JP3577651B2 - Optical disk drive - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical disk drive for recording, erasing, and initializing information by irradiating a light amount emitted from a light source onto an optical disk as a pulse train having a frequency higher than a recording frequency, and particularly to a laser diode (semiconductor laser) of the light source. The present invention relates to a laser power control device for controlling the light emission power of (1).
[0002]
[Prior art]
The phase-change optical disk is a disk capable of high-density recording, and various types of information recording methods have been proposed.
[0003]
For example, a laser beam is irradiated with a short single pulse or a plurality of pulses to form an amorphous mark on a disk (JP-A-63-266632), or a high-frequency pulse train is used for crystallization. There is known a recording method such as irradiating a laser beam with a laser beam (Japanese Patent Laid-Open No. 1-119921).
[0004]
Here, a recording method in the phase change optical disk will be briefly described.
[0005]
FIGS. 11A and 11B are diagrams for explaining the principle of a recording method in a phase-change optical disk. FIG. 11A shows a relationship between recording information and laser power, and FIG. 11B shows a recording state on a track corresponding to the recording information. In the figure, Pp indicates an amorphization level, Pe indicates a crystallization level, and Pr indicates a read level.
[0006]
In the case of a phase-change type optical disk, when recording information, a laser spot is irradiated on the track of the disk and the laser power is changed according to the recorded information, so that a crystallized region and an amorphous region are formed on the recording film of the disk. This is done by forming a textured mark.
[0007]
This state is shown in FIG. 11A, in which the recording film is crystallized by setting the laser power to the crystallization level (Pe) in accordance with the level of the recording information “0”. Formation region is formed.
[0008]
On the other hand, by changing the laser power in a pulse form between the amorphization level (Pp) and the read level (Pr) in accordance with the level of “1” of the recording information, the recording film is formed. Is made amorphous to form an amorphous mark.
[0009]
By such a recording operation, as shown in FIG. 11 (2), an amorphous mark corresponding to the level "1" of the recorded information is formed on the track. Here, the relationship between the three levels is Pp (amorphization level)> Pe (crystallization level)> Pr (read level).
[0010]
In this manner, a crystallized area corresponding to the level of “0” of the recording information and an amorphization mark corresponding to the level of “1” of the recording information are formed on the phase-change optical disk. Therefore, as the laser power, the (intermediate) crystallization level (Pe) corresponding to the “0” level of the recording information and the (highest) amorphous level for forming the “1” level of the recording information are used. It is necessary to control at a total of three levels, namely the activation level (Pp) and the (lowest) readout level (Pr).
[0011]
[Problems to be solved by the invention]
In an optical disk drive such as a phase-change type optical disk that records, erases, or initializes information by irradiating a laser spot on the optical disk as a high-frequency pulse train, the laser power also changes at a high frequency.
[0012]
For this reason, if an output light amount detector having a limited detection band is used, it becomes difficult to accurately detect the output light amount.
[0013]
Even if the amount of emitted light is adjusted based on the inaccurately detected amount of emitted light, accurate adjustment is difficult, and it is also difficult to stabilize the amount of emitted light.
[0014]
As a result, a case may occur in which processing such as recording, erasing, and initialization of information becomes incomplete.
[0015]
SUMMARY OF THE INVENTION It is an object of the present invention to obtain an optical disk drive with high information reliability by stabilizing the amount of light emitted from a laser diode with an inexpensive and simple configuration.
[0016]
[Means for Solving the Problems]
The optical disk drive according to claim 1, further comprising: a light source such as a semiconductor laser; a driving circuit of the light source; and an emission light amount detection unit for detecting an emission light amount of the light source. In an optical disk drive for recording, erasing, and initializing information by irradiating a high-frequency pulse train onto the optical disk, a current applying means for applying a first level current to the light source as a laser power control device; A first current superimposing means for superimposing a second-level current on the one-level current; a second current superimposing means for superimposing a third-level current on the first-level current; First switch means for on / off control according to recording information, second switch means for pulse-on / off control of the third level current in accordance with recording information, First timing control means for generating a first control signal for turning on the third level current in a non-pulse manner; and a first sample for holding the output of the emitted light amount detection means during a period in which the first switch means is on. Holding means; second sample and hold means for holding the output of the emitted light quantity detection means during the generation period of the first control signal; and adjusting the second level current according to the output of the first sample and hold means First adjusting means for adjusting the current of the third level in accordance with the output of the second sample and hold means, adjusting the adjusted current of the second level, and adjusting the adjusted current of the third level. A subtractor for adjusting the first level current according to the value of the level current.
[0017]
According to a second aspect of the present invention, in the optical disk drive of the first aspect, the generation period of the first control signal is within a period according to the state of the recorded information.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is a functional block diagram showing a reference example 1 for describing an embodiment of a main part configuration of a laser power control device of an optical disk drive of the present invention.
[0019]
In FIG. 1, 1 is a laser diode, 2 is a photodetector, 3 is an amplifier, 4 is an Ip switch, 5 is an Ip current source, 6 is an Sp adjustment circuit, 7 is an Sp sample and hold circuit, 8 is an Ie switch, and 9 is an Ie current. Source, 10 is an Ie adjustment circuit, 11 is an Ie sample and hold circuit, 12 is an Ir current source, 13 is an Sr adjustment circuit, 14 is an Sr sample and hold circuit, 15 is a Pp sample timing circuit, 16 is a Pr sample timing circuit, 17 is An Ip switch control circuit, 18 denotes an Ie switch control circuit, Ir denotes a drive current at the read level (Pr), Ie denotes a current superimposed on the current Ir in order to set the crystallization level (Pe), and Ie ′ denotes a current Ie. The switched current, Ip, is a current superimposed on the current Ir to bring it to the amorphization level (Pp), and Ip ′ is the current Ip. The switched current, Sp is a sample signal for sampling a pulse signal at the amorphization level (Pp), Sr is a sample signal for sampling a pulse signal at the read level (Pr), Di is recording information, and Dp is Ip. An on / off signal of the switch 4, De represents an on / off signal of the Ie switch 8, and Vd represents a detection voltage of the amount of emitted light of the amplifier 3.
