusted in consideration of the thermal influence from the adjacent recording mark, and a more accurate recording mark can be formed.
If each additional time is corrected by a run length having a higher influence, the circuit can be reduced in addition to the above-described effects.
That is, the additional times To1 and Tu1 to the first pulse TP are set according to the immediately preceding space S0 and the mark length M1, and the additional times To3 and Tu3 to the last pulse LP are set according to the mark length M1 and the immediately following space length S1. Good. Further, the additional times To2 and Tu2 to the intermediate pulse MP may be set according to the mark length M1.
[0037]
Next, a description will be given of a preferred embodiment in the case of using an LD in which a delay in rising / falling of an optical waveform (referred to as “rounding”) occurs due to the above-described junction capacitance of the LD.
In the light source driving device shown in FIG. 1, the additional time set by the additional time setting unit 15 is added by an amount substantially corresponding to the charge / discharge current to the junction capacitance of the LD.
That is, if the added amount of the additional time is Δt, Δt is set so that Δt · I3 is the charging current to the junction capacitance.
[0038]
FIG. 4 is a waveform chart for explaining the additional time set by the additional time setting unit 15 shown in FIG.
The waveform a of the drive current ILD of the LD shown in (i) of the figure is a case where the overshoot current Ios is not added at the time of the rise of the drive current, and the waveforms b to d sequentially increase the addition time of the overshoot current Ios. Is the case.
The optical waveforms shown in (ii) of the figure are examples of respective optical waveforms for the drive current ILD. The light waveform a has a rising edge due to the charging current to the junction capacitance of the LD, and the light waveform b is a case where the added overshoot current Ios is applied just as the charging current. When the additional time is further increased, the additional power is added as shown by the optical waveforms c and d, and the function of improving the irradiation energy resolution is achieved as in the previous embodiment.
[0039]
A part of the overshoot current Ios and the undershoot current Ius generated and superimposed in this manner are applied as charging / discharging current to the junction capacitance of the LD to be driven, so that the rising / falling of the optical waveform is thereby caused. The time delay (rounding) can be suppressed, and the remaining power can be added to the heating pulse, and the resolution of the irradiation energy can be improved without increasing the pulse width resolution. As a result, Light can be emitted with a desired light waveform including the additional pulse, and accurate recording marks can be formed.
[0040]
Since the junction capacity differs depending on the LD used, setting the current value so that the charge of the charge / discharge current is appropriate for the LD to be used can be applied as the charge / discharge current without excess or deficiency. And a more accurate recording mark can be formed. In the present embodiment, the superimposed current value setting section 16 fulfills its function. The same effect can be obtained by changing the additional time of the overshoot current Ios and the undershoot current Ius. In the present embodiment, the additional time setting unit 15 fulfills its function. Of course, they may be combined.
[0041]
Furthermore, it is more preferable to change the current value or the additional time of the overshoot current Ios and the undershoot current Ius according to the changing irradiation level difference.
That is, the amount of change in the potential difference between the cathode and the anode of the LD varies depending on the changing irradiation level difference (for example, Pe → Pw, Pb → Pw, Pb → Pe), so that the charge / discharge current also differs. Therefore, if the superposition time (To1, To2, To3) is changed according to the changing irradiation level difference, the delay (rounding) of the rise / fall time of the optical waveform can be more accurately suppressed. The same effect can be obtained by changing the current value.
[0042]
FIG. 5 is a block diagram showing a configuration of the information recording apparatus of this embodiment.
In this information recording apparatus, a recording data signal Wdata is output from a digital LSI 21, and the recording data signal Wdata is input to a Strategy (recording waveform) generating unit 22, converted into a recording waveform, and transmitted to an LD driver (LD-Driver unit) 23. Sent to actually modulate the laser drive current.
The output of the laser light thus modulated enters the optical system 25 as Pout, and a part of the output enters the FSPD 26 as a monitor (Pmon) and is converted into a voltage signal Smon by an IV amplifier (IV-AMP) 27. .
