KR100329235B1 - Recording Control Method of Optical Disc - Google Patents

Abstract

The present invention relates to a recording control method for an optical disc, which enables the disc state to be determined by determining the state of the optical disc before recording.

An optical disc recording control method according to the present invention comprises the steps of detecting a tracking error signal that has been test-recorded and reproduced on a recordable disc, and an abnormality section identification signal indicating a case where the magnitude of the tracking error signal is greater than an arbitrary reference value from the tracking error signal. Storing the maximum detection time of the abnormal section identification signal and updating the detection frequency of the abnormal section identification signal, and comparing the identification signal detection time and the detection number of the abnormal section with the determined value to determine whether the defective disk is a defective disk. Characterized in that it comprises a step.

According to the present invention, it is possible to prevent a recording failure due to a bad disc in advance by determining the state of the disc by using the tracking error signal before recording and to determine a bad disc, so that the user can know that the disc is bad.

Description

Recording Control Method of Optical Disc

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a recording control method for an optical disc, and more particularly, to a recording control method for an optical disc to determine whether recording is possible by determining the state of the optical disc before recording.

In general, an optical recording / reproducing apparatus uses a light beam of a small energy that irradiates a relatively large energy light beam that can change the physical properties of the information recording layer to record information on the optical disc and does not change the physical properties of the information recording layer. Information from the optical disc. To this end, an optical recording / reproducing apparatus typically drives a laser diode at a relatively high recording power when recording using a laser diode to perform optical recording, and performs a reproducing operation by driving a relatively low playback power at the time of reproduction.

Recently, as described above, various optical recording / reproducing apparatuses which record information on an optical disc using optical signals and reproduce the recorded information have been released. For example, optical recording for recording / reproducing signals on optical discs such as CD-R (Compact Disc-Recordable), CD-RW (CD-Rewritable), DVD-RAM (DigitalVersatile Disc-Random Access Memory), DVD-RW, etc. / Playback devices are exploding. In response, there are quite a few disk manufacturers, especially for dozens of CD-Rs. As a result, bad discs are generated in the disc manufacturing process in some companies, and the possibility of recording failure increases when information is recorded on such discs. Accordingly, there is a demand for a method of determining whether or not a defective disc is recorded before recording information on the optical disc. However, conventionally, there was no method of determining a defective disk before recording information.

Accordingly, it is an object of the present invention to provide an optical disc recording control method for judging whether a disc is recorded by judging the state of the disc before recording.

1 is a block diagram showing a configuration of an optical recording / reproducing apparatus to which an optical disc recording control method according to an embodiment of the present invention is applied.

FIG. 2 is a signal waveform diagram illustrating an abnormal section identification signal (TERR) for identifying a case where a tracking error signal detected in an optical disc test step and a magnitude of the tracking error signal are out of a reference range.

3 is a block diagram illustrating a configuration of a detection circuit for an abnormal section identification signal of FIG. 2;

4 is a flowchart for explaining an optical disc recording control method according to an embodiment of the present invention in stages;

<Brief description of symbols for the main parts of the drawings>

2: optical disc 4: spindle motor

6: optical pickup 8: laser diode driving unit

10 current-voltage converter 12 lead channel IC

14: DSP Servo 16: Focus / Tracking / Sled Driver

18: spindle motor driver 20: microcomputer

22: Encoding / Decoding / Interface IC 24: Host

26: low pass filter 28: three-phase buffer

30, 32: comparator 36: OR gate

34: Retriggerable Mono Multivibrator

In order to achieve the above objects, the optical disc recording control method according to the present invention comprises the steps of: detecting a tracking error signal reproduced by test recording on a recordable disc; and wherein the size of the tracking error signal is greater than an arbitrary reference value from the tracking error signal. Detecting an abnormal section identification signal indicating a case, storing the maximum detection time of the abnormal section identification signal and updating the detection frequency of the abnormal section identification signal, and comparing the identification signal detection time and the detection number of the abnormal section with the determined value, respectively; Characterized in that it comprises the step of determining whether the bad disk.