[0020]
The light emitted from the laser diode 1 is condensed by a lens and radiated onto a disk. A part of the emitted light is also radiated onto a photodetector 2 and its output is amplified by an amplifier 3 to reduce the amount of emitted light. Used for detection.
[0021]
Currents from three current sources (Ip current source 5, Ie current source 9, and Ir current source 12) are applied to the laser diode 1, and two of the current sources (Ip current sources 5, Ie). The current from the current source 9) is turned on / off by the Ip switch 4 and the Ie switch 8.
[0022]
First, the Ir current source 12 applies a current Ir necessary for setting the laser power to the read level Pr to the laser diode 1 (the lowest level).
[0023]
On the other hand, at the time of driving the crystallization level Pe, the current Ie from the Ie current source 9 is superimposed on the current Ir of the read level Pr as the current Ie ′ on / off controlled by the Ie switch 8 so as to be superimposed on the laser diode 1. Is applied.
[0024]
That is, during the operation of the Ie switch 8, a current Ir + Ie 'necessary for setting the laser power to the crystallization level Pe is applied to the laser diode 1 (an intermediate level).
[0025]
At the time of driving the amorphization level Pp, the current from the Ip current source 5 is superimposed on the current Ir at the read level Pr as a switching current Ip ′ that is turned on / off by the Ip switch 4. Applied to the diode 1. That is, when the Ip switch 4 is turned on, a current Ir + Ip ′ necessary for setting the laser power to the amorphous level Pp is applied to the laser diode 1 (the highest level).
[0026]
FIG. 2 is a timing chart for explaining the operation of the optical disk drive shown in FIG. The reference numerals given to the respective waveforms in the figure correspond to the reference positions in FIG. 1, where I is the current actually applied to the laser diode 1, P is the laser power by the current I, and a is "0" of the recording information Di. , B is the period of the “1” level of the record information Di, c is the period of generation of the sample signal Sr at the read level Pr, and d is the period of generation of the sample signal Sp at the amorphization level Pp. , (A) and (b) show signals in which the record information Di is not recorded.
[0027]
Ir shown in FIG. 2 is a current Ir required to bring the laser power to the read level Pr, and is a constant level current.
[0028]
When the crystallization level Pe is driven, as shown by Ie ', the current Ie from the Ie current source 9 is turned on / off by the Ie switch 8, and a switching current Ie' is generated.
[0029]
In order to perform such a switching operation at the crystallization level Pe, the Ie switch control circuit 18 of FIG. 1 outputs an on / off signal De of the Ie switch 8 according to the level of the record information Di at the time of information recording. .
[0030]
The on / off signal De of the Ie switch 8 becomes “H” level when the recording information Di is “0” (period a in FIG. 2), so that the Ie switch 8 is turned on and the laser diode 1 is turned on. Is applied with a current Ir + Ie.
[0031]
On the other hand, when the recording information Di is "1" (period b in FIG. 2), the on / off signal De of the Ie switch 8 becomes "L" level, and the Ie switch 8 is turned off.
[0032]
Therefore, the current Ir + Ie is applied to the laser diode 1 as indicated by I in FIG. As a result, as indicated by P in FIG. 2, a laser power at the crystallization level (Pe) is obtained during the period a in which the recording information Di is “0”.
[0033]
Therefore, during this period a, the recording film is crystallized to form a crystallized region as described with reference to FIG. 11B.
[0034]
On the other hand, at the time of driving the amorphization level Pp, the current from the Ip current source 5 is turned on / off by the Ip switch 4 to generate the switching current Ip 'as shown by Ip' in FIG. Is done.
[0035]
In order to perform the switching operation at the amorphization level Pp, the Ip switch control circuit 17 outputs an on / off signal Dp of the Ip switch 4 according to the level of the recording information Di at the time of recording information.
[0036]
The on / off signal Dp of the Ip switch 4 becomes “L” level when the recording information Di is “0” (period a in FIG. 2), and the Ip switch 4 is turned off.
[0037]
On the other hand, when the recording information Di is “1” (period b in FIG. 2), the on / off signal Dp of the Ip switch 4 changes in a pulse shape.
[0038]
Therefore, the Ip switch 4 is turned on / off in a pulse shape. During this period b, the level between the current Ir and the current Ir + Ip is applied to the laser diode 1 as indicated by I in FIG. A pulse-like current that changes in the range is applied. Therefore, in this period b, as described with reference to FIG. 11B, an amorphization mark corresponding to “1” of the recording information Di is formed.
[0039]
As described above, the laser power becomes the crystallization level (Pe) according to the “0” level of the recording information Di, and the laser power becomes amorphous according to the “1” level of the recording information Di. It changes like a pulse between the activation level (Pp) and the read level (Pr).
[0040]
Then, part of the light emitted from the laser diode 1 is detected by the photodetector 2 and its output is amplified by the amplifier 3, so that the emitted light amount detection voltage Vd of the amplifier 3 has a value proportional to the laser power.
[0041]
However, when the response band of the photodetector 2 and the amplifier 3 is limited, the pulsed light emitting unit corresponding to the period b indicated by Di in FIG. 2 cannot accurately detect the light amount.
[0042]
The waveform in this state repeats a small wavy change as shown by Vd in FIG.