[0043]
On the other hand, most of the Pout is emitted to the recording surface (media surface) of the recording medium (media) 20, reflected on the media surface, passes through the optical system 25, and enters the OPIC (detection IC) 28 as reflected light Pdet. , OPIC 28, and the converted voltage signal Sig is sent to AFE 29.
The AFE 29 performs preprocessing as an analog signal (various matrix operations and the like), and the digital LSI 21 performs processing according to the servo signal / RF signal and the like. Here, the voltage signal Smon is also input to the AFE 29 and digitized by the sampling signal SMP controlled by the digital LSI 21.
From the digitized value, the digital LSI 21 controls the laser drive current so that the LD 24 has an appropriate laser output.
[0044]
FIG. 6 is a block diagram showing the internal configuration of the AFE 29 shown in FIG. 5 in a little more detail. The voltage signal Sig in FIG. 5 is a plurality of analog signals, and the AFE 29 performs a matrix operation and amplification on the signals with a matrix amplifier (Matrix AMP) 30 to obtain wobble (WBL) RF-AGC 32, RF-AGC 33, and a track. The count (Track Count) unit 34, DPD 35, OPC detector (Detector) 36, DFCT and other detectors (Detector) 37 detect signals such as wobble, RF, track (Track), DPD, OPC, and DFCT, respectively. In addition, it also has a serial (Serial) I / F 31, a tilt detector (Tilt Detector) 38, a WBL detector 39, an RF equalizer (Equalizer) 40, a cerbody detector (Servo Detector) 41, and an A / D 42.
[0045]
Here, the phase detector (Phase-Detector) 43 inside the AFE 29 compares the phases of Smon and SMP in the test mode 1, and inputs the P-Det to the digital LSI 21 as a result.
In the test mode 1, the recording data signal Wdata is simply a signal which repeatedly repeats "high (H)" and "low (L)". As a result, the output of the LD driver 23 is similarly modulated by the power of the reproduction level. The strategy (recording waveform) is set as follows.
[0046]
In the digital LSI 21, the SMP timing is controlled by a delay control unit (Delay Control) 51 so that the P-Det output from the phase detector 43 is minimized. The minimum timing in this way is stored in the internal register of the digital LSI 21 as P-Delay, and is used as the delay time of the SMP signal when sampling the Smon by the delay unit 52.
[0047]
By doing so, as shown in FIG. 7A, Smon is delayed with respect to Pout. Therefore, in order to sample the high-power (High-Power) portion of Pout, (c) in FIG. The SMP signal is changed to the timing indicated by the dotted line because the sampling error caused by sampling at the solid line portion (high-power sample: High-Power Sample) of the SMP shown in FIG. Sampling can be performed, and the detection accuracy of laser light can be increased even when the operation speed is improved.
[0048]
In the test mode 2, the laser beam is simply modulated in accordance with the recording data signal Wdata in the same manner as in the test mode 1.
At this time, the phase detector 43 compares the phase of the RF signal inside the AFE 29 with the SMP, and inputs the result P-Det to the digital LSI 21.
The digital LSI 21 changes the delay time of the SMP so that the P-Det output from the phase detector 43 becomes minimum, and stores the delay time having the minimum value as an RF-Delay in an internal register.
The stored RF-Delay outputs the recording data signal Wdata earlier than the recording start time at the time of actual recording. Thus, the delay of the RF signal is corrected.
[0049]
FIG. 8 is a waveform chart showing timing when Smon is detected, and FIG. 9 is a waveform chart showing timing when sampling an RF signal.
By doing so, the recording data signal Wdata is output before RF-Delay from the time when the last position of the already recorded area is detected, and recording is to be started. As a result, the laser light is actually transmitted to the medium. The position of the irradiation start of recording is correct, and the recording can be performed by being added to the end of the already recorded area.
[0050]
That is, assuming that the time from the output of the recording data signal Wdata to the irradiation of the medium with the laser beam is T1 and the time from the detection of the reflected light from the medium is T2, the last position of the recorded area is detected. The disk must be irradiated with the laser before the time T2 before the time, which is T1 + T2 hours before in the recording data signal Wdata. From the detection method of RF-Delay, RF-Delay = T1 + T2.
