KR20080041840A - Detecting method of writing power in optical disc driver - Google Patents

Abstract

A method for optimum power calibration of an optical disk device is provided to reduce difference in optimum recording power from different manufacturers by controlling an RF signal such that a gain adjustment value of detected RF signal can be adjusted within a measurable range of the detection signal. A method for optimum power calibration of an optical disk device comprises the steps of: reading test data for measuring a reproduction RF signal level, which is a signal calibrated by a reference gain value, while optimal recording power is detected(S21); discriminating whether the measured reproduction RF signal is within a range of reference level(S22,S23); and determining gain calibration value of the reproduction RF signal such that the measured reproduction RF signal can be included within the range of reference level(S25,S26).

Description

Detecting method of writing power in optical disc driver

1 is a control block diagram for adjusting recording power in a general optical disk device.

2 shows a control configuration diagram for detecting optimal recording power of an optical disk apparatus according to the present invention;

3 is a flowchart illustrating an operation for detecting optimal recording power of an optical disk apparatus according to the present invention;

4 is a flowchart illustrating an operation for adjusting the gain of the RF signal when the optimum recording power is detected in the optical disk apparatus according to the present invention.

Explanation of symbols on the main parts of the drawings

110: optical disk 111: spindle motor

120: optical pickup 140: channel bit encoder

141: optical drive 150: R / F section

160 drive unit 161 servo unit

170: microcomputer 171: EEPROM

130a: digital recording signal processor 130b: digital reproduction signal processor

180: level detector 185: AGC

The present invention relates to a method for detecting an optimal recording power of an optical disk device, and more particularly, to an optimum recording power of an optical disk device capable of detecting an optimum recording power by correcting a deviation of an RF signal measured at the time of detecting an optimal recording power. It relates to a detection method.

In general, the recording optical power in the optical disc apparatus varies depending on the state of the recording medium or the state of the recording medium (laser quality, recording method, laser type and temperature characteristics, etc.), recording speed, and the like. Therefore, in each recording apparatus, the optimum recording optical power value is obtained by using the target recording optical power value recorded on the disc, and then the recording operation is performed using the recording optical power value. The optimal recording power detection process (OPC: Optimum Power Control) is briefly described as follows.

Fig. 1 shows the structure of a general optical disk device, and includes a digital recording signal processing unit 30a for adding an error correction code (ECC) to input digital data and converting it into a recording format, and converting the data converted into the recording format into bits. A channel bit encoder 40 which is reconverted to a scrim, an optical driver 41 which outputs a light quantity driving signal according to the input signal, and writes a signal to the optical disc 10 according to the light quantity driving signal and writes a recording signal from the recording surface. Rotating the optical pickup 20 for detection, the R / F unit 50 for filtering the signal detected by the optical pickup 20 and outputting it as a binary signal, the optical pickup 20 and the optical disc 10 The drive unit 70 driving the spindle motor 11 to drive the drive unit 70, the tracking error TE and the focus error FE signal of the optical pickup 20, and the rotational speed of the optical disc 10. Control the driving of Is a servo unit 60, a digital reproduction signal processing unit 30b for restoring the binary signal to original data with its own clock phase-locked to the binary signal, and OPC for the optical disc 10 and data recording / reproducing. It is configured to include a microcomputer 80 to control the process.

When there is a recording request for data input from the outside through the microcomputer 80 in the optical disk device configured as described above, an optimal recording optical power detection process (OPC) is performed.

First, the microcomputer 80 sets a recording speed to a driver and drives the spindle motor 11 through the servo unit 70 and the drive unit 70 to drive the optical disc 10 in rotation. . Subsequently, the microcomputer 80 reads and confirms the target recording optical power value recorded as data on the optical disc 10 before recording the inputted data, and reads the read and confirmed target recording optical power (for example, 8 mW) value. As a reference, an adjustment signal for varying the magnitude of the optical power by the designated step size ΔP is variably applied to the optical driver 41. The ΔP value is determined in consideration of the power range (for example, 5 mW to 10 mW) that should be changed in size based on the identified target recording optical power value, and the number of test data recording times (15 times).

The optical driver 41 outputs a recording signal for test data at an optical driving power corresponding to the applied control signal, so that the test data is recorded in the test area PCA by the optical pickup 20. .

