KR100235331B1 - Optical recording and reproducing device for optimal recording power control - Google Patents

Abstract

The present invention relates to an optical recording and reproducing apparatus for optimum recording power control capable of quickly and optimally recording in response to changes in recording conditions.

An optical recording and reproducing apparatus for optimal recording power control according to the present invention is an optical recording and reproducing apparatus for recording information on an optical disk with an optical beam, the optical recording and detecting light source generating a light beam to be irradiated on the optical disk and a light beam reflected by the optical disk. An optical pickup apparatus having means; Recording pulse generating means for generating recording pulses to be actually recorded on the optical disc by including additional information in recording information; A microcomputer for providing additional information to the recording pulse generating means, setting a coefficient to normalize the recording power level, and adjusting the recording power to keep the normalization coefficient constant; Light control means for controlling the light source in accordance with a recording pulse output from the recording pulse generating means and a recording power applied from a microcomputer; High frequency generating and amplifying means for generating and amplifying a high frequency signal from the electrical signal of the light detecting means; Comparison means for outputting a pulse-shaped signal by comparing the high frequency signal with an arbitrary comparison voltage level to detect average pit formation time information from the high frequency signal of the high frequency generation and detection means; And a low pass filter for converting the period of the pulse output from the comparing means into a DC voltage level and outputting it to the microcomputer.

According to the present invention, by implementing a quick response with a simple configuration such as a comparator, it is possible to always record with the optimum recording power in response to the change of the recording conditions during recording.

Description

Optical record and playback device for optimal recording power control

1 is a block diagram of a conventional optical recording and reproducing apparatus for optimal recording power control, and an output signal waveform diagram for each portion thereof.

2 is a block diagram of an optical recording and reproducing apparatus for optimum recording power control according to a first embodiment of the present invention, and an output signal waveform diagram for each portion thereof.

3 is a block diagram of an optical recording and reproducing apparatus for optimum recording power control according to a second embodiment of the present invention, and an output signal waveform diagram for each portion thereof.

4 is a block diagram of an optical recording and reproducing apparatus for optimum recording power control according to a third embodiment of the present invention, and an output signal waveform diagram for each portion thereof.

5 is a block diagram of an optical recording and reproducing apparatus for optimum recording power control according to a fourth embodiment of the present invention, and an output signal waveform diagram for each portion thereof.

* Explanation of symbols for main parts of the drawings

2: microcomputer 4: recording pulse generator

6 laser diode (LD) driver 8 analog-to-digital converter (ADC)

10: optical pickup LD: laser diode

PD: photodiode 12: optical disc

14: RF generator and amplifier 16: sampler

18: analog-to-digital converter (DAC) 20, 24, 30, 32: comparator

22,34,36: Low Pass Filter (LPF) 26: Timer

28: latch 38: amplifier

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a recording power control technique for optimal recording in an optical recording and reproducing apparatus, and more particularly, to an optical recording and reproducing apparatus for controlling recording power according to recording conditions by following a change in recording conditions while performing recording. will be.

In general, an optical recorder records information by causing a change in a recording medium coupling structure using a high-power laser, and reproduces the information by using a change in optical characteristics.

Then, the optical recorder controls the recording power, that is, the laser power, for optimal recording while recording information, which is a signal sampled at a stable state and a signal level at a constant reproduction power level. This is done by normalizing the level in the microcomputer. The laser power control process for optimal recording in the optical recorder will be described in detail with reference to FIG.

1 shows a block diagram of a CD-R (Compact Disc Recorder) for optimum recording power control and an output signal waveform diagram for each part thereof.

In general, an optical recording / reproducing apparatus includes a recording pulse generator (4) for generating actual recording pulses by including auxiliary information from the microcomputer (2) in the recording information, and recording pulses and microcomputers (the recording pulses from the recording pulse generator (4). An LD driver 6 for driving a laser diode (hereinafter referred to as LD) provided in the optical pickup 10 in accordance with the laser power level from 2) is provided.

