KR100955477B1 - Method for accessing target position in optical disc device - Google Patents

Abstract

The present invention relates to a method of accessing a target position on an optical disc, comprising: a first step of moving an optical pickup by calculating a target movement track number to the target position when the target position is accessed except for a predetermined specific section on the optical disc; Calculating a moving error of the optical pickup from the calculated target moving track number and the actual moving track number of the optical pickup; A third step of storing the calculated moving error; A fourth step of calculating a target movement track number to the target position when the target position in the specific section is accessed; And a fifth step of moving the optical pickup by calculating the actual number of movement tracks from the calculated target number of movement tracks and the stored movement error, wherein the predetermined specific section on the optical disc that has a risk of servo interruption at the time of access. In terms of, it is a very useful invention to access the target position by applying the value updated through the learning operation, so that the target position can be accessed more quickly and accurately without fear of servo interruption.

Access, Fine Track Search, Error, Learn, Update

Description

Method for accessing target position in optical disc device             

1 shows a configuration of an embodiment of a general optical disk device,

2 shows an example of a preset specific section and the current position of the optical pickup on the optical disc;

3 is a block diagram of an embodiment of an optical disk apparatus in which a target position access method of the optical disk apparatus according to the present invention is implemented.

Fig. 4 shows the flow of a preferred embodiment of the method for accessing the target position of the optical disc apparatus according to the present invention.

※ Explanation of code for main part of drawing

10: optical disc 20: optical pickup

30: R / F part 40: digital signal processing part

50: servo unit 60: drive unit

70: micom 71: memory

The present invention relates to a method of accessing a target position of an optical disk apparatus for quickly and accurately accessing a target position on an optical disk by using a value updated through a predetermined learning operation.

1 shows the configuration of an embodiment of a general optical disc apparatus, comprising: an optical pickup 20 for reading a record signal from the optical disc 10; An R / F unit 30 for shaping the signal detected by the optical pickup 20 and outputting it as a binary signal; A digital signal processor (40) for restoring the binary signal to original data with its own clock synchronized with the binary signal; A drive unit 60 for driving a spindle motor for rotationally driving the optical pickup 20 and the optical disc 10; A servo unit (50) for controlling the drive of the drive unit (60) from the servo error signals (F.E, T.E) output from the optical pickup (20) and the rotational speed of the optical disc (10); And a microcomputer 70 which performs a target position access and a control operation according to the target position on the optical disc 10.

In the optical disk apparatus configured as described above, first, in the state where recording data exists in the data area of the optical disk 10, the microcomputer 70 sets a predetermined specific section on the optical disk 10, that is, FIG. As shown in FIG. 2, location information of the inner peripheral section K1 of the data area near the innermost circumference of the optical disk 10 and the predetermined section K2 from the data recording end position near the outermost circumference of the optical disk 10 to the inner circumference. Will remember.

In this case, the specific section is set to a section that may cause the servo operation to stop due to the movement error of the optical pickup 20.

In this state, the target position access operation of the microcomputer 70 is as follows.

First, when target location access request, the microcomputer 70 checks whether the inside of the a, based on the storage location information access request, the target position is pre-set the predetermined range (K1 or K2), and if the target location (for example, For example, when the 1000th track is within the specific section, the microcomputer 70 may move the target from the current position of the optical pickup 20 (eg, P (eg, 10000th track) in FIG. 2). The number of target movement tracks to the position is calculated (10000-1000 = 9000).

When the target movement track number is calculated, the microcomputer 70 calculates the actual movement track number by subtracting a randomly set default value (for example, 100 tracks) from the calculated target movement track number (9000-100 = 8900). The optical pickup 20 is moved by the calculated number of actual tracks.

In this manner, when the optical pickup 20 reaches the target position, the microcomputer 70 starts at the actuator of the optical pickup 20 such as a kick pulse and a brake pulse. A fine track search operation for precisely moving the optical pickup 20 to the target position by applying a jump pulse is performed.