[0051]
In the above description, the test mode is prepared and the optimum delay time is automatically detected. However, in order to detect the light output of the laser, a value is set simply in consideration of the delay of Smon for a certain time. It is effective even if you just keep it.
However, the accuracy is higher when the automatic adjustment mechanism is provided. In addition, it is also effective to set a value checked as an initial value in the same manner for RF-Delay. Also in this case, the accuracy can be improved by performing the automatic adjustment similarly.
[0052]
In general, a digital LSI generates a high frequency clock which is N times the recording channel clock to modulate a laser light source and generate recording timing by a plurality of pulse trains. Set the amount of time.
However, the strategy generation unit 22 may include a high-frequency clock generation unit. In this case, a smaller delay time may be set using the high-frequency clock of the strategy generation unit 22. At this time, the final fine adjustment is performed on the LD driver 23 side, and the LD driver 23 side has a function of finely adjusting the delay time by serial communication or the like.
[0053]
In this manner, in an optical information recording method in which a recording mark is formed by irradiating a medium with light emitted by a plurality of pulse trains of a light source, the light source is modulated by irradiation intensity that does not form a recording mark by recording data, and the light source is modulated. The delay time between the output of the monitor unit to be monitored and the recorded data is held, and the output of the monitor unit is sampled after delaying the delay time to control the light intensity of the light source. The effect of the delay time until the output of the optical output monitor can be eliminated, and the monitor level can be taken in correctly even at the time of high-speed recording, so that optical information recording suitable for high-speed recording can be realized.
[0054]
Also, in an optical information recording method in which a recording mark is formed by irradiating a medium with light emitted by a plurality of pulse trains from a light source, the light source is modulated by irradiation intensity that does not form a recording mark by recording data, and reflected from the recording medium. Since the light intensity is detected, the delay time between the detection result and the recording data is held, and the recording data is output earlier by the delay time, the mark position detected as reflected light from the recording medium during high-speed recording and the recording position are recorded. The time lag of the start timing can be corrected, and optical information recording suitable for high-speed recording can be realized.
Further, the delay time between the delay data obtained by sequentially delaying the recording data and the output of the monitor section is detected, the minimum delay time of the detection result is held, and the output of the monitor section is sampled by delaying the minimum delay time. Since the light intensity is controlled, the delay time that fluctuates due to variations in temperature, IC, and the like can be automatically corrected, and optical information recording suitable for high-speed recording can be realized.
[0055]
Also, the delay time between the delay data obtained by sequentially delaying the recording data and the reflected light intensity from the medium is detected, the minimum delay time of the detection result is held, and the recording data is output earlier by the minimum delay time. , The delay time fluctuating due to variations in temperature, IC, etc., can be automatically corrected, and optical information recording suitable for high-speed recording can be realized.
Furthermore, since the increment of the delay time is a timing pulse for causing the light source to emit a pulse train, the correction can be performed at low cost and with high accuracy, and optical information recording suitable for high-speed recording can be realized.
[0056]
Further, since the increment of the delay time is a timing pulse for causing the above-described light source to emit a pulse train, correction can be performed at low cost and with high accuracy, and optical information recording suitable for high-speed recording can be realized.
Further, a pulse of a predetermined power is added for a predetermined time after the rise of at least a part of the pulse in the pulse train, and the formation of the recording mark is controlled by adjusting the width of the added pulse. The error can be corrected, and optical information recording suitable for high-speed recording can be realized.
Furthermore, since the minimum delay time is detected before recording, it is possible to re-correct a time error due to a difference between the temperature immediately before recording, each IC, an optical component, a used medium, and the like, thereby stably performing high-speed recording. A feasible optical information recording can be provided.
[0057]
【The invention's effect】
As described above, according to the optical information recording apparatus and the optical information recording method of the present invention, the time resolution of the irradiation time and the cooling time is not affected by the delay time of the recording system even during high-speed recording. Accurate recording mark formation can be performed without raising.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of a light source driving device according to a first embodiment of the present invention.
