KR20030029269A - Method for data writing a bad disc - Google Patents

Abstract

PURPOSE: A data writing method according to reject disc determination is provided to precisely determine whether a disc is a reject disc or not and normally carry out the writing operation for the reject disc by controlling the writing speed downward. CONSTITUTION: A data writing method according to reject disc determination includes the steps of determining the reject of a recording medium on the basis of a normality detection of an inserted modulated signal according to a wobble frequency deviation and a level of a servo signal generated in the process of the writing operation along wobble tracks(S40), and controlling the writing operation to reduce the writing speed according to the determination(S50-S51). The servo signal is to be a tracking error signal. The level detection of the servo signal is reset by a preset time. The modulated signal is to be an ATIP synchronization signal.

Description

Method for data writing a bad disc

The present invention relates to a data recording method according to a defective disk determination for accurately determining whether an optical disk is defective or not and adjusting the recording speed.

In the conventional bad disc determination and the data recording method accordingly, the level of the tracking error signal is continuously monitored by continuously monitoring the level of the tracking error signal during data recording on the inserted and rewritable optical disc (CD-RW) at the set recording speed. If there is a difference between the reference level and the predetermined level or more, the optical disk is discriminated as a defective disk due to defects or the like. That is, if the servo signal (tracking error signal) is found to be in an unstable state by monitoring the servo signal during recording, the optical disc is identified as a bad disc. If the optical disc is identified as a bad disc, it is determined that it is difficult to continue recording further. In this case, the recording operation is unconditionally interrupted. In this case, there is a troublesome problem of finding and rewriting the interrupted recording part, or in some cases, rewriting from the beginning of the optical disc.

In addition, in the conventional bad disk discrimination method, the servo signal may be temporarily unstable due to an external shock or a disturbance, not due to the failure of the optical disc, but only by the level of the tracking error signal. Since there is a problem in determining whether or not there was a problem, there was a problem that can occur.

Accordingly, the present invention was created to solve the above problems, and accurately determine whether an optical disc is defective by using a tracking error signal detected according to data recording and a synchronization signal of modulated-inserted ATIP data according to wobble frequency deviation. In the case where it is determined that the defective disk is determined, the recording speed is adjusted downward to perform the recording operation again from the position where the recording is stopped, thereby providing a data recording method according to the determination of the defective disk to allow a normal recording operation even for the defective disk. Its purpose is to.

Fig. 1 shows the configuration of an optical disk driver to which a data recording method according to a bad disk determination according to the present invention is applied.

FIG. 2 shows a detailed configuration of an ATIP encoder of the optical disk drive device of FIG.

3A and 3B show the flow of a preferred embodiment of a data recording method according to the determination of a bad disk according to the present invention;

4 shows the shape of a wobble signal recorded on an optical disc,

5 and 6 show examples of servo signals (tracking error signals) output from the R / F section of FIG.

FIG. 7 shows an operation example of the servo loop of FIG.

※ Explanation of symbols for main parts of drawing

10 optical disc 11: spindle motor

20: optical pickup 30a: digital recording signal processing unit

30b: digital reproduction signal processor 40: channel bit encoder

41: optical drive 50: R / F section

51: A / D converter 60: ATIP decoder

70: servo unit 71: drive unit

72: pulse counter 80: microcomputer

In the data recording method according to the determination of the defective disk according to the present invention for achieving the above object, the normal detection of the modulation-inserted signal according to the level of the servo signal generated during the recording operation along the wobble track and the deviation of the wobble frequency A first step of determining whether or not the recording medium is defective based on whether the recording medium is defective; And a second step of controlling the recording operation according to the determination result.