[0043]
On the other hand, in the period a shown by Di in FIG. 2, the laser power is non-pulse at the crystallization level (Pe), so that the emitted light amount detection voltage Vd is, as shown in Vd in FIG. The value is proportional to the crystallization level Pe.
[0044]
Therefore, when the laser power is at a stable level (period a in FIG. 2), the emitted light amount detection voltage Vd is taken in and the laser power is controlled.
[0045]
In the apparatus of FIG. 1, the Ie sample and hold circuit 11 detects the amount of emitted light when the recording information Di is “0” and the on / off signal De of the Ie switch 8 is at “H” level (period a in FIG. 2). The voltage Vd is sampled.
[0046]
Therefore, a detection voltage proportional to the crystallization level (Pe) is always obtained at the output of the Ie sample and hold circuit 11.
[0047]
The Ie adjustment circuit 10 adjusts the Ie current source 9 based on the detection voltage so that the laser power P becomes an optimum value of the crystallization level (Pe).
[0048]
The above is the operation for adjusting the crystallization level (Pe) of the laser power. In the first embodiment, the light amount of the light source is adjusted at the non-pulse crystallization level (Pe) in which the laser power is stable.
[0049]
In Reference Example 1, a light source such as a semiconductor laser (the laser diode 1 in FIG. 1), a driving circuit of the light source (Ip switch 4, Ip current source 5), and an emission light amount detecting means (photodetector 2) for detecting the emission light amount of the light source And an amplifier 3), and irradiates the light amount emitted from the light source as a pulse train having a frequency higher than the recording frequency onto the optical disk to record, erase, and initialize information. Period setting means (Pr sample timing circuit 16 and Ie switch control circuit 18) for setting a period in which the light source is appropriately driven in a non-pulse manner, based on the emission light amount detected by the emission light amount detection means during the set period. And a light amount adjusting means (Ie sample and hold circuit 11, Ie adjusting circuit 10) for adjusting the light amount of the light source.
[0050]
As described above, in the first embodiment, since the output light amount is detected during the period in which the light source is driven in a non-pulse shape, even if the output light amount detector having a limited detection band is used, Can be accurately detected.
[0051]
Then, by adjusting the output light amount to an optimum value based on the detected output light amount, the light source is stabilized. Moreover, since the configuration is simple, a device with high information reliability can be obtained by low-cost means.
[0052]
Reference Example 2 will be described. In the first reference example, the case where the crystallization level (Pe) of the laser power is stabilized has been described. The reference example 2 is further characterized in that the amorphization level (Pp) and the readout level (Pr) can be stabilized. The hardware configuration is the same as in FIG. The operation is also the same as in the timing chart of FIG.
[0053]
According to the correspondence with FIG. 1, the configuration is as follows.
[0054]
A light source such as a semiconductor laser (laser diode 1 in FIG. 1), a driving circuit of the light source (Ip switch 4, Ip current source 5), and an emission light amount detecting means (photodetector 2, amplifier 3) for detecting an emission light amount of the light source. In the optical disk drive device for recording, erasing, and initializing information by irradiating the light amount emitted from the light source as a pulse train having a frequency higher than the recording frequency onto the optical disk,
As a laser power control device,
Current applying means (Ir current source 12) for applying a first level current (Ir) to the light source;
First current superimposing means (Ie current source 9) for superimposing the second level current (Ie) on the first level current (Ir);
Second current superimposing means (Ip current source 5) for superimposing the third level current (Ip) on the first level current (Ir);
First switch means (Ie switch 8) for controlling on / off of the second level current (Ie) according to the recording information (Di);
Second switch means (Ip switch 4) for controlling on / off of the third level current (Ip) in a pulse form according to the recording information (Di);
First timing control means (Pr sample timing circuit 16) for generating a first control signal (Sr) for turning off the third level current (Ip);
Second timing control means (Pp sample timing circuit 15) for generating a second control signal (Sp) for turning on the third level current (Ip) in a non-pulse manner;
First sample-and-hold means (Sr sample-and-hold circuit 14) for holding the output (Vd) of the emitted light amount detection means (photodetector 2, amplifier 3) during the generation period of the first control signal (Sr);
Second sample-and-hold means (Ie sample-and-hold circuit 11) for holding the output (Vd) of the output light amount detection means (photodetector 2, amplifier 3) during the ON period of the first switch means (Ie switch 8);
Third sample-and-hold means (Sp sample-and-hold circuit 7) for holding the output (Vd) of the output light quantity detection means (photodetector 2, amplifier 3) during the generation period of the second control signal (Sp);
First adjusting means (Sr adjusting circuit 13) for adjusting the first level current (Ir) according to the output of the first sample and holding means (Sr sample and hold circuit 14);
A second adjusting means (Ie adjusting circuit 10) for adjusting the second level current (Ie) according to an output of the second sample and holding means (Ie sample and hold circuit 11);
A third adjusting means (Sp adjusting circuit 6) for adjusting the third level current (Ip) according to the output of the third sample holding means (Sp sample holding circuit 7).
[0055]
In the first reference example, the Ie sample and hold circuit 11 of FIG. 1 operates in the period a shown by Di in FIG. 2, that is, when the recording information Di is “0” and the on / off signal De of the Ie switch 8 is “H”. The case where the output light quantity detection voltage Vd is sampled at the “level” has been described.
[0056]
In this case, a detection voltage proportional to the crystallization level (Pe) is always obtained at the output of the Ie sample and hold circuit 11. The Ie adjustment circuit 10 adjusts the Ie current source 9 based on the detected voltage (Vd) so that the laser power P becomes an optimum value of the crystallization level (Pe).
[0057]
Therefore, the crystallization level (Pe) can be adjusted to an optimum value, and thus can be stabilized. However, the amorphization level (Pp) and the read level (Pr) cannot be adjusted. In the reference example 2, the amorphization level (Pp) and the read level (Pr) are also adjusted to optimal values.