Other objects and advantages of the present invention in addition to the above object will be apparent from the description of the preferred embodiment of the present invention with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 1 to 4.

1 is a block diagram of an optical disk recording / reproducing apparatus to which an optical disk recording control method according to the present invention is applied, in which the optical disk recording / reproducing apparatus shown in FIG. 1 accesses an optical disk 2 that is rotated by a spindle motor 4. An optical pickup 6, a current-voltage converter 10 and a laser diode (LD) driver 8 connected to the optical pickup 6, a current-voltage converter 10 and a laser diode driver ( 8) a lead channel integrated circuit (hereinafter referred to as an IC) 12 connected to a digital signal process (hereinafter referred to as a DSP) servo connected to an output terminal of the lead channel IC 12; 14) and a focusing / tracking / sled driver 16 and spindle motor driver 18 connected between the DSP servo 14 and the optical pickup, and connected between the lead channel IC 12 and the host 24. The encoder / decode / interface IC 22 and the DSP servo 14 and the encoder / decode / interface IC 22 connected to the ECOM 20 is provided.

When the information recorded on the optical disc 2 is reproduced in the optical recording / reproducing apparatus of FIG. 1, the laser diode mounted on the optical pickup 6 generates light in accordance with the reproduction power supplied from the laser diode driver 8 to generate the optical disc. The light reflected by (2) and reflected by the optical disc 2 is detected by the photodiode and converted into an electrical signal. The current-voltage converter 10 converts an electrical signal input from the photodiode of the optical pickup 6 into a current-voltage converter and supplies it to the lead channel IC 12. The lead channel IC 12 detects a focus error signal for tracking disk, a tracking error signal, a wobble signal, a high frequency signal, and the like from the output signal of the current-voltage converter 10 and supplies it to the DSP servo 14. The DSP servo 14 supplies control signals to the focus / tracking / sled driver 16 and the spindle motor driver 18 based on the focus / tracking error signal and the wobble signal input from the read channel IC 12. . The focus / tracking / sled driver 16 drives the focus actuator, tracking actuator, and sled motor built in the optical pickup 6 according to the control signal input from the DSP servo 14, and the spindle motor driver 18 In addition, the spindle motor 4 is driven in accordance with a control signal input from the DSP servo 14. Here, the focus control refers to controlling the objective lens, which is embedded in the optical pickup 6 and focuses the optical disk 2 on the optical disk 2, to control the objective lens in the vertical direction so that the focus is on the optical disk 2 surface. Refers to controlling the objective lens to the left and right directions so that light follows the center of the track. Then, the sled control extracts the DC component of the tracking error to transfer the optical pickup 6 so that the objective lens is at the center of the track and controls to transfer the optical pickup 6 when finding a distant track. Say that. Spindle control refers to controlling the spindle motor 18 to rotate at a constant speed. The high frequency signal detected by the lead channel IC 12 is equalized and then supplied to the encoding / decoding / interface IC 22. The decoding unit of the encoding / decoding / interface IC 22 decodes the high frequency signal input from the lead channel IC 12 to supply the reproduction signal to the host 24 through the interface unit.

On the other hand, in the case where information is recorded on the optical disc 2 in the optical recording / reproducing apparatus of FIG. 1, data to be recorded in the host 24 is supplied to the encoding unit through the interface unit of the encoding / decoding / interface IC 22. The encoder encodes a signal to be recorded and supplies a recording pulse to the laser diode driver 8. The laser diode driver 8 supplies the recording power according to the input recording pulse to the laser diode of the optical pickup 6 so that the information is recorded on the optical disc 2. In this case, the light reflected from the optical disc 2 is detected by the photodiode and supplied to the lead channel IC 12 via the current-voltage converter 10 to detect the wobble signal previously formed on the optical disc 2. By supplying the wobble signal to the DSP servo 14, the spindle motor 4 can be controlled to rotate at a constant speed.

