KR20050036358A - Method for controlling mirror slice level in optical disc driver - Google Patents

Abstract

The present invention relates to a method of adjusting a mirror slice level such that a mirror signal required for a track count and an actuator brake is normally output regardless of an optical disc state during a track jump operation. A first step of slicing a high frequency reproduction signal to detect a mirror signal; And a second step of adjusting the mirror slice level according to the high and low intervals of the detected mirror signal, thereby adjusting the mirror slice level to an optimal value according to a disk state during track jumping for a target track search. By adjusting, the target track can be precisely searched using the normal mirror signal and the track zero cross signal from now on regardless of the disk state, and it is a very useful invention that the servo operation is made stable.

Description

{Method for controlling mirror slice level in optical disc driver}

The present invention relates to a method of adjusting a mirror slice level so that a mirror signal required for a track count, an actuator brake, or the like is always normally output regardless of an optical disc state during a track jump operation.

In general, in order to navigate to the desired position (track) on the optical disc, the laser beam generated from the optical pickup must be accurately moved from the current track to the target track and tracked on the target track. This operation is performed by search or seek. It is called.

This search operation calculates the number of tracks to the target track and moves the optical pickup directly to the desired track when the number of tracks to be jumped is hundreds to thousands or more, and the tracking actuator of the optical pickup when the remaining tracks are several hundred tracks or less. The target track is searched by moving. This track jump is called a track crossing.

On the other hand, in a general optical disk device, a mirror (MIRR) signal obtained from the RF signal during the above search operation (a signal generated by the R / F unit in the mirror surface where there is no data between tracks and tracks in the track crossing) and tracking The track zero cross (TZC) signal obtained from the error (TE) signal is used because the track count and the actuator brake operation are performed from the MIRR signal and the TZC signal during the track jump for the target track search.

FIG. 1 illustrates an example of a TE signal at three track traverses in a forward direction, a TZC signal obtained therefrom, and an RF signal and a MIRR signal obtained therefrom. The MIRR signal sliced from the RF signal is shown in FIG. It is normal without noise and has a phase difference of exactly 90 degrees between the MIRR signal and the TZC signal. In this case, the MIRR signal is possible because the RF Bottom signal can obtain an accurate traverse signal for the track and the mirror surface when the track is crossed. will be.

Therefore, the optical disk apparatus performs a stable search operation so that the MIRR signal and the TZC signal have a phase difference of exactly 90 degrees.

However, there is a significant difference in the MIRR signal depending on the reflectivity of each optical disk and the state of the pit and mirror surface.

For example, if the RF Bottom signal is not accurate and the level is abnormal when crossing the track as shown in FIG. 2, the MIRR signal is abnormal even though the TZC signal is normal. Thus, the abnormal MIRR signal is obtained from the RF signal. This is because the variable range of the reference signal MIRR Slice Level for extraction is limited.

That is, until now, the slice level could be adjusted by selecting the partial pressure ratio to the power supply voltage. If the disk is not in good condition due to scratches, or if the pit and mirror surface are incorrectly formed during manufacture, the RF bottom signal is crossed during the track. May not be output correctly, in which case only a fixed or limited range of slice level selections could not adequately respond to the state of each such disk.

Therefore, conventionally, when the MIRR signal is abnormal according to the state of the optical disc, tracking may not slide or target tracks may be unstable, and servo operation may be unstable due to failure to determine accurate brake operation and on track after crossing the track. Done.

Accordingly, the present invention has been made to solve the above problems, and by appropriately adjusting the mirror slice level for the RF signal in accordance with the disk state, an optical disk apparatus capable of accurately searching the target track with stable servo operation It is an object of the present invention to provide a mirror slice level adjustment method.

According to an aspect of the present invention, there is provided a method for adjusting a mirror slice level of an optical disk device, the method comprising: a step of detecting a mirror signal by slicing a high frequency reproduction signal at a preset mirror slice level when jumping to a target track; And a second step of adjusting the mirror slice level according to the magnitudes of the high and low sections of the detected mirror signal.