When the target position requested for access is within the specific section, and after calculating the number of target movement tracks, calculating the actual number of movement tracks and moving the optical pickup 20 again may include moving errors of the optical pickup 20. Therefore, when the calculated number of target movement tracks is moved, the optical pickup 20 is located in a lead-in area or an unrecorded area of the optical disc 10 outside the target position, or in the extreme case, the innermost circumference of the optical disc 10. Or it may be located in the outermost circumference, in this case to prevent the servo operation can be stopped.

On the other hand, if the access request target position is not within the specific section, the microcomputer 70 moves the optical pickup 20 by the number of target movement tracks calculated as described above, and then performs the fine track search operation again. The optical pickup 20 is accurately moved to the target position.

However, in the above-described conventional target position access method of the optical disk apparatus, since the default value used when accessing a specific section of the optical disk is set arbitrarily, if the value is set too small, the optical pickup at the target position access is performed. It may be located in the lead-in area or the data unrecorded area of the disc, or in severe cases, the innermost or outermost circumference of the optical disc may cause the servo operation to be interrupted. It may not be moved near the target position, and in this case, there is a problem of access delay because the target position must be accessed again through the search operation.

Therefore, the present invention was created to solve the above problems, and by accessing the target position by applying the value updated by the learning operation to a predetermined section of the optical disc, and more quickly and without fear of stopping the servo operation. It is an object of the present invention to provide a method for accessing a target position of an optical disk device that can accurately access the target position.

In the method of accessing the target position of the optical disk apparatus according to the present invention for achieving the above object, when the target position is accessed except for a predetermined specific section on the optical disk, the optical pickup is moved by calculating the number of target movement tracks to the target position. First step to make; Calculating a moving error of the optical pickup from the calculated target moving track number and the actual moving track number of the optical pickup; A third step of storing the calculated moving error; A fourth step of calculating a target movement track number to the target position when the target position in the specific section is accessed; And a fifth step of moving the optical pickup by calculating the actual number of movement tracks from the calculated target number of movement tracks and the stored movement error.

BEST MODE Hereinafter, preferred embodiments of a method for accessing a target position of an optical disk apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 illustrates a configuration of an embodiment of an optical disk apparatus in which the target position access method of the optical disk apparatus according to the present invention is implemented. In FIG. 1, a track value or a predetermined ratio calculated through a predetermined learning operation is stored. It further comprises a memory 71.

4 is a flow chart illustrating a preferred embodiment of the method for accessing a target position of the optical disk apparatus according to the present invention. Hereinafter, the access method of FIG. 4 according to the present invention will be described in detail with reference to the configuration of FIG.

First, the microcomputer 70 performs a predetermined learning operation every time the target position is accessed except for a specific section (K1, K2 of FIG. 2) on the optical disc 10 (S10).

The microcomputer 70 calculates a target movement track number from a current position of the optical pickup 20 to a target position, and controls the optical pickup 20 to move by the calculated movement track number (S11). ).

After the movement of the optical pickup 20, the microcomputer 70 calculates a difference value between the calculated number of moving tracks and the actual number of moving tracks of the optical pickup 20, and calculates the difference value as an error value X. 71) (S12).

On the other hand, the microcomputer 70 updates the stored value of the memory 71 by using an error value calculated every time the learning operation is performed (S13). An average value of previously stored error values is calculated and stored in the memory 71 as an error value X.

In this state, when access to the target location within the specific section is requested (S20), the microcomputer 70 accesses the requested target location using the stored error value, which is as follows.

First, the microcomputer 70 calculates the target moving track number from the current position of the optical pickup 20 to the target position.

As described above, when the target movement track number is calculated, the microcomputer 70 calculates the actual movement track number by subtracting the error value stored by the learning operation from the calculated target movement track number, and calculates the actual movement track number by the calculated actual movement track number. The optical pickup 20 is moved (S21), and the optical pickup 20 is precisely moved from the moved position to the target position by performing the aforementioned fine track search operation. It is made (S22).