Best Mode for Carrying Out the Invention A preferred embodiment of the data recording method according to the determination of a defective disk according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an optical disk driver to which a data recording method according to a bad disk determination according to an embodiment of the present invention is applied, and an error correction code (ECC) and the like to digital data input from an external host or the like. A digital recording signal processing unit 30a which adds and converts into a recording format; A channel bit encoder (40) for reconverting the data converted into the recording format into a bitstream; An optical driver 41 for outputting a light quantity driving signal according to the input signal; An optical pickup (20) for recording a signal on the optical disc (10) in accordance with the light quantity driving signal and for detecting a recording signal from the recording surface; From a signal detected by the optical pickup 20, a servo signal (focus error signal FE and tracking error signal TE), a high frequency reproduction signal, and a shape of a recording track on the optical disc 10 are formed. An R / F unit 50 for outputting a wobble signal; An A / D converter (51) which converts and outputs a tracking error signal (T.E) of the servo signals output from the R / F unit (50) into digital data; A digital reproduction signal processor 30b for restoring the output high frequency reproduction signal to original data; Decode the output wobble signal to detect ATIP (Absolute Time In Pre-Groove) data, and generate ATIP_OK (a), ATIP (b), and ATIP_Sync (c) signals based on the detected ATIP data. An ATIP decoder 60 for outputting each; A drive unit 71 for driving the optical pickup 20 and the spindle motor 11; A servo unit 70 controlling the driving of the drive unit 71 from the output servo signal and wobble signal, and the rotational speed of the optical disc 10; A pulse counter 72 for counting an output pulse (FG signal) of the drive unit 71 according to the rotation of the spindle motor 11; And a microcomputer that determines whether the optical disc 10 is defective or not based on the count value, the level of the digitally converted tracking error signal, and the output signal of the ATIP decoder 60, and controls the recording operation accordingly. 80).

FIG. 2 shows a detailed configuration of an ATIP encoder of the optical disk drive device of FIG.

3A and 3B show a flow of a preferred embodiment of a data recording method according to a bad disk determination according to the present invention. Hereinafter, the data recording of FIGS. 3A and 3B according to the present invention will be described with reference to the configuration of FIG. The method will be described in detail.

First, when the optical disk 10 is inserted and mounted in a tray (not shown) provided therein, when there is a recording request for data input from the outside through the microcomputer 80 (S10), the microcomputer 80 ) Drives the spindle motor 11 through the servo unit 70 and the drive unit 71 to rotate and drive the optical disc 10, and also to drive the optical pickup 20 on the optical disc 10. The recording operation is performed by moving to the recording area (S11). The recording operation is as follows.

The digital recording signal processor 30a generates an error correction code (ECC Block) by adding an encoding and an error correction parity for reliability of recording / reproducing the input coded data, and the channel bit encoder. 40 converts the digital bitstream output from the digital recording signal processing unit 30a into a pulse width modulated signal form for recording on the optical disc 10, and applies the signal to the optical driver 41. 80 controls the optical driver 41 so that the recording signal is output by the optical driving current corresponding to the detected optimal recording optical power value. Accordingly, the optical driver 41 outputs a signal for recording data at an optical driving power corresponding to the applied pulse width modulated signal, so that the optical pickup 20 is applied to a program area of the optical disc 10. In this case, the microcomputer 80 causes the optical pickup 20 to maintain a signal level or duration of a recording pulse based on a specified write strategy. Record the data.

According to the data recording operation, ATIP data of FIG. 4 is FM-modulated at 22.05 kHz by the ATIP encoder shown in FIG. 2 and recorded on the optical disc 10. That is, 21.05 kHz and 23.05 kHz are recorded as data '0' and Corresponds to '1' and is FM modulated and recorded.

During the recording operation, the A / D converter 51 digitally converts and outputs a tracking error signal among the servo signals output from the R / F unit 50, and the ATIP decoder 60 performs the same. ATIP data is detected by decoding the wobble signal output from the R / F unit 50 at the time of detecting the predetermined signal 5T or 6T during the reproduction section during data recording. The ATIP decoder 60 checks whether the detected ATIP data is normally decoded in the form of FIG. 4, and when the ATIP data is normally decoded, the ATIP_OK (a) signal and the decoded ATIP data (b) are used for the servo. And outputs a signal ATIP_Sync (c) indicating whether the ATIP synchronization signal is normally detected, and outputs the signal ATIP_Sync (c) to the servo unit 70 at this time. The ATIP decoder 60 also outputs the ATIP_OK (a) signal and the ATIP_Sync (c) signal to the microcomputer 80.