Detecting a bottom signal of a high frequency reproduction signal when jumping to a target track; And a second step of adjusting the mirror slice level from the peak level and the bottom level of the detected bottom signal, respectively.

Hereinafter, a preferred embodiment of a method for adjusting a mirror slice level of an optical disk apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 shows the configuration of an embodiment of an optical disk apparatus in which a mirror slice level adjusting method according to the present invention is implemented, comprising: an optical pickup 20 for reading recorded data from a target position of the optical disk 10; Filtering the signal output by the optical pickup 20 to output a high frequency reproduction signal (RF signal) in the form of a binary signal, and outputs a mirror (MIRR) signal sliced from the RF signal according to a set mirror slice level. R / F section 30; A digital signal processor (40) for restoring and outputting the output RF signal to original data with its clock synchronized with the binary signal; A drive unit 70 for rotating the optical disc 10 by applying an appropriate driving voltage to the spindle motor M and moving the optical pickup 20; A servo unit (60) for controlling the driving of the drive unit (70) from a focusing error (FE) signal and a tracking error (TE) signal output from the optical pickup (20) and the rotational speed of the optical disc (10); A TZC generator 31 generating and outputting a track zero cross (TZC) signal from the TE signal; And adjusting the mirror slice level set in the R / F unit 30 according to the state of the optical disc 10, and performing a track jump operation for a target track search from the MIRR signal and the TZC signal output therefrom. It is comprised including the microcomputer 50. As shown in FIG.

4 is a flowchart illustrating an exemplary embodiment of a method for adjusting a mirror slice level of an optical disk device according to the present invention, and FIG. 5 illustrates an example of a MIRR signal sliced to a mirror slice level that is variably set according to the present invention. Hereinafter, the level adjusting method of FIG. 4 according to the present invention will be described in detail with reference to the configuration of FIG. 3 and the example of the MIRR signal of FIG. 5.

First, as described above, the MIRR signal and the TZC signal are used during the track jump for the target track search, because the track count and the actuator brake operation are performed from the MIRR signal and the TZC signal.

However, the MIRR signal varies considerably depending on the reflectance of each optical disk and the state of the pit and the mirror surface. Therefore, in the present invention, the slice level of the MIRR signal set in the R / F unit 30 is adjusted appropriately during the initial operation. By doing so, a normal MIRR signal can be obtained regardless of the state of the optical disc.

First, the micom 50 performs the mirror slice level adjustment operation at the initial operation according to the insertion and mounting (S10) of the optical disk 10, for this purpose, the micom 50 is the servo unit 60 and the drive Through the unit 70, the tracking actuator inside the optical pickup 20 is moved to the target track during the initial operation.

Accordingly, the tracking actuator traverses a predetermined track, and the R / F unit 30 slices a high frequency reproduction signal (RF signal) generated along the track crossing to a mirror slice level set therein, and performs a square wave MIRR signal. In this case, as shown in FIG. 5, the microcomputer 50 has a variable range of mirror slice levels ((1) to (3) of FIG. 5) based on the reference mirror slice level ((2) of FIG. 5). Since the microcomputer 50 sets the mirror slice level by a predetermined size for each step within the variable range (S11), the MIRR signal (MIRR (1 in FIG. 5) is sliced to the variable set level. ), MIRR (2) and MIRR (3) are continuously monitored so as to detect the magnitude of the high section (A) of FIG. 5 and the magnitude of the low section (B) of FIG. do.

When the variable setting of the step-by-step mirror slice level within the variable range and the size detection of the high and low sections of the MIRR signal are completed, the microcomputer 50 generates the smallest difference in size between the detected high and low sections. The mirror slice level (FIG. 5 (2)) of (MIRR (2) in FIG. 5) is determined as an optimal value, and the mirror slice level of the R / F unit 30 is adjusted to the value (S13).