The recording pulse generating unit 4 adds auxiliary information provided from the microcomputer 2 to the recording information to generate a recording pulse that is actually applied, and outputs the recording pulse to the LD driver 6. At this time, the recording pulse output from the recording pulse generating unit 4 is the same as the waveform shown in (a) of FIG. The LD driver 6 controls the light beam of the LD 10 in accordance with the recording pulse output from the recording pulse generator 4 and the appropriate laser power level provided from the microcomputer 2. At this time, the laser power level input from the microcomputer 2 to the LD driver 6 is a magnitude set by the optimum power control of the microcomputer 2, and is referred to as a digital-analog converter (DAC). Is converted into analog signal level and input. The LD of the optical pickup 10 records the information on the optical disk 12 by irradiating the optical disk 12 with a light beam of high power under the control of the LD driver 6.

The conventional optical recorder reproduces the signal level from the RF signal reflected from the optical disc 12 and output through the optical pickup 10 and the RF generator / amplifier 14 during recording for optimum power control. And a sampler 16 for providing 2) and an analog-to-digital converter (hereinafter referred to as ADC) 18.

As the recording is performed, the signal reflected from the optical disk 12 is converted into an electrical signal through a photo diode (hereinafter referred to as PD) of the optical pickup 10, and the RF generator / amplifier 14 It is output as an RF signal of the form as shown in (b) of FIG. At this time, the shape of the RF signal changes depending on the state in which the pits are formed in the recording layer of the optical disc 12. In other words, when the pit is formed by changing the characteristics of the recording layer of the optical disc 12, since the pit was not formed during the pit formation time, ie, the delta T, which is the initial stage of the recording pulse irradiation, the reflection signal is large and the delta T time Thereafter, since the pit is formed, the reflected signal becomes stable. At this time, the recording pits formed on the optical disc 12 are as shown in (c) of FIG. 1, and the delta T in FIG. 1 (c) is the change of the write pulse, the characteristics of the media, and the recording conditions. Will change accordingly.

For details, referring to (d) and (e) of FIG. 1, in FIG. 1, (d) shows the shape of the recording pulse according to the power level of the stages 1 to 6 outputted from the LD driver 6. , (e) shows the output form of the RF signal reflected when recording on the optical disc 12 with the pulse of (d).

First, in (d), when recording is performed with recording pulses having power levels of ①, ②, and ③, the reflected signal does not change as in ① ', ②', ③ ', which is the recording layer of the optical disc 12. This is because they did not reach enough power to change the characteristics of. The power pulses of ④, ⑤, and ⑥ in the recording pulses of (d) are powers enough to change the characteristics of the recording layer, and thus have reflection signals such as ④ ', ⑤', and ⑥ '. Here, the case of ⑥ 'is the optimum power.

The sampler 16 samples the signal level at the point of time T _b at which the signal is stable with respect to the reflected signal outputted from the RF generator / amplifier 14 such as ⑥ ', and at T _r , which is a point of constant regeneration power level. The signal level is sampled and provided to the microcomputer 2 through the ADC 18. The microcomputer 2 normalizes the signal level input from the sampler 16 through the ADC 18 to perform optimal recording power control for the LD driver 6.

However, in the conventional optical recorder as described above, it is difficult to accept the sampled signal by setting the sample time point for each recording pulse, and as the recording speed increases, the response speed of the ADC 18 and the DAC 8 and Price has become a problem. In other words, in the trend of information recording becoming faster, the conventional optical recorder is time Tb for sampling the RF signal level reflected during the recording pulse and time Tr for sampling the signal level during the reproduction power period between each recording pulse and the pulse. The selection of is extremely difficult and complicated, resulting in high cost burden.

Accordingly, an object of the present invention is to provide an optical recording and reproducing apparatus for optimal recording power control that can cope with changes in recording conditions during recording while simplifying the configuration of the system.

