KR100774618B1 - Method for controlling focus position in optical disc driver - Google Patents

Abstract

The present invention relates to a focus position adjusting method of an optical disk apparatus that enables an optimal focus position adjustment to a recordable optical disk, the first step of measuring a predetermined number of RF levels while scanning a predetermined region of an inserted optical disk. ; Determining whether to repeat the scan operation and the RF level measurement operation based on the measured RF level pattern; A third step of moving the scan area based on a point at which the highest level of the measured RF levels is measured according to the determination result; A fourth step of performing the scan operation and the RF level measurement operation on the moved scan area again; And a fifth step of adjusting a focus position based on the RF level measured through the redo, and measuring a predetermined number of RF levels while scanning a predetermined area of the optical disc for adjusting the focus position. If the RF level does not meet the conditions for optimally adjusting the focus position, the scan area can be moved and retryed according to the measured RF level pattern, so that the focus position can be optimally adjusted in a shorter time. This is a very useful invention in which reproduction and recording quality are improved.

RF signal, focus position, objective lens, scan, retry

Description

Method for controlling focus position in optical disc driver

1 illustrates a configuration of an embodiment of an optical disk device in which a focus position adjusting method according to the present invention is implemented.

2 shows a flow of a preferred embodiment of the focus position adjusting method of the optical disk apparatus according to the present invention,

3 to 5 illustrate patterns of RF levels measured by scanning a predetermined area of the optical disk.

※ Explanation of code for main part of drawing

M: Spindle Motor 10: Optical Disc

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

60: servo unit 61: drive unit

70: micom 71: memory

The present invention relates to a method for adjusting the focus position of an optical disc apparatus such that an optimal focus position adjustment is made with respect to a recordable optical disc.

In general, various servo adjustments are required to perform recording on an optical disc. The focus position depends on the state of the disc, mecha, and optical pickup, and greatly affects playback and recording quality. Coordination is quite important.

That is, when the focus position of the objective lens (focus lens) with respect to the inserted optical disc is not appropriate, the reproduction and recording quality may be deteriorated, so it is necessary to optimally adjust the focus position with respect to the inserted disc.

In general, in the case of adjusting the focus position with respect to the optical disk on which the recording data exists, the predetermined predetermined area of the optical disk is scanned to detect and adjust the optimum focus position value based on the level of the RF signal obtained therefrom.

However, in the conventional focus position adjusting method, as described above, the predetermined position of the optical disk is scanned and the focus position is adjusted based on the RF signal obtained therefrom. In this case, focus drop may occur, and setting the predetermined area to a narrow area narrows the adjustment range of the focus position, making it difficult to optimally adjust the focus position, thereby reducing playback and recording quality. There is a problem, and there is a problem that a lot of time is spent in adjusting the focus position optimally.

Therefore, the present invention was created to solve the above problems, and while measuring a predetermined number of RF levels while scanning a predetermined area of the optical disk for focus position adjustment, if the measured RF level is optimally adjusted focus position If the conditions are not met, the scan area is moved and retryed according to the measured RF level pattern, so that the focus position can be optimally adjusted in a shorter time and the reproduction and recording quality can be improved. It is an object of the present invention to provide a method for adjusting the focus position of an optical disk device.

According to an aspect of the present invention, there is provided a method of adjusting a focus position of an optical disk device, the method including: measuring a predetermined number of RF levels while scanning a predetermined region of an optical disk in which the optical disk is inserted; Determining whether to repeat the scan operation and the RF level measurement operation based on the measured RF level pattern; A third step of moving the scan area based on a point at which the highest level among the measured RF levels is measured according to the determination result; A fourth step of performing the scan operation and the RF level measurement operation on the moved scan area again; And a fifth step of adjusting a focus position based on the RF level measured through the rerun.