On the other hand, during the track traversal for the target track search, the microcomputer 50 counts the current number of moving tracks from the TRR signal of the square wave generated from the MIRR signal and the TE signal sliced to the adjusted level and the target track. Search (S14).

As described above, when the mirror slice level of the R / F unit 30 is set to be adjusted to be suitable for the disk state, when the target track needs to be searched according to the playback request (S20) of the user, the microcomputer 50 The track jump operation for the target track search is performed. For this purpose, the microcomputer 50 calculates the number of moving tracks from the current track to the target track, and then moves the optical pickup to move by the calculated number of moving tracks. 20) By applying drive control, i.e., kick pulse, to the tracking actuator therein, the tracking actuator is moved to the reclaimed target track.

According to the track crossing of the tracking actuator, the R / F unit 30 slices an RF signal generated along the track crossing at the adjusted mirror slice level and outputs a MIRR signal, and outputs the TZC generation unit ( 31 generates and outputs a TZC signal of a square wave from the TE signal output from the optical pickup 20, wherein the TZC signal is a signal turned on / off at the track cross time.

The microcomputer 50 continuously counts the number of moving tracks of the tracking actuator from the output MIRR signal and the TZC signal, while monitoring the output MIRR signal to detect the magnitude of the high section and the low section. The adjusted mirror slice level is readjusted (S21), and the readjustment operation during the target track search for data reproduction is performed a predetermined number of times.

Through the readjustment operation, a normal MIRR signal having a phase difference of 90 degrees with the TZC signal can be obtained.

On the other hand, when the counted number of moving tracks and the calculated number of moving tracks are the same, the microcomputer 50 applies a brake pulse to the tracking actuator, that is, the microcomputer 50 vibrates in the direction of the tracking actuator. By rapidly suppressing the vibration of the tracking actuator by applying the brake in the opposite direction of the target track through the track jump operation (S22) to accurately search (S22), and then to perform the requested playback operation from the searched target track.

FIG. 6 illustrates a configuration of another embodiment of an optical disk apparatus in which a mirror slice level adjustment method according to the present invention is implemented. In the configuration of FIG. 3, a bottom signal is detected from the RF signal, and the detected And a bottom signal detector 32 for detecting the peak level and the bottom level of the bottom signal, respectively.

In the optical disk device configured as described above, unlike the above-described embodiment in which the MIRR signal is directly monitored in consideration of the reflectance of each optical disk and the state of the pit and the mirror surface, and the mirror slice level is adjusted therefrom, the RF bottom at the track crossing is provided. If the signal is not correct, the MIRR signal is also abnormal, so that the mirror slice level is adjusted using the RF bottom signal, which will be described in detail below.

FIG. 7 illustrates an operation flow of another embodiment of the method for adjusting the mirror slice level of the optical disk device according to the present invention, and FIG. 8 illustrates the RF bottom signal detected from the RF signal for adjusting the mirror slice level according to the present invention. As an example, hereinafter, the level adjusting method of FIG. 7 according to the present invention will be described in detail with reference to the configuration of FIG. 6 and the example of the RF bottom signal of FIG.

First, the micom 50 performs a mirror slice level adjustment operation at the initial operation according to the insertion and mounting (S30) of the optical disk 10, for this purpose, the micom 50 is the servo unit 60 and the drive The tracking actuator within the optical pickup 20 is moved through the unit 70 by a predetermined track. Accordingly, when the tracking actuator traverses a predetermined track, the bottom signal detector 32 is connected to the R / F unit 30. The bottom signal (Fig. 8 (2)) is detected from the RF signal (1) of Fig. 8 (S31), and the peak level and the bottom level of the detected bottom signal are detected (S32).

The microcomputer 50 determines an intermediate value between the detected peak level and the bottom level as an optimal mirror slice level ((3) of FIG. 5) and adjusts the mirror slice level to the value (S33). In the above-described track traversal for the target track search, the current number of moving tracks is counted from the TZC signal of the square wave generated from the MIRR signal and the TE signal sliced to the adjusted level, as in the above-described embodiment. The target track is searched (S34).