In order to achieve the above object, the optical recording and reproducing apparatus for optimal recording power control according to the present invention is an optical recording and reproducing apparatus for recording information on an optical disk with an optical beam, the optical recording and reproducing apparatus for generating a light beam to be irradiated to the optical disk. An optical pickup apparatus having light detecting means for detecting a light beam reflected by the light beam; Recording pulse generating means for generating recording pulses to be actually recorded on the optical disc by including additional information in recording information; A microcomputer for providing additional information to the recording pulse generating means, setting a coefficient to normalize the recording power level, and adjusting the recording power to keep the normalization coefficient constant; Light control means for controlling the light source in accordance with a recording pulse output from the recording pulse generating means and a recording power applied from a microcomputer; High frequency generating and amplifying means for generating and amplifying a high frequency signal from the electrical signal of the light detecting means; Comparison means for outputting a pulse-shaped signal by comparing the high frequency signal with an arbitrary comparison voltage level to detect average pit formation time information from the high frequency signal of the high frequency generation and detection means; And a low pass filter for converting the period of the pulse output from the comparing means into a DC voltage level and outputting it to the microcomputer.

An optical recording and reproducing apparatus for optimal recording power control according to the present invention is an optical recording and reproducing apparatus for recording information on an optical disk with an optical beam, the optical light detecting the light beam reflected by the optical disk and the light source for generating the optical beam to be irradiated on the optical disk. An optical pickup apparatus having a detection means; Recording pulse generating means for generating recording pulses to be actually recorded on the optical disc by including additional information in recording information; A microcomputer for providing additional information to the recording pulse generating means, setting a coefficient to normalize the recording power level, and adjusting the recording power to keep the normalization coefficient constant; Optical control means for controlling the light source in accordance with a recording pulse output from the recording pulse generating means and a recording power that is converted into an analog signal from the microcomputer and applied; High frequency generating and amplifying means for generating and amplifying a high frequency signal from the electrical signal of the light detecting means; Comparison means for outputting a pulse-shaped signal by comparing the high frequency signal with an arbitrary comparison voltage level to detect average pit formation time information from the high frequency signal of the high frequency generation and detection means; A timer for counting a period of the pulse output from the comparing means; And a latch for temporarily storing a value output from the timer and providing the same to the microcomputer.

An optical recording and reproducing apparatus for optimal recording power control according to the present invention is an optical recording and reproducing apparatus for recording information on an optical disk with an optical beam, the optical light detecting the light beam reflected by the optical disk and the light source for generating the optical beam to be irradiated on the optical disk. An optical pickup apparatus having a detection means; Recording pulse generating means for generating recording pulses to be actually recorded on the optical disc by including additional information in recording information; A microcomputer for providing additional information to the recording pulse generating means, setting a coefficient to normalize the recording power level, and adjusting the recording power to keep the normalization coefficient constant; Optical control means for controlling the light source according to a recording pulse output from the recording pulse generating means and a recording power that is converted into an analog signal from the microcomputer and applied; High frequency generating and amplifying means for generating and amplifying a high frequency signal from the electrical signal of the light detecting means; A plurality of comparison means for outputting a pulse-shaped signal by comparing the high frequency signal with an arbitrary comparison voltage level to detect a pit formation time from the high frequency signal of the high frequency generation and detection means; And a plurality of low pass filters for converting the pit formation time information detected from each of the plurality of comparison means into a DC voltage level and providing the same to the microcomputer.

The above and other objects and advantages of the present invention will become more apparent from the detailed description of the embodiments of the present invention.

Hereinafter, the most preferred embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a block diagram of an optical recording / reproducing apparatus for optimum recording power control according to the first embodiment of the present invention, and a signal characteristic diagram thereof. The optical recording and reproducing apparatus of FIG. 2 includes an LD driver 6 for driving the LD of the optical pickup 10 in accordance with the laser power level from the microcomputer 2 and the recording pulse from the recording pulse generator 4, and an optical disc. 12 is a comparator for inputting the RF signal through the optical pickup 10 and the RF generator / amplifier 14 to reflect the signal reflected during recording, and to provide the microcomputer 2 with information on the pit formation time at a DC voltage level. 20 and LPF 22 are provided.

First, the optical recording and reproducing apparatus of FIG. 2 distinguishes the type of optical disc in the focus search loop.

In detail, the waveform of the RF signal reflected from the optical disk 12 and output through the optical pickup 10 and the RF generator and amplifier 14 during focus search is shown in (d) of FIG. Depends on type A and B Accordingly, the pulse period Tread of the pulses outputted through the comparator 20 having the constant comparison voltage level, that is, Vread, is respectively shown in FIG. Since Ta and Tb are different, the type of disc can be distinguished according to these pulse periods Ta and Tb. At this time, the comparison voltage Vread of the comparator 20 is a voltage level input from the microcomputer 2 via the first node 21.