Accordingly, the microcomputer 80 determines whether the optical disc 10 is defective based on the digitally converted tracking error signal and the input ATIP_OK (a) signal and the ATIP_Sync (c) signal, which are as follows. .

First, the microcomputer 80 continuously detects the level of the digitally converted tracking error signal TE (S12), and checks whether the detected signal level exceeds a preset reference level 600mv. When the level of the detected tracking error signal exceeds the reference level (S20), the microcomputer 90 continues to be detected for a predetermined time (e.g., time required for one rotation of the optical disc 10). It is checked whether the level of the tracking error signal exceeds the reference level (S30). For this purpose, the microcomputer 80 controls the pulse counter 72 to start a counting operation. The pulse counter 72 The output pulse (FG signal) output from the drive unit 71 is counted according to the rotation of the spindle motor 11, and the count value N _FG is applied to the microcomputer 80. The optical disc 10 ) During one revolution, the count value of the FG signal output from the spindle drive unit 71 is 12, for example, so that the microcomputer 80 determines the number of rotations of the optical disc 10 through the count value of the FG signal. You will know.

Based on the count value of the pulse counter 72, the microcomputer 80 continuously checks whether the level of the tracking error signal exceeds the reference level during one rotation of the optical disc 10. When the level of the tracking error signal continues to exceed the reference level for one rotation of the optical disc 10 as described above, the signal input from the ATIP decoder 60 (ATIP_OK (a) signal and ATIP_Sync (c) ) To determine whether the ATIP data is normally decoded and whether the ATIP synchronization signal is normally detected, and thereby determining whether the optical disc 10 is defective (S40). If it is determined that the data is not normally decoded or the ATIP synchronization signal is not normally detected, the microcomputer 80 replaces the optical disk 10 with a bad disk. Will be determined.

As such, when the optical disc 10 is determined to be a bad disc (S50), the microcomputer 80 performs a buffer under run prevention function to temporarily transmit data from an external host. The recording operation is interrupted and the recording operation is suspended.

Subsequently, the microcomputer 80 adjusts the current recording speed to a low speed through the servo unit 70 and the drive unit 71 (S51), and records the optical pickup 20 on the optical disc 10. After moving to the stopped position, the recording operation is performed again from the position (S52). If the recording speed is adjusted to a low speed as described above, the frequency of the tracking error signal exceeding a predetermined level is lowered as shown in FIG. Thus, as shown in FIG. 7, the servo is increased in the low frequency band on the servo loop so that the tracking gain is stabilized, thereby making the recording operation stable.

Such bad disc determination and its operation are continued until the recording operation is terminated (S60).

However, in the above embodiment, if the level of the tracking error signal does not exceed the reference level or exceeds the reference level, it is determined that the period exceeding the reference level is within one revolution of the optical disc 10. In this case, or if the ATIP data is normally decoded and the ATIP synchronization signal is determined to be normally detected, the microcomputer 80 determines the optical disc 10 as a normal disc and performs a recording operation without adjusting the recording speed ( S31).

The above-described preferred embodiments of the present invention are disclosed for purposes of illustration, and those skilled in the art can improve, change, and substitute various other embodiments within the technical spirit and scope of the present invention disclosed in the appended claims below. Or addition may be possible.

According to the data recording method according to the determination of a bad disk according to the present invention, whether or not an optical disk is defective from a synchronization signal of ATIP data modulated and inserted in accordance with the level of a tracking error signal and a wobble frequency deviation during the data recording operation of the optical disk. This is a very useful invention in which the recording operation is normally performed even if a bad disk is determined by accurately determining and adjusting the recording speed downwardly.

Claims (5)

In the data recording method of an optical disc, A first step of determining whether or not the recording medium is defective based on the level of the servo signal generated during the recording operation along the wobble track and whether the modulation-inserted signal is normally detected according to the wobble frequency deviation; And And a second step of controlling the recording operation in accordance with the determination result. The method of claim 1, And the servo signal is a tracking error signal. The method of claim 1, And detecting the level of the servo signal in the first step is reset by a predetermined time. The method of claim 1, And the modulation-inserted signal is an ATIP synchronization signal. The method of claim 1, And the control of the recording operation is a downward control of the recording speed.