As described above, when the mirror slice level of the R / F unit 30 is set to be properly adjusted to the disk state, when the target track needs to be searched according to the user's playback request (S40) or the like, the microcomputer 50 When crossing the track for the target track search, the adjusted mirror slice level is readjusted (S41) from the bottom signal of the RF signal as described above, and this readjustment operation during the target track search for data reproduction is predetermined. It is made a predetermined number of times.

On the other hand, the microcomputer 50 searches for the target track (S42) while counting the number of moving tracks based on the MIRR signal and the TZC signal sliced to the readjusted level, which is the same as in the above-described embodiment. same.

Or more, preferred embodiments of the present invention described above, for the purpose of illustration, those skilled in the art, within the technical spirit and the technical scope of the present invention disclosed in the appended claims below, to further improve various other embodiments Changes, substitutions or additions will be possible.

The method for adjusting the mirror slice level of the optical disk apparatus according to the present invention as described above comprises a mirror slice level at an optimal value according to the disk state from the duty ratio of the mirror signal or the bottom signal of the RF signal during the track jump for the target track search. By adjusting, the target track can be precisely searched using a normal mirror signal and a track zero cross signal from now on regardless of the disk state, and it is a very useful invention that the servo operation is made stable.

1 and 2 illustrate a TE signal, a TZC signal obtained therefrom, and an RF signal and a mirror signal obtained therefrom, respectively.

3 is a block diagram of an embodiment of an optical disk apparatus in which a mirror slice level adjusting method according to the present invention is implemented.

4 is a flowchart illustrating a preferred embodiment of a method for adjusting a mirror slice level of an optical disk device according to the present invention;

5 illustrates a MIRR signal sliced to a variable mirror slice level set according to the present invention;

Fig. 6 shows the construction of another embodiment of the optical disk device in which the mirror slice level adjusting method according to the present invention is implemented.

FIG. 7 illustrates an operation flow of another embodiment of a method of adjusting a mirror slice level of an optical disk device according to the present invention;

8 illustrates a bottom signal detected from an RF signal for mirror slice level adjustment according to the present invention.

※ Explanation of code for main part of drawing

10: optical disc 20: optical pickup

30: R / F section 31: TZC generating section

32: bottom signal detector 40: digital signal processor

50: microcomputer 60: servo unit

70: drive unit M: spindle motor

Claims (8)

A first step of detecting a mirror signal by slicing a high frequency reproduction signal at a preset mirror slice level when jumping to a target track; And And a second step of adjusting the mirror slice level in accordance with the magnitudes of the detected high and low sections of the mirror signal. The method of claim 1, The first and second steps are mirror slice level adjustment methods of an optical disc apparatus, characterized in that at the initial operation according to the insertion and insertion of an optical disc. The method of claim 1, In the first step, the optical disk apparatus may detect a mirror signal by varying the mirror slice level by a predetermined size within a preset mirror slice level variable range and slicing the high frequency reproduction signal with the variable mirror slice level. To adjust the mirror slice level. The method of claim 1, And said second step adjusts a preset mirror slice level to a mirror slice level when the magnitude difference between the high and low sections of the detected mirror signal is smallest. The method of claim 1, And a third step of searching for the target track while counting the number of moving tracks from the mirror signal sliced to the adjusted level and the track zero cross signal detected from the tracking error signal. How to adjust slice level. The method of claim 5, A fourth step of slicing a high frequency reproduction signal at the adjusted mirror slice level and detecting a mirror signal when jumping to a target track according to a data reproduction request; And And a fifth step of re-adjusting the adjusted mirror slice level according to the magnitudes of the detected high and low intervals of the mirror signal. Detecting a bottom signal of a high frequency reproduction signal when jumping to a target track; And And a second step of adjusting a mirror slice level from the peak level and the bottom level of the detected bottom signal. The method of claim 7, wherein And in the second step, adjusting the mirror slice level to an intermediate value between the detected peak signal and the bottom level of the detected bottom signal.