In addition, the pulse periods Ta and Tb at this time are stored in a separate storage location of the microcomputer 2 for optimal power adjustment during recording.

Next, the optical recording / reproducing apparatus performs a test on the PCA area of the optical disk 12 to obtain an optimum recording power from the reference recording power read from the optical disk 12 when recording starts.

In detail, the microcomputer 2 uses the optical pickup 12, the RF generation unit and the amplification unit 14, and the comparator 20 from the optical disc 12 so that the signal input to the LPF 22 becomes a reference. The input signal is input through the second node 23 to set the reference voltage Vwrite of the comparator 20. Then, the microcomputer 2 calculates and multiplies the reference voltage Vwrite by a value that is proportional to the ratio between the pulse period Tread and the reference voltage Vread at the focus, that is, the reflectance according to the type of the disc, and multiplies the normalization coefficient ( K). This means that the microcomputer 2 sets the criteria for the reproduction characteristics and the recording characteristics of the optical disc for optimum recording power control. In this case, the normalization coefficient K set by the microcomputer 2 is represented by a formula as follows.

Here, K is a value having a recording characteristic of the optical disc 12 currently being recorded, and is a value to be kept constant while recording information on the current optical disc 12.

In the optical recording and reproducing apparatus of FIG. 2, the LD driver 6 converts the recording signal (a) of FIG. 2 generated by the recording pulse generator 4 and the normalization coefficient K from the microcomputer 2. The optimum recording power level set by using this is inputted through the DAC 8, thereby driving the LD of the optical pickup 10 so that desired information is recorded on the optical disc 12.

The signal reflected from the optical disc 12 during recording is output as an RF signal waveform as shown in FIG. 2B through the PD, the RF generator and the amplifier 14 of the optical pickup 10. As shown in FIG. The comparator 22 receives the RF signal Vwrite, which is set from the microcomputer 2, through the first node 21, and generates a pulse as shown in (c) of FIG. Output Here, the comparison voltage level Vwrite of the comparator 22 set by the microcomputer 2 takes into account the pulse period Ta or Tb of the output signal reflected during the focus search, that is, a value reflecting reflectance according to the type of disk. By setting the voltage level, this is to obtain a more accurate output of the comparator 22. The widths T1 and T2 of the pulses output from the comparator 22 shown in FIG. 2C mean the pit formation time (delta T). Subsequently, the LPF 24 having a sufficiently large time constant changes the period of the output pulse from the comparator 22 to the DC voltage level and outputs it to the microcomputer 2. Here, the DC voltage level output from the LPF 24 means a value obtained by normalizing the average pit formation time to the entire time. The microcomputer 2 reads the DC voltage level from the LPF 24 to adjust the laser power output to the LD driver 6. In other words, when the output level from the LPF 24 changes due to the change of the recording variable during recording, the microcomputer 2 adjusts the laser power to keep the normalization coefficient K constant so that the recording is always performed at the optimum power. Be sure to At this time, changes in the recording variable during recording, that is, factors that cause the laser power to fluctuate, include changes in the drive temperature of the LD 10, variations and defects in the optical disc 12, variations in circuit elements, and the like.

3 is a block diagram of an optical recording / reproducing apparatus for optimum recording power control according to a second embodiment of the present invention, and an output signal waveform diagram for each part thereof. In FIG. 3, the LPF 24 of FIG. 2 is replaced with a timer 26 and a latch 28 so that the time information obtained during the focus search in the first embodiment can be used by the microcomputer 2 as it is. do. Therefore, detailed descriptions of the components overlapping with those of the first embodiment will be omitted.

First, the comparison voltage level of the comparator 24 during focus search and writing is fixed to the reference voltage input through the input line 25, that is, Vref. The timer 26 at the time of focus search counts the period of the pulse output from the comparator 24 and inputs this value to the latch 28. The microcomputer 2 can perform more accurate control by normalizing using only the value input to the latch 28, that is, time information. That is, the reference voltage Vref may be fixed at the time of focus search and writing, and the ratio of Tread / Twrite may be reflected as it is.