FIG. 2 is an example of a waveform diagram of signals of respective parts of the light source driving device shown in FIG. 1, and is a diagram for explaining a recording method of the present embodiment.
FIG. 3 is a waveform diagram showing a relationship between an overheating pulse obtained by adding an additional power described with reference to FIG. 2 and irradiation energy.
FIG. 4 is a waveform chart for explaining an additional time set by an additional time setting unit 15 shown in FIG. 1;
FIG. 5 is a block diagram illustrating a configuration of an information recording device according to an embodiment of the present invention.
6 is a block diagram showing the internal configuration of the AFE 29 shown in FIG. 5 in a little more detail.
FIG. 7 is a waveform chart for explaining sampling of Pout when Smon is delayed with respect to Pout.
FIG. 8 is a waveform chart showing timing when Smon is detected.
FIG. 9 is a waveform diagram showing timing when sampling an RF signal.
FIG. 10 is a diagram illustrating a problem in driving a light source in a conventional light source driving device.
FIG. 11 is a diagram showing an example of an optical waveform according to the description based on FIG. 10;
[Explanation of symbols]
1: light source driving unit 2: irradiation level setting unit
3: Modulation unit 4: Modulation signal generation unit
5: Addition / subtraction unit 6: Current drive unit
7: LD control unit 8, 8a, 8b, 8c: current source
9, 9b, 9c, 14a, 14b: switch
10: adder 11: additional signal generator
13a, 13b: current source
15: Additional time setting unit 16: Additional power setting unit
17: control unit 18: additional current generation unit
19: controller 20: recording medium
21: Digital LSI 22: Strategy generator
23: LD driver 24: LD
25: Optical system 26: FSPD
27: IV amplifier 28: OPIC
29: AFE 30: Matrix AMP
31: Serial I / F 32: WBL RF-AGC
33: RF AGC 34: Track count section
35: DPD 36: OPC detector
37: DFCT etc. Detector
38: Title Detector
39: WBL detector 40: RF equalizer
41: Surbody Tekta 42: A / D
43: Phase detector
51: Delay control section
52: delay section 201: LD drive section
203: LD equivalent model

Claims (14)

An optical information recording device that emits light at a predetermined light intensity based on recording data to generate light of a plurality of pulse trains, and irradiates the generated light to a recording medium to form a recording mark corresponding to the recording data; In the device,
Monitoring means for modulating light emitted by the light source with light intensity based on the recording data, monitoring the light intensity, outputting the monitoring result, outputting the monitoring result from the monitoring means, and outputting the recording data Delay time detecting means for detecting a delay time between the first and second light sources, and a monitor result output from the monitor means is sampled by delaying the output by the delay time detected by the delay time detecting means. An optical information recording apparatus, further comprising: a light intensity control means for controlling the light intensity of light to be emitted. An optical information recording device that emits light at a predetermined light intensity based on recording data to generate light of a plurality of pulse trains, and irradiates the generated light to a recording medium to form a recording mark corresponding to the recording data; In the device,
Monitoring means for modulating light emitted by the light source with light intensity based on the recording data, monitoring the light intensity, outputting the monitoring result, outputting the monitoring result from the monitoring means, and outputting the recording data Minimum delay time detecting means for detecting the minimum delay time between the first and the second delay means, and a monitor result output from the monitor means is sampled by delaying the output by the minimum delay time detected by the minimum delay time detecting means. An optical information recording device, comprising: light intensity control means for controlling the light intensity of light emitted by the light source based on the light intensity. An optical information recording device that emits light at a predetermined light intensity based on recording data to generate light of a plurality of pulse trains, and irradiates the generated light to a recording medium to form a recording mark corresponding to the recording data; In the device,
The light emitted from the light source is modulated at a light intensity based on the recording data, the modulated light is irradiated onto the recording medium, and the reflected light is detected to detect the light intensity of the reflected light from the recording medium. Light intensity detection means, delay time detection means for detecting a delay time between the output of the detection result by the reflected light intensity detection means and the output of the recording data, and the recording data is detected by the delay time detection means An optical information recording apparatus, further comprising control means for outputting the signal earlier by a predetermined delay time. An optical information recording device that emits light at a predetermined light intensity based on recording data to generate light of a plurality of pulse trains, and irradiates the generated light to a recording medium to form a recording mark corresponding to the recording data; In the device,