The tracking error signal will be used to determine a bad manufacturing disc before recording information in such an optical recording / reproducing apparatus. This is because an optical disc with a possibility of manufacturing defect may be out of track by looking at the shape of the tracking error.

FIG. 2 is a signal waveform diagram showing an abnormal section identification signal TERR detected when the tracking error signal detected in the optical disc test recording step and the size of the tracking error signal are outside the reference range.

In FIG. 2, it can be seen that the tracking error signal, which is detected by continuously reproducing while recording test information before recording the information on the optical disc 2, has a portion in which the size of the tracking error signal is increased one cycle or randomly. In this case, a portion where the tracking error signal is larger than the reference value is detected as a pulse-shaped abnormal section identification signal TERR and supplied to the microcomputer 20, and the microcomputer 20 determines whether or not the defective disk is using the signal. .

FIG. 3 is a circuit configuration for detecting an abnormal section identification signal TERR from the tracking error signal shown in FIG. 2, and the abnormal section identification signal TERR detection circuit shown in FIG. The low pass filter 26 for pass filtering, the three-phase buffer 28 connected to the output terminal of the low pass filter 26, and the first and second comparators 30 commonly connected to the output terminal of the three-phase buffer 28. , 32, retriggerable mono multivibraters 34 and 35 connected to the first and second comparators 30 and 32, and output terminals of the retriggerable mono multivibrators 34 and 35. An OR gate 36 connected to is provided.

In the abnormal region identification signal (TERR) detection circuit shown in FIG. 3, the low pass filter (LPF) 26 removes the high frequency noise by low pass filtering the tracking error signal input through the input line 25 and then removes the three-phase buffer. Output to (28). The three-phase buffer 28 amplifies the output signal of the low pass filter 26 and outputs it to the first comparator 30, and inverts the amplified output signal of the low pass filter 26 to the second comparator 32. ) The first comparator 30 compares the output signal of the three-phase buffer 28, which is input to its '+' terminal, with the reference voltage, and is a high state signal when the output signal of the three-phase buffer 28 is larger than the reference voltage. If it is small, it outputs a low signal. Similarly, the second comparator 32 compares the phase-inverted signal of the three-phase buffer 28, which is input to its '-' terminal, with the reference voltage, and outputs a low state signal when the phase-inverted signal is larger than the reference voltage. If it is small, the output will be high. The retriggerable mono multivibrators 34 and 35 generate an output signal of a high state when the output signals of the first and second comparators 30 and 32 are high, respectively, and the high state is retriggered for a certain period of time. It maintains for time and outputs to OR gate 36, respectively. The OR gate 36 ORs the two output signals of the retriggerable mono multivibrators 34 and 35 so as to show an abnormal section identification signal that becomes high when the tracking error signal exceeds a specific range as shown in FIG. 2. Will output (TERR). The microcomputer 20 shown in FIG. 1 inputs the abnormal section identification signal TERR and checks the length and frequency of occurrence of the abnormal section identification signal TERR, and determines that the host 24 is a bad disk when it is larger than the reference value. The user is informed via

FIG. 4 is a flowchart for explaining an optical disc recording control method according to an embodiment of the present invention step by step, which is performed by the microcomputer 20 shown in FIG.