The RF signal reflected from the optical disk 12 during recording with the recording pulse as shown in FIG. 3A is as shown in FIG. 3B, and the comparator 24 receives the RF signal and compares it with the comparison voltage level Vref. To obtain an output pulse as shown in FIG. 3C. Subsequently, the timer 26 counts the periods of the pulses output from the comparator 24, that is, t1 and t2, and inputs this value to the latch 28. The microcomputer 2 reads the value input to the latch 28 from time to time to maintain the normalized time information, i.e., the optimum recording power control in accordance with the change of the recording situation. At this time, the period t1 of the pulse shown in FIG. 3C is about several hundred ns at 1x speed, and a high speed timer should be used.

4 is a block diagram of an optical recording / reproducing apparatus for optimum recording power control according to a third embodiment of the present invention, and an output waveform diagram for each part thereof. 4 includes two comparators 30 and 32 and two LPFs 34 and 36 instead of the comparator 22 and the LPF 24 of the second configuration according to the first embodiment. Therefore, detailed descriptions of the components overlapping with those of the first embodiment and their operations will be omitted.

In the first and second embodiments, the recording power is controlled to be normalized and maintained by using the voltage and time information obtained during the focus search and the voltage and time information obtained during the initial recording test. The slope of the RF pit formation time is obtained and recording power control is performed to maintain this slope optimally.

In detail, first, a recording test is performed before recording.

At this time, the comparison voltage levels of the two comparators 30 and 32 are fixed to Vref1 and Vref2, respectively, or set from the microcomputer 2. The comparator 1 30 receives the RF signal (FIG. 3 (b)) reflected from the optical disc 12 and output from the RF generator / amplifier 14 through the optical pickup 10. A pulse as shown in FIG. 3C is output to LPF1 34 by Vref1. In addition, comparator 2 (32) also receives the RF signal from the RF generator / amplifier 14 and outputs a pulse as shown in (d) of FIG. 3 to LPF2 36 by the comparison voltage level Vref2. . Then, LPF1 and LPF2 34 and 36 change the respective pulse periods from comparators 1,2 (30 and 32) to the DC voltage level and apply them to the microcomputer 2. The microcomputer 2 calculates the slope K of the RF signal at the time of recording by using the voltage applied from the LPF1, 2 (34, 36). This K can be expressed as an expression:

This is the absolute value of the ratio of the difference ΔVref between the comparison voltage levels and the value of the pulse periods of the comparators 1 and 2 (30, 32) detected as voltages, which is a value to be maintained while recording information on the current optical disc 12. . Therefore, the microcomputer 2 adjusts the recording power such that K is constant during recording according to the change of the recording situation, so that the LD driver 6 always maintains the optimum recording power.

5 is a block diagram of an optical recording / reproducing apparatus for optimum recording power control according to the fourth embodiment of the present invention, and an output waveform diagram for each part thereof.

This further includes a differential amplifier 38 in the configuration of the third embodiment shown in FIG. 4, so that the outputs of LPF1, 2 (30, 32) can be directly driven by using the differential amplifier 38. Is fed back to drive LD. In this case, the microcomputer 2 sets the reference voltage of the optimal recording power in the LD, and sometimes checks whether the K of FIG. 4 is constant at the output of the differential amplifier 38 and feeds it back to the LD driver 6, most of which is directly feedback. By doing so, the burden on the microcomputer 2 can be reduced.

In addition, if the time constants of the LPFs 1 and 2 (34, 36) in Figs. 4 and 5 are constant, a quick response is possible regardless of the condition that the time constant of the LPF 22 of Fig. 2 is sufficiently large. This is advantageous because a quick response is required if part of the optical disc has different conditions than the surroundings.