As described above, in the state in which test data is recorded in the test area PCA of the optical disc 10 by the optical driving power varying in a predetermined size and by a fixed recording pulse, the microcomputer 80 performs the optical pickup 20. Control to read out the test data recorded in the test area (PCA) sequentially. In addition, the microcomputer 80 calculates an asymmetry value β of a reproduction signal with respect to test data read out sequentially and normalized by the R / F unit 50, and calculates the β value thus calculated. To determine the optimal recording optical power value.

As such, when the optimal recording optical power value is determined, the microcomputer 80 outputs a recording signal for the input data by an optical driving current corresponding to the determined optimal recording optical power value for recording the input data. The optical driver 41 is controlled, and the optical driver 41 applies a signal according to the optical driving power to the optical pickup 20 so that the pulse width modulated signal is transmitted to the program area of the optical disc 10. By recording, the recording operation is performed.

And while adjusting the recording power appropriately so that the reflection level β by the optimum recording power detected by the OPC operation and the reflection level (the level of the signal reflected by the recording light) continuously detected during the recording operation are equal to each other. The recording operation is performed.

On the other hand, in the conventional optical disk device operating as described above, the optimum recording power detection detects a specific reproduction pulse section (for example, 3T, 11T) from the recorded test data, and operates the OPC using the RF level of the detected signal. We are looking for the beta (β) needed.

However, in the conventional optical disk device, the variation of the magnitude of the detected RF signal is very large, which makes it difficult to find the optimal recording power from the RF signal in the OPC operation. In other words, due to the deviation of the optical pickup, digital element, disk medium, etc., a deviation occurs in the detected RF signal, and it is difficult to find the optimal recording power due to the deviation of the RF signal generated. In particular, in the case where the detected RF levels of the specific regeneration pulse sections 3T and 11T exceed the measurement range, the RF level itself may not be measured.

Accordingly, the present invention has been made to solve the above problems, and the optimal recording power detection method of the optical disc apparatus which reduces the deviation of the RF signal measured at the detection of the optimum recording power, so that the optimum recording power can be detected more effectively. The purpose is to provide.

According to an aspect of the present invention, there is provided a method of detecting an optimum recording power of an optical disk apparatus, comprising: a first step of reading test data and measuring a magnitude of a reproduced RF signal during an optimal recording power detection; A second step of determining whether the measured reproduction RF signal is included in a range set as a reference value; And a third step of determining a gain compensation value of the reproduced RF signal so that the measured reproduced RF signal can be included in the range of the reference value.

The reproduction RF signal detected in the first step of the present invention is a signal compensated by a reference gain value.

In addition, the present invention, the fourth step of measuring the beta value from the reproduction RF signal compensated by the determined gain compensation value; And a fifth step of setting an optimum recording power so that the measured beta value approaches a target beta value.

The reference value of the second step of the present invention is characterized by setting the measurement range of the reproduced RF signal.

Hereinafter, a preferred embodiment of a method for detecting an optimal recording power of an optical disk apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

2 shows an overall configuration diagram of an optical disk apparatus according to the present invention.

As shown in the drawing, the optical disk apparatus of the present invention includes a digital recording signal processing unit 130a for adding an error correction code (ECC) or the like to input digital data to convert it into a recording format, and converting the data converted into the recording format. And a channel bit encoder 140 for reconverting to a bit stream, and an optical driver 141 for outputting a light amount driving signal according to the input signal.

In addition, the optical disk apparatus of the present invention includes an optical pickup 120 for recording a signal on the optical disk 110 in accordance with the light amount driving signal, and for detecting a recording signal from the recording surface, and a signal detected by the optical pickup 120. R / F unit 150 for outputting a binary signal by shaping the filter, a drive unit 160 for driving the optical pickup 150 and the spindle motor 111, and a tracking error signal of the optical pickup 120. (TE) and a focusing error signal (FE) and the servo unit 161 for controlling the drive of the drive unit 160 from the rotational speed of the optical disc 110.

The optical disk apparatus of the present invention includes a digital reproduction signal processor (130b) for restoring the binary signal to original data with its own clock synchronized with the binary signal, and for each recording speed for each disk code (disc manufacturer). The reference recording power is controlled to perform the optimal recording power detection method through the OCP at the time of recording the data of the memory 171 and the optical disk 110, which are pre-stored in the form of firmware, and recording is performed using the detected optimal recording power. It comprises a microcomputer 170 to control to be made.