[0058]
In FIG. 1, the Pr sample timing circuit 16 appropriately generates a sample signal Sr for sampling a pulse signal at the read level (Pr).
[0059]
For example, as shown by Sr in FIG. 2, during a period c, the sample signal Sr is generated at “H” level. In Sr of FIG. 2, during the period of occurrence of Sr (the period c of “H” level), both the Ie switch control circuit 18 and the Ip switch control circuit 17 perform the Ie switch 8 operation regardless of the level of the recording information Di. And the Ip switch 4 is turned off.
[0060]
Therefore, during this period c, only the current Ir is applied to the laser diode 1, and as shown by P in FIG. 2, the laser power is Pr (read level) and non-pulse.
[0061]
By such an operation, during this period c, unlike the previous period a, the output light amount detection voltage Vd becomes a value proportional to Pr.
[0062]
The Sr sample-and-hold circuit 14 samples the output light amount detection voltage Vd during the generation period (period c) of the sample signal Sr shown in Sr in FIG. Therefore, a detection voltage proportional to the read level (Pr) is always obtained at the output of the Sr sample and hold circuit 14.
[0063]
The Sr adjustment circuit 13 adjusts the Ir current source 12 based on the detection voltage output from the Sr sample and hold circuit 14 so that the laser power becomes an optimal value of the read level (Pr).
[0064]
The above is the operation of adjusting the read level (Pr) of the laser power.
[0065]
Next, adjustment of the amorphization level (Pp) of the laser power will be described.
[0066]
The Pp sample timing circuit 15 appropriately generates a Pp sample signal Sp, as indicated by Sp in FIG. For example, during the period d of Sp in FIG. 2, the sample signal Sp is generated at the “H” level.
[0067]
In the Sp of FIG. 2, during the Sp generation period (“H” level period d), the Ip switch control circuit 17 turns off the Ip switch 4 regardless of the level of the recording information Di.
[0068]
Therefore, during this period d, the current Ir + Ip is applied to the laser diode 1, and the laser power is Pp (amorphization level) and non-pulse as shown by P in FIG.
[0069]
Due to such an operation, the light amount detection voltage Vd becomes a value proportional to the amorphization level (Pp) even during this period d, unlike the period a.
[0070]
Since the Sp sample hold circuit 7 samples the light amount detection voltage Vd during the generation period (period d) of the sample signal Sp indicated by Sp in FIG. 2, the output of the Sp sample hold circuit 7 is always amorphous. A detection voltage proportional to the activation level (Pp) is obtained.
[0071]
The Sp adjusting circuit 6 adjusts the Ip current source 5 based on the detection voltage output from the Sp sample hold circuit 7 so that the laser power becomes an optimal value of the amorphization level (Pp). .
[0072]
With such a configuration, it is possible to stabilize not only the crystallization level (Pe) but also the amorphization level (Pp) and readout level (Pr) of the laser power.
[0073]
As in the first embodiment, even if an output light amount detector having a limited detection band is used, the output light amount can be accurately detected, and the output light amount is set to an optimum value based on the detected output light amount. The adjustment stabilizes the light source.
[0074]
Reference Example 3 will be described. In the apparatus described in the reference example 2, regardless of the state (level) of the recording information Di, the laser power is set to the read level (Pr) while the first control signal (Sr) is generated, and to the second control signal (Sp). ), The non-pulse-like amorphous level (Pp) occurs.
[0075]
Therefore, during the generation of the first or second control signal (Sr or Sp), information cannot be recorded, and the information capacity that can be recorded on the optical disc decreases.
[0076]
In the third embodiment, the generation period of the second control signal (Sp) is set to coincide with the period in which an amorphous mark is to be formed in accordance with the state of the recording information Di. This is characterized in that it is generated during recording of the data.
[0077]
The hardware configuration is the same as in FIG.
[0078]
FIG. 3 is a timing chart for explaining a laser driving operation according to the reference example 3 with respect to the optical disk drive shown in FIG. The reference numerals given to the respective waveforms in the figure are the same as those in FIG.
[0079]
As shown in FIG. 3, the Pp sample timing circuit 15 appropriately generates the pulse signal at the amorphization level (Pp) only during the period of the “1” level of the recording information Di (period d in FIG. 3). Is generated.
[0080]
In this case, although the laser power is generated in a non-pulse shape during the period d of Sp in FIG. 3, the laser power is at the amorphization level Pp, so that an amorphous mark is formed on the disk in accordance with the recording information Di. Formed.
[0081]
Therefore, in the case of FIG. 3, information (the signal (a)) cannot be recorded in the period c, but information can be recorded in the period d.
[0082]
That is, in the reference example 2 (in the case of FIG. 2), information (signals (a) and (b)) corresponding to the record information Di could not be recorded in the periods c and d. According to Example 3 (in the case of FIG. 3), the information (the signal (a)) cannot be recorded only in the period c.
[0083]
Therefore, only during the generation of the first control signal (Sr) is a portion where information cannot be recorded, and it is possible to reduce a decrease in the information capacity recordable on the optical disk.
[0084]
Reference Example 4 will be described. In Reference Example 2, the detection of the amount of emitted light is performed for each of the amorphization level (Pp), the crystallization level (Pe), and the readout level (Pr).
[0085]
In the reference example 4, the ratio between the superimposed currents Ip and Ie is set in advance to a value such that optimum laser powers Pp (amorphization level) and Pe (crystallization level) are obtained. The laser beam power, for example, the amount of emission at Pe (crystallization level) is detected and set to an optimum value, thereby setting the other Pp (amorphization level) to the optimum value. Is also characterized in that it is stabilized.