Firstly, in step 10, the optical recording / reproducing apparatus starts test recording on the optical disc 2. Here, test recording refers to reproducing the disc from the same recording start position to the end position to be recorded at the same recording speed although it is not recorded on the disc. At this time, the track is followed by using the wobble signal configured in the disc in advance, and the rotation speed of the disc detects the period of the wobble and adjusts the rotation speed to the period. In step 12, the microcomputer 20 detects the detection time determination values e1, e2 and e3 of the abnormal section identification signal TERR and the detection frequency determination value e4 of the abnormal section identification signal TERR according to the section to be tested. e5 and e6) are determined and stored in the internal memory. Here, the judgment value of the detection time of the abnormal section identification signal TERR and the detection frequency of the abnormal section identification signal TERR are determined as e1, e2, e3 and e4, e5, e6 to determine the grade of the bad disk. Set to 3 steps as shown. Next, in steps 14 and 16, the microcomputer 20 records the maximum value of the detection time of the abnormal section identification signal TERR detected from the tracking error signal detected by continuously playing the test recording until the end of the test recording. The number of times of detection of the abnormal section identification signal TERR is continuously updated. In this way, when the test recording is completed in step 16, the process proceeds to step 18 where the detection time of the abnormal section identification signal TERR is compared with the determination value e1, and the detection frequency of the abnormal section identification signal TERR is compared with the determination value e4. In this step 18, if the detection time of the abnormal section identification signal TERR is smaller than the judgment value e1 and the frequency of detection of the abnormal section identification signal TERR is smaller than the judgment value e4, the process proceeds to step 20 to notify the host 24 that the disk is a normal disk. Done. On the other hand, when the detection time of the abnormal section identification signal TERR is greater than the judgment value e1 and the number of detection of the abnormal section identification signal TERR is greater than the judgment value e4 in step 18, the process proceeds to step 22 and the abnormal section identification signal TERR is detected. The detection time is compared with the judgment value e2, and the number of detection of the abnormal section identification signal TERR is compared with the judgment value e5. In this step 22, if the detection time of the abnormal section identification signal TERR is smaller than the judgment value e2 and the frequency of detection of the abnormal section identification signal TERR is smaller than the judgment value e5, the process proceeds to step 24 and judges that it is a bad grade A. The host 24 is notified that the disk is less likely. On the other hand, in step 22, when the detection time of the abnormal section identification signal TERR is greater than the judgment value e2 and the number of detection of the abnormal section identification signal TERR is larger than the judgment value e5, the process proceeds to step 26 to determine the abnormal section identification signal TERR. The detection time is compared with the determination value e3, and the number of detections of the abnormal section identification signal TERR is compared with the determination value e6. In step 26, if the detection time of the abnormal section identification signal TERR is smaller than the judgment value e3 and the frequency of detection of the abnormal section identification signal TERR is smaller than the judgment value e6, the process proceeds to step 28 and is determined as bad grade B. The host 24 is informed that the disk is more or less likely. On the other hand, in step 26, if the detection time of the abnormal section identification signal TERR is greater than the judgment value e3 and the number of detection of the abnormal section identification signal TERR is larger than the judgment value e6, the process proceeds to step 30 and is determined as a bad grade C and recording failure The host 24 will be notified that the most likely disk is. The host 24 receives the above-described information from the interface IC 22 and informs the user so that the user can judge. Since the user can grasp the quality of the disc to be recorded in advance, the user can determine whether to record the data accordingly, and then purchase the more stable quality disc without purchasing the disc.

As described above, according to the optical disc recording control method according to the present invention, it is possible to prevent a recording failure due to a bad disc in advance by determining the state of the disc by using the tracking error signal before recording and discriminating the defective disc. Make sure that is a bad disk.

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 (6)

Detecting tracking error signals reproduced by test recording on a recordable disc; Detecting an abnormal section identification signal representing a case where the magnitude of the tracking error signal is greater than an arbitrary reference value from the tracking error signal, storing the maximum detection time of the abnormal section identification signal, and updating the detection frequency of the abnormal section identification signal. Steps, And comparing the identification signal detection time and the detection frequency of the abnormal section with the determination value to determine whether the defective disk is defective. The method of claim 1, And informing the user of the result of determining the defective disk. The method of claim 1, And setting at least one determination value of the abnormal section identification signal detection time and the determination value of the abnormal section identification signal detection frequency. The method of claim 1, The step of determining whether the bad disk is And classifying the optical disc into grades according to the determination value. The method of claim 1, The step of determining whether the bad disk is Detecting an abnormality section identification signal for inputting the tracking error signal to identify a large case where the voltage level of the tracking error signal is outside a predetermined reference voltage level; And determining whether or not the defective disk is based on the abnormal section identification signal. The method of claim 5, And determining whether or not the defective disk is determined by comparing each of a detection time and a detection frequency of the abnormal section identification signal with at least one or more predetermined determination values.