Unlike the above-described embodiment, if a predetermined ratio (for example, 10%) is set and stored in the memory 71 as an initial value, and in such a state, access to a target position in the specific section is requested. The microcomputer 70 calculates the number of target movement tracks as described above, and then the number of tracks 900 corresponding to the stored constant ratio (10%) from the calculated target movement tracks (for example, 9000 tracks). The actual number of moving tracks is calculated by subtracting and the actual number of moving tracks is calculated so that the target position is accessed as described above.

In this case, the microcomputer 70 moves the optical pickup 20 by the target movement track number calculated as described above every time the target position access except for the specific section is performed. By calculating the difference value of the actual number of moving tracks of the optical pickup 20 and continuously updating the constant ratio based on the difference, the target position can be accessed more quickly and accurately based on the updated constant ratio.

Unlike the above-described embodiment, the number of moving tracks for the optical disc 10 (for example, 0 to 1000 tracks, 1000 to 2000 tracks, 2000 to 3000 tracks, etc.) is preset. In the state where the target position except for the specific section is accessed, the microcomputer 70 moves the optical pickup 20 by the number of target movement tracks (eg, 9100) to the target position. The difference value between the number of target movement tracks and the actual number of movement tracks of the optical pickup 20 is calculated, and the calculated difference value is stored in the memory 71 in association with the set interval of the corresponding movement tracks (9000 to 10000 tracks). do.

In this state, when access to the target position in the specific section is requested, the microcomputer 70 calculates the target movement track number as described above, and then calculates the calculated target movement track number (for example, 9100 tracks). And the number of tracks stored in association with the plurality of tracks is detected from the memory 71, and the actual number of tracks is calculated by subtracting the detected number of tracks from the calculated target number of tracks. Similarly, the target position is accessed.

In this case, the microcomputer 70 calculates the difference value between the number of target movement tracks and the number of actual movement tracks as described above every time the target position is accessed except for the specific section, and calculates the calculated difference value of the corresponding number of movement tracks. By continuously storing and updating the stored value in association with the section, the target position can be accessed more quickly and accurately based on the updated number of tracks.

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.

In the method of accessing the target position of the optical disk apparatus according to the present invention as described above, the target position is accessed by applying a value updated through the learning operation to a predetermined specific section on the optical disk which may cause servo interruption at the time of access. It is a very useful invention that can access the target position more quickly and accurately without fear of servo interruption.

Claims (6)

A first step of moving the optical pickup by calculating the number of target movement tracks to the target position when the target position is accessed except for a specific section corresponding to the predetermined section in the inner circumferential direction from the leading section of the data area on the optical disc and the last data recording position. step; Calculating a moving error of the optical pickup from the calculated target moving track number and the actual moving track number of the optical pickup; A third step of storing the calculated moving error; A fourth step of calculating a target movement track number to the target position when the target position in the specific section is accessed; And And a fifth step of subtracting the stored movement errors from the calculated target movement tracks, calculating the actual movement tracks, and then moving the optical pickups. delete The method of claim 1, The third step may further include performing the first to third steps every time the target position is accessed except for the specific section, and updating the previously stored moving error value based on the calculated moving error. A method of accessing a target position of an optical disc device, characterized in that. delete A first step of calculating a target movement track number to the target position when accessing a target position in a specific section corresponding to a predetermined section in the inner circumferential direction from the leading section of the data area on the optical disc and the last data recording position; A second step of obtaining the actual number of moving tracks by subtracting the number of tracks corresponding to a predetermined ratio from the calculated target number of moving tracks; And Including the third step of moving the optical pickup by the actual number of movement tracks, The predetermined ratio is updated according to a difference between a target movement track number to the target position calculated at every target position access except for the specific section and the actual movement track number of the optical pickup. Way. delete

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