[0086]
FIG. 4 is a functional block diagram of Reference Example 4. The reference numerals in the figure are the same as those in FIG. 1, and 21 indicates an amplifier circuit.
[0087]
The device shown in FIG. 4 is different from the device shown in FIG. 1 in that the Sp adjustment circuit 6, the Sp sample hold circuit 7, and the Pp sample timing circuit 15 are omitted, and an amplifier circuit 21 is added instead.
[0088]
Then, the amplification circuit 21 amplifies the output of the Ie adjustment circuit 10 with a constant gain and adjusts the Ip current source 5. The basic configuration is the same as in FIG. 1 described above, and the operation is also the same as in FIG.
[0089]
FIG. 5 is a timing chart for explaining a laser driving operation according to the reference example 4 in the optical disk drive shown in FIG. The reference numerals given to the respective waveforms in the figure are the same as those in FIG. 2, and correspond to the reference positions in FIG.
[0090]
4, the Pr sample timing circuit 16 appropriately generates a sample signal Sr for sampling a pulse signal at the read level (Pr).
[0091]
For example, as shown in Sr in FIG. 5, during a period c, the sample signal Sr is generated at the “H” level.
[0092]
In the Sr of FIG. 5, during the period of occurrence of Sr (the period “c” at the “H” level), the Ie switch control circuit 18 and the Ip switch control circuit 17 both switch the Ie switch 8 regardless of the level of the record information Di. And the Ip switch 4 is turned off.
[0093]
Therefore, during this period c, only the current Ir is applied to the laser diode 1, so that the laser power is Pr (read level) and non-pulse as shown by P in FIG.
[0094]
By such an operation, during this period c, unlike the previous period a, the light amount detection voltage Vd becomes a value proportional to Pr.
[0095]
The Sr sample and hold circuit 14 samples the light amount detection voltage Vd during the generation period (period c) of the sample signal Sr shown in Sr in FIG.
[0096]
Therefore, a detection voltage proportional to the read level (Pr) is always obtained at the output of the Sr sample and hold circuit 14.
[0097]
The Sr adjustment circuit 13 adjusts the Ir current source 12 based on the detection voltage output from the Sr sample and hold circuit 14 so that the laser power becomes an optimal value of the read level (Pr).
[0098]
The above is the operation of adjusting the read level (Pr) of the laser power, which is the same as that in FIGS. 1 and 2 described above.
[0099]
As described above, in the fourth embodiment, the newly added amplifier circuit 21 amplifies the output of the Ie adjustment circuit 10 with a constant gain to adjust the Ip current source 5.
[0100]
Therefore, the value of the current Ip from the Ip current source 5 and the value of the current Ie from the Ie current source 9 are always adjusted to a fixed ratio.
[0101]
More specifically, the value of the current Ip superimposed on the current Ir to obtain the amorphization level (Pp) and the value of the current Ie superimposed on the current Ir to obtain the crystallization level (Pe) are always constant. Adjusted to the ratio.
[0102]
Here, the relationship between the current I of the laser diode 1 (I in FIG. 5) and the laser power P (P in FIG. 5) will be described.
[0103]
FIG. 6 is a characteristic diagram showing the relationship between the current I and the laser power P of the laser diode 1 according to the reference example 4 in the optical disk drive shown in FIG. In the figure, the horizontal axis represents the current I of the laser diode 1 and the vertical axis represents the laser power P. A and B represent different characteristic curves, respectively, and Ith1 and Ith2 represent current thresholds.
[0104]
As shown in FIG. 6, the characteristics of the current I and the power P of the laser diode 1 change like the characteristic curves A and B due to the influence of the ambient temperature and the like.
[0105]
However, the characteristics are almost linear when the threshold currents are Ith1 and Ith2 or more.
[0106]
Therefore, even if the slope of the characteristic curve changes, the drive current Ir of the read level (Pr) and the current Ie superimposed on the current Ir to obtain the crystallization level (Pe) are constant levels Pr and Pe, respectively. And the current Ie that is superimposed on the current Ir in order to obtain the crystallization level (Pe) is adjusted so that the current Ie superimposed on the current Ir in order to obtain the crystallization level (Pe). Is adjusted to a constant ratio, the Ip switch 4 of FIG. 4 is turned on, and when the current Ir + Ip is applied to the laser diode 1, a constant laser power Pp (amorphization level) Is obtained.
[0107]
That is, if the ratio between the currents Ip and Ie is set in advance to a value at which the optimum laser power Pp (amorphization level) and Pe (crystallization level) can be obtained, the amorphization level can be increased. By simply stabilizing the current Ip superimposed on the current Ir so as to obtain (Pp), the other superimposed current Ie is also stabilized.
[0108]
As described above, in the fourth embodiment, the readout level (Pr) and the crystallization level (Pe) are detected, and the drive current Ir and the superimposition current Ie are adjusted to the optimum values, respectively. The current Ip to be superimposed on the current Ir in order to attain the activation level (Pp) is automatically set to an optimum value from a preset ratio with the superimposed current Ie (the ratio between Ie and Ip). The amorphization level (Pp) also has an optimum value.
[0109]
Conversely, when the current Ip is applied at a predetermined optimum ratio to the current Ie, the laser power Pp (amorphization level) is also set to an optimum value. That is, even if the drive current Ir and the superimposed current Ip are adjusted to optimal values instead of the superimposed current Ie, the ratio between the preset superimposed current Ip (the ratio between Ip and Ie) is automatically calculated. It is possible to set the optimal power level.
[0110]
The configuration is as follows according to the correspondence with FIG.