The light emitted from the light source is modulated at a light intensity based on the recording data, the modulated light is irradiated onto the recording medium, and the reflected light is detected to detect the light intensity of the reflected light from the recording medium. Light intensity detection means, minimum delay time detection means for detecting a minimum delay time between an output of a detection result by the reflected light intensity detection means and an output of delay data obtained by sequentially delaying the recording data, and the recording data And a control means for outputting the signal at an earlier time by the minimum delay time detected by the minimum delay time detection means. The optical information recording device according to any one of claims 1 to 4,
The optical information recording apparatus according to claim 1, wherein the increment of the delay time is a timing pulse for causing the light source to emit light in a pulse train. The optical information recording device according to any one of claims 1 to 5,
A means for controlling the formation of the recording mark by adding a pulse of a predetermined power for a predetermined time after the rise of at least a part of the pulse of the pulse train and adjusting the width of the added pulse is provided. Optical information recording device. The optical information recording device according to claim 2 or 4,
An optical information recording apparatus, wherein the detection of the minimum delay time by the minimum delay time detecting means is performed before recording a recording mark on the recording medium. An optical information recording device that emits light at a predetermined light intensity based on recording data to generate light of a plurality of pulse trains, and irradiates the generated light to a recording medium to form a recording mark corresponding to the recording data; In the method,
The light emitted by the light source is modulated by the light intensity based on the recording data to monitor the light intensity, the monitoring result is output, and the delay time between the output of the monitoring result and the output of the recording data is calculated. An optical information recording method, comprising: detecting, sampling the output of the monitoring result with a delay of the delay time, and controlling the light intensity of light emitted by the light source based on the sampling result. An optical information recording device that emits light at a predetermined light intensity based on recording data to generate light of a plurality of pulse trains, and irradiates the generated light to a recording medium to form a recording mark corresponding to the recording data; In the method,
The light emitted from the light source is modulated by the light intensity based on the recording data to monitor the light intensity, the monitoring result is output, and the minimum delay time between the output of the monitoring result and the output of the recording data And sampling the output of the monitoring result with a delay of the minimum delay time, and controlling the light intensity of the light emitted from the light source based on the sampling result. An optical information recording device that emits light at a predetermined light intensity based on recording data to generate light of a plurality of pulse trains, and irradiates the generated light to a recording medium to form a recording mark corresponding to the recording data; In the method,
The light emitted by the light source is modulated at a light intensity based on the recording data, and the modulated light is irradiated on the recording medium, and the light intensity of reflected light from the recording medium of the irradiated light is detected, An optical information recording method comprising: detecting a delay time between the output of the detection result and the output of the recording data; and outputting the recording data earlier by the delay time. An optical information recording device that emits light at a predetermined light intensity based on recording data to generate light of a plurality of pulse trains, and irradiates the generated light to a recording medium to form a recording mark corresponding to the recording data; In the method,
The light emitted by the light source is modulated at a light intensity based on the recording data, and the modulated light is irradiated on the recording medium, and the light intensity of reflected light from the recording medium of the irradiated light is detected, Optical information recording, wherein a minimum delay time between an output of the detection result and an output of delay data obtained by sequentially delaying the recording data is detected, and the recording data is output earlier by the minimum delay time. Method. The optical information recording method according to any one of claims 8 to 11,
The optical information recording method according to claim 1, wherein the step of the delay time is a timing pulse for causing the light source to emit light in a pulse train. The optical information recording method according to any one of claims 8 to 12,
An optical information recording method, wherein a pulse of a predetermined power is added for a predetermined time after the rise of at least a part of the pulse of the pulse train, and the width of the added pulse is adjusted to control the formation of the recording mark. . The optical information recording method according to claim 9 or 11,
An optical information recording method, wherein the detection of the minimum delay time by the minimum delay time detecting means is performed before recording a recording mark on the recording medium.

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