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

1 is a block diagram of an embodiment of an optical disk apparatus in which a focus position adjusting method according to the present invention is implemented. A digital recording signal processing unit converts the recording format by adding an error correction code (ECC) to the input digital data. 30a; 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) according to the light quantity driving signal and for detecting a recording signal; An R / F unit 50 for shaping the signal detected by the optical pickup 20 and outputting it as a binary signal; A digital reproduction signal processor (30b) for restoring and outputting the binary signal to original data with its own clock synchronized with the binary signal; A drive unit 61 driving the spindle motor M for rotating the optical disk 10 and the optical pickup 20; A servo unit 60 for controlling the driving of the drive unit 61 from the tracking error signal TE and the focus error signal FE of the optical pickup 20 and the rotational speed of the optical disc 10; A memory 71 for storing various control data required for the reproduction and recording of the optical disc 10; And scanning a predetermined area of the optical disc 10 to measure a predetermined number of RF levels with respect to the RF signal obtained therefrom, and when the pattern of the measured RF level satisfies a condition for optimally adjusting the focus position. And a micom 70 that adjusts the focus position based on the highest level among the measured levels, and otherwise moves and retrys the scan area according to the pattern of the measured levels. .

2 is a flow chart illustrating a preferred embodiment of the method for adjusting the focus position of the optical disk apparatus according to the present invention. Hereinafter, the method for adjusting the focus position of FIG. 2 according to the present invention will be described in detail with reference to the configuration of FIG. 1. Shall be.

First, when the optical disc 10 is inserted and mounted (S10), the microcomputer 70 moves the optical pickup 20 to a predetermined region of the optical disc 10 which is preset for adjusting the focus position. The microcomputer 70 scans the predetermined area through the optical pickup 20 (S11).

When the reproduction RF signal is output through the R / F unit 50 and the digital reproduction signal processing unit 30b through the scan operation, the microcomputer 70 predetermined the predetermined interval from the first measurement point with respect to the RF signal. The number (for example, nine) of the RF level is measured (S12), wherein the predetermined region is set to enable the RF level measurement as described above for the RF signal.

Accordingly, when a predetermined number (9) of RF levels are measured with respect to the RF signal at an initial measurement point (for example, 46) at predetermined intervals, the microcomputer 70 may measure the predetermined number of RF levels. The highest RF level is checked, and it is checked whether the highest RF level is measured at an intermediate point (for example, 48 to 52) among the predetermined number of measurement points (for example, 46 to 54) (S20).

In addition, the microcomputer 70 checks the measured number of the predetermined number (9) RF levels in order to count the RF level of increasing size to determine whether the count value is 3 to 7 (S30). The microcomputer 70 counts an RF level whose magnitude is larger than the RF level measured immediately before the measured number of RF levels.

As a result of the check, when the highest RF level is measured at the intermediate point as shown in FIG. 3 and the count value is 3 to 7, the microcomputer 70 performs the measured highest RF without retrying. The optimum focus position value of the objective lens with respect to the optical disc 10 is detected based on the level, and the focus position of the objective lens is optimally adjusted based on the detected value (S31).

However, if the check result indicates that the highest RF level is not measured at the intermediate point or the count value is 2 or less or 8 or more, the microcomputer 70 moves the scan area to perform the scan operation and the RF level measurement operation. When the retry operation is performed, the microcomputer 70 searches for an area corresponding to 4 points in the-direction from 4 points in the-direction based on the point where the highest RF level is measured. As a scan area (S40), the area is scanned and an RF level measurement operation is performed (S41).

An example of the above-described retry operation is as follows.

As a result of the check, if the highest RF level is not measured at the intermediate point as shown in FIG. 4 or the count value is 8 or more, the microcomputer 70 determines the point (eg, the point at which the highest RF level is measured). 54) Scanning an area corresponding to 4 points (point 58) in the-direction from 4 points (point 50) in the -direction and a predetermined number (9) at a predetermined interval from the point 50 for the RF signal output therefrom. Measure the RF level.

Accordingly, when a predetermined number (9) RF levels are measured for the RF signal from the first measurement point 50 at predetermined intervals, the microcomputer 70 performs the highest RF level among the measured RF levels as described above. If it is measured at an intermediate point (for example, 52 to 56) among the predetermined number of measurement points 50 to 58 and the number of increasing RF levels is 3 to 7, the highest RF If the level is measured at an intermediate point and the number of increasing RF levels is 3-7, the microcomputer 70 will optimally focus the objective lens with respect to the optical disc 10 based on the measured highest RF level. The position value is detected, and the focus position of the objective lens is optimally adjusted based on the detected value.