[0111]
A light source such as a semiconductor laser (laser diode 1 in FIG. 4), a driving circuit for the light source (Ip switch 4, Ip current source 5), and an emission light amount detecting means (photodetector 2, amplifier 3) for detecting the emission light amount of the light source. In an optical disc drive device for recording, erasing, and initializing information by irradiating the light quantity emitted from the light source on the optical disc as a pulse train having a frequency higher than the recording frequency,
As a laser power control device,
Current applying means (Ir current source 12) for applying a first level current (Ir) to the light source;
First current superimposing means (Ie current source 9) for superimposing the second level current (Ie) on the first level current (Ir);
Second current superimposing means (Ip current source 5) for superimposing the third level current (Ip) on the first level current (Ir);
First switch means (Ie switch 8) for controlling on / off of the second level current (Ie) according to the recording information (Di);
Second switch means (Ip switch 4) for controlling on / off of the third level current (Ip) in a pulse form according to the recording information (Di);
First timing control means (Pr sample timing circuit 16) for generating a first control signal (Sr) for turning off the third level current (Ip);
First sample-and-hold means (Sr sample-and-hold circuit 14) for holding the output (Vd) of the emitted light amount detection means (photodetector 2, amplifier 3) during the generation period of the first control signal (Sr);
Second sample-and-hold means (Ie sample-and-hold circuit 11) for holding the output (Vd) of the output light amount detection means (photodetector 2, amplifier 3) during the ON period of the first switch means (Ie switch 8);
First adjusting means (Sr adjusting circuit 13) for adjusting the first level current (Ir) according to the output of the first sample and holding means (Sr sample and hold circuit 14);
A second adjusting means (Ie adjusting circuit 10) for adjusting the second level current (Ie) according to an output of the second sample and holding means (Ie sample and hold circuit 11);
A fourth adjusting means (amplifying circuit 21) for adjusting the third level current (Ip) to have a value proportional to the second level current (Ie).
[0112]
According to the reference example 4, the Sp adjustment circuit 6, the Sp sample and hold circuit 7, and the Pp sample timing circuit 15 are not required as compared with the apparatus of FIG.
[0113]
Next, Embodiment 1 of the present invention will be described. The first embodiment corresponds to the first aspect of the present invention.
[0114]
In Reference Example 4, the current Ip to be superimposed on the current Ir in order to obtain the amorphization level (Pp) is automatically determined from the ratio of the superimposed current Ie (the ratio between Ie and Ip) set in advance. Since the readout level (Pr) and the crystallization level (Pe) are detected and the drive current Ir and the superimposed current Ie are adjusted to optimal values, respectively, by detecting the readout level (Pr) and the crystallization level (Pe). The case where the amorphization level (Pp) is also set to the optimum value has been described.
[0115]
In the first embodiment, the ratio between the superimposed currents Ip and Ie is set in advance to a predetermined value so as to obtain an optimum value of the driving current Ir, and the crystallization level (Pe) and the amorphization level ( Pp) is detected and adjusted to an optimum value, whereby the optimum drive current Ir is automatically set to an optimum value, and an optimum read level Pr is obtained. I have.
[0116]
FIG. 7 is a functional block diagram showing an example of the first embodiment of the main part configuration of the optical disk drive of the present invention. The reference numerals in the figure are the same as those in FIG. 4, where 31 indicates an amplifier circuit and 32 indicates a fifth adjustment circuit.
[0117]
The device shown in FIG. 7 is different from the device shown in FIG. 1 in that the Sr adjustment circuit 13, the Sr sample hold circuit 14, and the Pr sample timing circuit 16 are omitted, and instead, the amplification circuit 31 and the fifth adjustment circuit 32 are used. Is added.
[0118]
FIG. 8 is a timing chart for explaining a laser driving operation according to the first embodiment in the optical disk drive shown in FIG. The reference numerals given to the respective waveforms in the figure are the same as those in FIG. 2 and correspond to the reference positions in FIG.
[0119]
The Pp sample timing circuit 15 appropriately generates a Pp sample signal Sp, as indicated by Sp in FIG. For example, during the period d of Sp in FIG. 8, the sample signal Sp is generated at “H” level.
[0120]
In Sp of FIG. 8, during the Sp generation period (“H” level period d), the Ip switch control circuit 17 turns on the Ip switch 4 in a non-pulse manner regardless of the level of the recording information Di.
[0121]
Therefore, during this period d, the current Ir + Ip is applied to the laser diode 1, so that the laser power is Pp (amorphization level) and non-pulse as shown by P in FIG.
[0122]
Due to such an operation, the light amount detection voltage Vd becomes a value proportional to the amorphization level (Pp) even during this period d, unlike the period a.
[0123]
Since the Sp sample hold circuit 7 samples the light amount detection voltage Vd during the generation period (period d) of the sample signal Sp indicated by Sp in FIG. 8, the output of the Sp sample hold circuit 7 is always amorphous. A detection voltage proportional to the activation level (Pp) is obtained.
[0124]
The Sp adjusting circuit 6 adjusts the Ip current source 5 based on the detection voltage output from the Sp sample hold circuit 7 so that the laser power becomes an optimal value of the amorphization level (Pp). .
[0125]
As described above, in the first embodiment, the newly added amplifier circuit 31 and the fifth adjustment circuit 32 output the superimposed currents Ip and Ie by the outputs of the Sp adjustment circuit 6 and the Ie adjustment circuit 10. The Ir current source 12 is adjusted so that the ratio becomes a predetermined value.
[0126]
Specifically, assuming that the predetermined ratio is K, the driving current Ir is increased when K × Ie> Ip, and the driving current Ir is decreased when K × Ie <Ip. Adjust the Ir current source 12.
[0127]
This relationship will be described with reference to FIG.