In addition, when the optimum recording power detection is performed through the OPC, the microcomputer 170 performs control to adjust a gain setting amount of the reproduction RF signal based on the magnitude of the detected RF signal.

In addition, the present invention provides a configuration for compensating the recording power to reach the optimum recording power by using the beta value detected from the reproduction RF signal when the signal recording is made using the detected optimal recording power for adjusting the optimal recording power Include.

Therefore, the microcomputer 170 of the present invention includes a level detector 180 that detects an RF level from the detected reproduction signal of the RF unit 150, and a level detected by the level detector 180 at the optimal recording power. And compensating recording power to reach the reference value in comparison with. The reference value is a reference value of the detected RF signal when the optimum recording power is set.

In addition, the present invention includes a configuration of the AGC 185 for adjusting the gain of the detection signal of the RF unit 150 so that the detection signal of the RF unit 150 can be included in a predetermined range. Therefore, the microcomputer 170 should store a signal measurable range value according to the reference level in the memory 171 to compare the detected RF level with the reference level for gain adjustment of the AGC 185. .

In the optimal recording power detection method of the optical disk device of the present invention having the above-described configuration, when the data recording request is input, the RF detection signal may be in a measurable range during the optimal recording power detection operation according to the OPC operation. The gain of the signal is adjusted. The operation is performed as follows.

When an optional optical disc 110 is mounted, in order to record a signal on the mounted optical disc, an optimum recording power suitable for the mounted optical disc should be detected. Since different variations occur depending on the material of the disk, the characteristics of the disk, the characteristics of the optical pickup, the characteristics of the set, etc., it is possible to detect the optimal recording power suitable for the mounted optical disk and to follow the detected optimal recording power. By adjusting the power, data is written to the optical disc.

First, the present invention performs an OPC operation for setting the optimum recording power according to the code of the optical disc.

3 is an operation flowchart of an OPC operation for setting an optimum recording power in the optical disk apparatus according to the present invention.

When the optical disc 110 is inserted and mounted, the microcomputer 170 moves the optical pickup 120 to the PCA set on the inner circumferential side of the optical disc 110 and then performs an OPC operation at a reference recording speed in the moved area. do.

The microcomputer 170 detects reference recording power (a general value set according to the code of the disc) stored in association with the reference recording double speed from the memory 171, and records recording power based on the detected recording power. An adjustment signal for changing by a predetermined predetermined size is applied to the optical driver 141.

Accordingly, the optical driver 141 outputs a recording signal for test data at an optical driving power corresponding to the applied control signal, and the optical pickup 120 records the output recording signal. During the conference OPC operation, 15 frames are recorded with 15 recording powers (S10).

When recording of the test data is completed, the microcomputer 170 controls the optical pickup 120 to sequentially read the recorded test data. The readout signal thus read is converted into a binary signal through the R / F unit 150, and then gain control is performed by the gain value set by the AGC 185 and output. At this time, the gain value of the AGC 185 is set as a reference value. As described above, the level detection unit 180 performs level detection on the reproduction signal passing through the AGC 185. The level of the RF signal thus detected is provided to the microcomputer 170.

The microcomputer 170 determines which range the level of the detected RF signal belongs to, and adjusts a gain value of the detected RF signal, that is, a gain value of the AGC 185 (S11). Detailed description of this part will be described with reference to FIG. 4.

By measuring the beta value of the recorded RF signal from the gain adjustment value of the read value of the data recorded in the test area in the above process, the optimum recording power of the beta value of the measured RF signal is close to the target beta value Adjustment is made continuously (S12, S13). Therefore, when the beta value of the gain-adjusted RF signal approaches the target beta value, the recording power value at this time is set to the optimum recording power. The target beta value is a predetermined reference value.

Next, FIG. 4 is an operation flowchart for adjusting the gain of the RF signal at the time of adjusting the optimum recording power according to the present invention.

If a recording operation is requested, the microcomputer 170 performs optimal recording power detection by the OPC operation before performing the requested recording operation. And controlling the gain of the RF signal detected in the optimal recording power detection process.