Another example of the above-described retry operation is as follows.

As a result of the check, if the highest RF level is not measured at the intermediate point as shown in FIG. 5 or the count value is 2 or less, the microcomputer 70 determines the point (eg, the point at which the highest RF level is measured). 46 is a predetermined number (9) at a predetermined interval from the point 42 with respect to the RF signal outputted therefrom while scanning an area corresponding to 4 points (point 50) in the + direction from the 4 points (point 42) in the-direction Measure the RF level.

Accordingly, when a predetermined number (9) RF levels are measured for the RF signal at a predetermined interval from the initial measurement point 42, the microcomputer 70 performs the highest RF level among the measured RF levels as described above. If it is measured at an intermediate point (for example, 44 to 48) among the predetermined number of measurement points 42 to 50, and if the number of increasing RF levels is 3 to 7, the highest RF If the level is measured at an intermediate point and the number of increasing RF levels is 3-7, the microcomputer 70 will optimally focus the objective lens with respect to the optical disc 10 based on the measured highest RF level. The position value is detected, and the focus position of the objective lens is optimally adjusted based on the detected value.

As described above, in the present invention, a predetermined number of RF levels are measured at predetermined intervals while scanning a predetermined region of the optical disc 10 to adjust the focus position, but if the measured RF level is used to optimally adjust the focus position. If the condition is not satisfied, the microcomputer 70 moves and retrys the scan area to adjust the focus position of the objective lens with respect to the optical disc 10 to an optimal state.

The retry operation may be repeatedly performed within a predetermined number of times.

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 would be possible.

In the method of adjusting the focus position of the optical disk apparatus according to the present invention as described above, a predetermined number of RF levels are measured while scanning a predetermined region of the optical disk for adjusting the focus position, and if the measured RF level is optimally adjusted the focus position. If the condition is not satisfied, the scan area can be moved and retryed according to the measured RF level pattern, so that the focus position can be optimally adjusted in a shorter time, thereby improving the reproduction and recording quality. It is a very useful invention.

Claims (6)

A first step of measuring a predetermined number of RF levels while scanning a predetermined area of an optical disc mounted; Determining whether to repeat the scan operation and the RF level measurement operation based on the measured RF level pattern; A third step of moving the scan area based on a point at which the highest level of the measured RF levels is measured according to the determination result; A fourth step of performing the scan operation and the RF level measurement operation on the moved scan area again; And And a fifth step of adjusting a focus position based on the RF level measured by the re-execution. The method of claim 1, The second step may include checking whether the highest level of the predetermined number of RF levels is measured at an intermediate measurement point; Checking whether the number of levels of which the magnitude increases among the measured number of RF levels is a predetermined number; And And if the highest level is not measured at the intermediate measuring point or the number of increasing levels thereof is not the predetermined number, determining that the scan operation and the RF level measuring operation are performed again. A focus position adjusting method of an optical disc device, characterized in that the configuration. The method of claim 1, The second step may include checking whether the highest level of the predetermined number of RF levels is measured at an intermediate measurement point; Checking whether the number of levels of which the magnitude increases among the measured number of RF levels is a predetermined number; And And determining that the scan operation and the RF level measurement operation are not performed again when the highest level is measured at the intermediate measuring point and the number of levels of which the size is increased is the predetermined number. A focus position adjusting method of an optical disk device, characterized in that made. The method of claim 3, wherein And adjusting the focus position based on the measured RF level, in accordance with the determination result. The method of claim 1, The first step is the method of adjusting the focus position of the optical disk device, characterized in that for measuring the RF level at a predetermined interval from the first measurement point of the predetermined area. The method of claim 1, In the fifth step, the focus position of the optical disk apparatus is adjusted based on the highest level among the measured RF levels.

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