[0128]
FIG. 9 is a characteristic diagram showing a relationship between the current I and the laser power P of the laser diode 1 according to the first embodiment in the optical disk drive shown in FIG. 7, and (1) shows a case where K × Ie <Ip. (2) shows the case where K × Ie = Ip, and (3) shows the case where K × Ie> Ip. The horizontal axis in the figure is the current I of the laser diode 1 and the vertical axis is the laser power P.
[0129]
9 (1) to 9 (3) show the relationship of the laser power P with respect to the current I of the laser diode 1, and read out by the drive current Ir based on the magnitude relationship between the superimposed current Ie and the value of Ip × K. The state where the crystallization level (Pe) and the amorphization level (Pp) change with respect to the level (Pr) is shown.
[0130]
In the timing chart of FIG. 8, when the recording information Di is “0” and the on / off signal De of the Ie switch 8 is at the “H” level as indicated by Di (period a in FIG. 8). Then, the light amount detection voltage Vd is sampled, and the Ie current source 9 is adjusted so that the laser power P becomes the optimum value of the crystallization level (Pe). During the occurrence period (“d” period d of “H” level), the Ip current source 5 is sampled so that the laser power P becomes the optimum value of the amorphization level (Pp). I am adjusting.
[0131]
Since both the superimposed currents Ie and Ip are adjusted to values that provide the optimum crystallization level (Pe) and the amorphization level (Pp), FIGS. Indicates that the superimposed currents Ie and Ip are at the same level.
[0132]
Then, as shown in FIG. 9B, when K × Ie = Ip, the optimum laser power P, that is, Pp (amorphization level), Pe (crystallization level), Pr (read level) Is obtained.
[0133]
On the other hand, as shown in FIG. 9 (3), when K × Ie> Ip, the value of the driving current Ir is insufficient, so that Pr (read level) is smaller than the optimum value.
[0134]
In such a case, the Ir current source 12 is adjusted by the amplifier circuit 31 and the fifth adjustment circuit 32 in FIG. 7 to increase the drive current Ir, so that the current values Ie, Ip, and Ir are optimized. Finally, the optimum laser power P as shown in FIG. 9 (2) is obtained.
[0135]
On the other hand, as shown in FIG. 9A, when K × Ie <Ip, the value of the drive current Ir is excessively large, so that Pr (read level) is larger than the optimum value.
[0136]
In such a case, conversely, the drive current Ir is reduced to make the respective current values Ie, Ip, Ir optimal values, and finally, similarly, as shown in FIG. Optimum laser power P can be obtained.
[0137]
As described above, in the first embodiment, the crystallization level (Pe) and the amorphization level (Pp) are detected and adjusted to optimal values.
[0138]
In this case, the ratio between the superimposed currents Ip and Ie is set in advance to a predetermined value so that the optimum value of the drive current Ir is obtained.
[0139]
Therefore, if the crystallization level (Pe) and the amorphization level (Pp) are respectively adjusted to the optimum values, the driving current Ir is automatically set to the optimum value, and the optimum reading level Pr is obtained. Can be
[0140]
Here, the configuration is shown as follows according to the correspondence with FIG.
[0141]
A light source such as a semiconductor laser (laser diode 1 in FIG. 7), a driving circuit of the light source (Ip switch 4, Ip current source 5), and an emission light amount detecting means (photodetector 2, amplifier 3) for detecting an emission light amount of the light source. In an optical disc drive device for recording, erasing, and initializing information by irradiating the light quantity emitted from the light source on the optical disc as a pulse train having a frequency higher than the recording frequency,
As a laser power control device,
Current applying means (Ir current source 12) for applying a first level current (Ir) to the light source;
First current superimposing means (Ie current source 9) for superimposing the second level current (Ie) on the first level current (Ir);
Second current superimposing means (Ip current source 5) for superimposing the third level current (Ip) on the first level current (Ir);
First switch means (Ie switch 8) for controlling on / off of the second level current (Ie) according to the recording information (Di);
Second switch means (Ip switch 4) for controlling on / off of the third level current (Ip) in a pulse form according to the recording information (Di);
First timing control means (Pp sample timing circuit 15) for generating a first control signal (Sp) for turning on the third level current (Ip) in a non-pulse manner;
First sample and hold means (Ie sample and hold circuit 11) for holding the output (Vd) of the output light quantity detection means (photodetector 2, amplifier 3) during the ON period of the first switch means (Ie switch 8);
Second sample-and-hold means (Sp sample-and-hold circuit 7) for holding the output (Vd) of the output light quantity detection means (photodetector 2, amplifier 3) during the generation period of the first control signal (Sp);
First adjusting means (Ie adjusting circuit 10) for adjusting the second level current (Ie) according to the output of the first sample and holding means (Ie sample and hold circuit 11);
A second adjusting means (Sp adjusting circuit 6) for adjusting the third level current (Ip) according to an output of the second sample holding means (Sp sample holding circuit 7);
Fifth adjustment means (fifth adjustment) for adjusting the first level current (Ir) according to the adjusted second level current (Ie) and the adjusted third level current (Ip). Circuit 32).
[0142]
Embodiment 2 of the present invention will be described. The second embodiment corresponds to the second aspect of the invention, but also relates to the first aspect of the invention.
[0143]
In the first embodiment, the case where the optimum read level Pr is automatically set by detecting the crystallization level (Pe) and the amorphization level (Pp) and adjusting the detected values to the optimum values. Was explained.
[0144]
However, in the optical disk drive shown in FIG. 7, as indicated by Sp in the timing chart of FIG. 8, the amorphous state is appropriately adjusted regardless of the state (level) of the recording information Di indicated by (b). A sample signal Sp for sampling a pulse signal at the quality level (Pp) is generated.