First, the optical pickup 120 is moved to the start point of the OPC of the test area. The test data is recorded in the test area PCA based on the reference recording power. When the recording of the test data is completed, the optical pickup 1200 is moved to the recording start position of the test data, and the recorded test data is read (S20).

The test data read in step S20 is converted into an RF signal through the R / F unit 150, and the detection signal of the R / F unit 150 is a reference value through the AGC 185 whose gain is adjusted to a default value. As many gain adjustments are made. The RF signal whose gain is adjusted by the reference value is detected by the level detector 180, and then the level of the detected RF signal is provided to the microcomputer 170 (S21).

At this time, the detected RF signal uses a detection value of a clock cycle of 3T to 11T. DVDs generally have a length of 3T to 14T (where 'T' represents one cycle of the data clock). Therefore, the signals of 3T to 11T are detected and the detected levels of 3T to 11T are used as detection values.

The microcomputer 170 compares the level of the RF signal detected in step S21 with a reference level, and determines which range it is included in. The reference level is a value that sets the measurable range of the RF signal in the optical disk device. That is, since the RF signal outside the reference level is a signal exceeding the measurable range, the measurement cannot be performed even if it is to be measured. Therefore, the microcomputer 170 determines whether the level of the RF signal detected in the step S21 is greater than the upper limit of the reference level (S22).

If the level of the RF signal detected in step S22 is greater than the upper limit of the reference level, the gain value of the AGC 185 is adjusted to be lower than the reference value (S25).

If the level of the RF signal detected in the step S21 is less than the lower limit of the reference level (S23), the gain value of the AGC 185 is adjusted to be higher than the reference value (S26).

After adjusting the steps S25 and S26, if the level of the RF signal detected again is included in the range of the reference level (S24), the gain value of the AGC 185 is set to the current gain value.

Subsequently, when the gain of the AGC 185 adjusted in the above-described process is determined, the RF signal to be reproduced in the process of detecting the optimal recording power in the process of detecting the optimal recording power or in the process of signal recording is then performed. After the gain adjustment is performed in the AGC 185 by the gain value adjusted in, it is used for the optimal recording power detection or the optimal recording power compensation process.

As described above, the method of detecting the optimal recording power of the optical disk apparatus according to the present invention is characterized in that, during the process of detecting the optimum recording power, the gain adjustment value of the detected RF signal can be controlled to be adjusted within the measurable range of the detection signal. do. To this end, when the write request signal is input, the present invention performs an OPC operation for optimal recording power detection, detects an RF signal reproduced during the OPC operation, and allows the detected RF signal to exist within a measurable range. Adjust the gain of the signal. With this control, the present invention makes it possible to reduce the deviation of detection of the optimum recording power due to the deviation of each product.

The above-described preferred embodiment of the present invention has been disclosed for the purpose of illustration, and can be applied when adjusting the gain value of the detection RF signal in the process of detecting the optimum recording power. Therefore, those skilled in the art will be able to improve, change, substitute or add other embodiments within the technical spirit and scope of the present invention disclosed in the appended claims.

The method of detecting the optimum recording power of the optical disk apparatus according to the present invention described above is characterized in that, during the process of detecting the optimum recording power, the gain adjustment value of the detected RF signal can be controlled to be adjusted within the measurable range of the detection signal. do. To this end, when the write request signal is input, the present invention performs an OPC operation for optimal recording power detection, detects an RF signal reproduced during the OPC operation, and allows the detected RF signal to exist within a measurable range. Adjust the gain of the signal. With this control, the present invention has the effect that it is possible to reduce the detection deviation of the optimum recording power due to the deviation of each product.

Claims (4)

A first step of reading test data and measuring a magnitude of a reproduced RF signal while optimum recording power detection is being performed; A second step of determining whether the measured reproduction RF signal is included in a range set as a reference value; And a third step of determining a gain compensation value of the reproduced RF signal so that the measured reproduced RF signal can be included in the range of the reference value. The method of claim 1, The reproduction RF signal detected in the first step is a signal compensated by a reference gain value. The method of claim 1, A fourth step of measuring a beta value from the reproduced RF signal compensated by the determined gain compensation value; And a fifth step of setting an optimum recording power so that the measured beta value approaches a target beta value. The method of claim 1, The reference value of the second step is to set the measurement range of the reproduction RF signal, the optimal recording power detection method of the optical disk device.

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