As described above, according to the optical recording and reproducing apparatus for controlling the optimum recording power according to the present invention, since it is simply configured with a comparator or the like so as to respond to the change of the recording condition at the time of recording, the recording is always performed at the optimum recording power by implementing a quick response. You can do that.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (8)

An optical recording and reproducing apparatus for recording information on an optical disk with an optical beam, the optical recording and reproducing apparatus comprising: an optical pickup apparatus having a light source for generating a light beam to be irradiated on the optical disk and light detecting means for detecting the light beam reflected by the optical disk; Recording pulse generating means for generating recording pulses to be actually recorded on the optical disc by including additional information in recording information; A microcomputer for providing additional information to the recording pulse generating means, setting a coefficient to normalize the recording power level, and adjusting the recording power to keep the normalization coefficient constant; Light control means for controlling the light source in accordance with a recording pulse output from the recording pulse generating means and a recording power applied from a microcomputer; High frequency generating and amplifying means for generating and amplifying a high frequency signal from the electrical signal of the light detecting means; Comparison means for outputting a pulse-shaped signal by comparing the high frequency signal with an arbitrary comparison voltage level to detect average pit formation time information from the high frequency signal of the high frequency generation and detection means; And a low pass filter for converting the period of the pulse output from said comparing means into a DC voltage level and outputting it to said microcomputer. The optical recording and reproducing apparatus for optimum recording power control according to claim 1, wherein the comparison voltage level of the comparing means is set in consideration of the period of the pulse output from the comparing means at the time of focus search in the microcomputer. The optimal recording power control according to claim 1, wherein the normalization coefficient is obtained by multiplying the comparison voltage of the comparison means by the comparison voltage from the comparison means and the pulse period at the time of focus search at the initial writing test in the microcomputer. Optical recording and reproducing apparatus. An optical recording and reproducing apparatus for recording information on an optical disk with an optical beam, the optical recording and reproducing apparatus comprising: an optical pickup apparatus having a light source for generating a light beam to be irradiated on the optical disk and light detecting means for detecting the light beam reflected by the optical disk; Recording pulse generating means for generating recording pulses to be actually recorded on the optical disc by including additional information in recording information; A microcomputer for providing additional information to the recording pulse generating means, and regulating the recording power to normalize the recording power level to maintain the normalized value; Optical control means for controlling the light source in accordance with a recording pulse output from the recording pulse generating means and a recording power that is converted into an analog signal from the microcomputer and applied; High frequency generating and amplifying means for generating and amplifying a high frequency signal from the electrical signal of the light detecting means; Comparison means for outputting a pulse-shaped signal by comparing the high frequency signal with an arbitrary comparison voltage level to detect average pit formation time information from the high frequency signal of the high frequency generation and detection means; A timer for counting a period of the pulse output from the comparing means; And a latch for temporarily storing the value output from the timer and providing the microcomputer to the microcomputer. The optical recording and reproducing apparatus for optimum recording power control according to claim 4, wherein the normalization coefficient is a ratio between time information detected at the time of focus search and time information detected at the initial recording test. An optical recording and reproducing apparatus for recording information on an optical disk with an optical beam, the optical recording and reproducing apparatus comprising: an optical pickup apparatus having a light source for generating a light beam to be irradiated on the optical disk and light detecting means for detecting the light beam reflected by the optical disk; Recording pulse generating means for generating recording pulses to be actually recorded on the optical disc by including additional information in recording information; A microcomputer for providing additional information to the recording pulse generating means, setting a coefficient for normalizing the recording power level, and adjusting the recording power to keep the normalized value constant; Optical control means for controlling the light source in accordance with a recording pulse output from the recording pulse generating means and a recording power that is converted into an analog signal from the microcomputer and applied; High frequency generating and amplifying means for generating and amplifying a high frequency signal from the electrical signal of the light detecting means; A plurality of comparison means for outputting a pulse-shaped signal by comparing the high frequency signal with an arbitrary comparison voltage level to detect a pit formation time from the high frequency signal of the high frequency generation and detection means; And a plurality of low pass filters for converting the pit formation time information detected from each of said plurality of comparison means into a DC voltage level and providing them to said microcomputer. 7. The method according to claim 6, wherein the normalization coefficient is a slope of the pit formation time and is an absolute value of a ratio between the difference between the comparison voltage levels of the plurality of comparison means and the voltages output from the plurality of low pass filters during an initial writing test. An optical recording and reproducing apparatus for controlling optimal recording power. 7. The optical recording and reproducing apparatus according to claim 6, further comprising a differential amplifier for feeding back the outputs from the plurality of low pass filters directly to the optical control means.

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