[0145]
Therefore, during the Sp occurrence period (“H” level period d) in FIG. 8, information corresponding to the recording information Di cannot be recorded (information shown in (b) of Di), and is recorded on the optical disc. The possible information capacity is reduced.
[0146]
In the second embodiment, the generation period of the second control signal (Sp) is matched with the period in which an amorphous mark is to be formed in accordance with the state of the recording information Di, so that the second control signal (Sp) is changed. It is characterized in that it occurs during recording of information.
[0147]
The hardware configuration is the same as in FIG.
[0148]
FIG. 10 is a timing chart for explaining the laser driving operation according to the second embodiment for the optical disk drive shown in FIG. The reference numerals given to the respective waveforms in the figure are the same as those in FIG. 2 and correspond to the reference positions in FIG.
[0149]
In the second embodiment, the Pp sample timing circuit 15 appropriately outputs the pulse signal at the amorphization level (Pp) only during the period of the “1” level of the recording information Di (period d in FIG. 10). A sample signal Sp to be sampled is generated.
[0150]
In this case, in the period d of Sp in FIG. 10, the laser power is generated in a non-pulse shape, but since the laser power is at the amorphization level Pp, an amorphous mark is formed on the disk corresponding to the recording information Di. Formed.
[0151]
Therefore, in the case of FIG. 10, information can be recorded in any period.
[0152]
That is, in the first embodiment (in the case of FIG. 8), the information corresponding to the record information Di could not be recorded in the period d, but according to the second embodiment (in the case of FIG. 10). In any case, information can be recorded.
[0153]
As a result, even when adjusting the laser power, there is no inconvenience that the information capacity recordable on the optical disk is reduced.
[0154]
【The invention's effect】
In the optical disk drive according to the first aspect, the ratio of the superimposed currents Ip and Ie is set in advance to a predetermined value so as to obtain an optimum value of the drive current Ir, and the crystallization level (Pe) and the amorphization By detecting the level (Pp) and adjusting the level to the optimal value, the optimal drive current Ir is automatically set to the optimal value, and the optimal read level Pr can be obtained. In addition, an inexpensive device can be obtained.
[0155]
According to a second aspect of the present invention, in the optical disk drive of the first aspect, the generation period of the second control signal (Sp) is set to a period during which an amorphous mark is to be formed according to the state of the recording information (Di). Therefore, the generation of the second control signal (Sp) is during the recording of information. Therefore, a device with high information reliability can be obtained with an inexpensive configuration without a decrease in the information capacity recordable on the disk.
[Brief description of the drawings]
FIG. 1 is a functional block diagram showing Reference Examples 1 and 2 of a main part configuration of a laser power control device for explaining an embodiment of an optical disk drive device of the present invention.
FIG. 2 is a timing chart for explaining the operation of the optical disk drive shown in FIG.
FIG. 3 is a timing chart illustrating a laser driving operation according to a reference example 3 with respect to the optical disk driving device illustrated in FIG. 1;
FIG. 4 is a functional block diagram illustrating an example of a reference example 4;
5 is a timing chart for explaining a laser driving operation according to a reference example 4 in the optical disk drive shown in FIG. 4;
FIG. 6 is a characteristic diagram showing a relationship between a current I and a laser power P of a laser diode 1 according to a reference example 4 in the optical disk drive shown in FIG.
FIG. 7 is a functional block diagram illustrating a configuration of a main part of the optical disc driving device according to the first embodiment of the present invention.
8 is a timing chart for explaining a laser driving operation according to the first embodiment in the optical disk driving device shown in FIG. 7;
FIG. 9 is a characteristic diagram showing a relationship between a current I and a laser power P of the laser diode 1 according to the first embodiment in the optical disk drive shown in FIG.
FIG. 10 is a timing chart illustrating a laser driving operation according to a second embodiment of the present invention with respect to the optical disk driving device shown in FIG. 7;
FIG. 11 is a diagram illustrating the principle of a recording method in a phase change optical disk.
[Explanation of symbols]
1 Laser diode
2 Photo detector
3 Amplifier
4 Ip switch
5 Ip current source
6 Sp adjustment circuit
7 Sp sample hold circuit
8 Ie switch
9 Ie current source
10 Ie adjustment circuit
11 Ie sample and hold circuit
12 Ir current source
13 Sr adjustment circuit
14 Sr sample and hold circuit
15 Pp sample timing circuit
16 Pr sample timing circuit
17 Ip switch control circuit
18 Ie switch control circuit

Claims (2)

A light source such as a semiconductor laser, a driving circuit for the light source, and an emission light amount detecting unit for detecting an emission light amount of the light source, and irradiating the light amount emitted from the light source onto the optical disc as a pulse train having a frequency higher than a recording frequency. In an optical disc drive device that performs information recording, erasing, and initialization,
As a laser power control device,
Current applying means for applying a first level current to the light source;
First current superimposing means for superimposing a second level current on the first level current;
Second current superimposing means for superimposing a third level current on the first level current;
First switch means for controlling on / off of the second level current according to recording information;
Second switch means for controlling on / off of the current of the third level in a pulse form according to recording information;
First timing control means for generating a first control signal for turning on the third level current in a non-pulse manner;
First sample and hold means for holding the output of the emitted light quantity detection means during the ON period of the first switch means;
Second sample and hold means for holding the output of the emitted light quantity detection means during the generation period of the first control signal;
First adjusting means for adjusting the current of the second level according to the output of the first sample and hold means;
Second adjusting means for adjusting the current of the third level according to the output of the second sample and hold means;
A subtracter for adjusting the first level current according to the adjusted values of the second level current and the adjusted third level current;
An optical disk drive device comprising: The optical disk drive according to claim 1,
An optical disk drive , wherein the generation period of the first control signal is within a period according to the state of the recorded information .

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