KR100288790B1 - Optical disc high speed access device and method - Google Patents

Abstract

When the optical pickup reaches the target track during the optical pickup movement between tracks in which the rotational speed of the optical disk is changed, the present invention even if the rotational speed of the optical disk at that time reaches the normal rotational speed in the track. An apparatus and method for accessing a high speed optical disc, wherein the reproduction synchronization clock is changed to a clock corresponding to the rotational speed of the optical disc so that the recording signal on the optical disc can be detected and restored immediately after the optical pickup is moved. A fast access method of a disc may include: a first step of detecting whether a target track of the optical pickup is moved when an optical pickup moves between tracks in which a rotational speed of a reproduced optical disc is changed; A second step of detecting a rotational speed of the optical disc at the completion of movement of the target track; Setting a period of a regeneration synchronous clock corresponding to the detected rotation speed; And a fourth step of restoring data of the recording signal detected by the set reproducing synchronization clock, which is a very useful invention to speed up the access speed during the inter-track movement reproduction of the optical disc.

Description

Optical disk high speed access device and method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high speed access device and a method of an optical disk for shortening the data access time due to movement between tracks when data is reproduced on an optical disk by optical pickup. When the optical pickup moves between tracks, when the optical pickup reaches the target track, the playback synchronous clock is started at a clock corresponding to the current rotation speed even before the rotation speed of the optical disc reaches the normal rotation speed on the track. The present invention relates to a high speed access apparatus and a method of an optical disc, which is adapted to be changed so that a recording signal on the optical disc can be detected and restored immediately after the movement of the optical pickup.

In general, the optical disc is formed in a disc shape, and the diameter of the track located at the innermost circumference of the optical disc is about 50 mm, and the diameter of the track located at the outermost circumference is about 116 mm, and thus the respective tracks for a predetermined angle are different. The circumferential lengths of are also different.

If the optical disk formed as described above is read out by the CAV (Constant Angular Velocity) method, which is driven and maintained at a constant angular velocity, when the data on the track having a different rotation speed from the track currently being reproduced is requested. (long jump) (Fig. 5), driving the sled motor to move the optical pickup in the radial direction on the optical disk and simultaneously driving the spindle motor to decelerate (or accelerate) the rotation speed of the optical disk. Let's go.

After the optical pickup is moved to the target track by the sled motor, when the optical disk reaches a constant corresponding rotation speed (about 4200 rpm in FIG. 5) at the target track by the spindle motor, the servo The recording signal on the optical disc is synchronized by the reproduction synchronous clock adjusted for the rotational speed in the track while maintaining the constant rotational speed by the control, thereby detecting and restoring data.

The above process is also performed in the disc section rotating at the same angular velocity. If a defect section is encountered during the playing of the track, the process is played by decelerating the rotating speed and moving the track during the playing at the reduced rotational speed in the region. When the optical pickup is made, the optical disc returns to the normal rotational speed (B in FIG. 5), and reads the recording signal when the normal rotational speed (5000 rpm in FIG. 5) is reached.

However, in the regeneration movement process as described above, the time that the optical pickup is moved to the target track by the sled motor, the time that the rotational speed of the optical disk reaches a constant rotational speed in the target track by the spindle motor It takes about 10 times longer. Therefore, even after the movement of the target track of the optical pickup, the normal rotation in the track in which the GFS (Good Frame Sync.) Signal is generated informing that the proper number of synchronization signals have been detected within a predetermined time in the high frequency signal read out by the optical pickup. Since the detection of the recording signal is delayed until the speed is reached, there is a problem that a large amount of access time is required when moving the section in which the rotational speed is changed.

Accordingly, an object of the present invention is to provide a high speed access apparatus and a method for an optical disk, which can reduce the data detection access time required for moving between tracks on an optical disk. It is.

1 shows a general configuration of an optical disc player,

FIG. 2 shows a detailed configuration of the phase synchronizer of FIG.

3 is a flowchart of an optical disk fast access method according to the present invention;

4 is a view showing an example of the time required for moving the target track of the optical pickup and the rotational speed of the optical disk;

Fig. 5 shows the type of movement between tracks in which the rotational speed is variable.

※ Explanation of code for main part of drawing

10: motor drive unit 10b: rotational speed detection unit

20: spindle motor 30: optical pickup

40: sled motor 50: R / F part

60: digital signal processing unit (DSP) 70: phase synchronization unit (PLL)

71: phase comparator (COMP.) 72: low pass filter (LPF)

73: voltage controlled oscillator (VCO) 74: divider

90: servo unit 100: MICOM

A high speed access method of an optical disk according to the present invention for achieving the above object, in the optical disk access method, corresponding to the movement target track during the optical pickup movement between tracks in which the rotation speed of the optical disk is changed A first step of variably setting a period of the regeneration synchronous clock; And a second step of detecting a recording signal by the variable set synchronization clock when the optical pickup reaches the movement target track.

In addition, the high speed access device of the optical disk according to the present invention comprises: clock generating means for generating a clock which is synchronized with a signal detected from the optical disk; And a clock varying means for varying the reference clock for phase synchronization of the clock generating means in a period different from the period of the normal reference clock scheduled for the movement target track during the optical pickup movement between tracks in which the rotational speed of the optical disk is changed. It is characterized by being configured.

In the high speed access device and method of the optical disk according to the present invention constructed and configured as described above, when the inter-track movement of the optical pickup whose rotation speed of the optical disk is changed during the reproduction of the optical disk is requested, the clock variable means The period of the regeneration synchronous clock generated from the clock generating means is changed, and the period of the reproducing synchronous clock is changed to a period corresponding to the rotation speed of the optical disc at the time when the optical pickup arrives at the movement requested target track, and the optical pickup is the target. When the track is reached, the recording signal read out from the optical disk is phase-locked and detected and reproduced by the reproduction synchronous clock generated from the clock generating means even before the normal rotational speed of the optical disk in the track is reached.

Best Mode for Carrying Out the Invention An exemplary embodiment of an optical disk high speed access device and a method thereof according to the present invention will be described in detail with reference to the accompanying drawings.

An optical disk reproducing apparatus, in which a preferred embodiment of the optical disk high speed access apparatus according to the present invention is constructed, has a spindle motor 20 for rotating a mounted optical disk, as shown in FIG. An optical pickup 30 for condensing the light on the signal recording surface of the rotating optical disk, and then reading the recorded digital signal by detecting the light reflected by the pit and converting the light into an electrical signal; A sled motor 40 for moving the optical pickup 30 in a radial direction of the optical disk; A motor driver 10 for driving both motors 20 and 40; A servo unit (90) for controlling rotation of the optical pickup (30) and the optical disc by a focus error (F.E.) and tracking error signal (T.E.) output from the optical pickup (30); An R / F unit 50 for filtering the analog high frequency signal read out by the optical pickup 30; A phase-locked loop (70) for synchronizing a reproduction synchronization clock applied from the outside according to the phase of the analog signal output from the R / F unit (50); A digital signal processor (DSP) for digitally restoring an analog signal output from the R / F unit 50 and performing signal processing based on the reproducing synchronous clock outputted synchronously from the phase synchronizer 70. ); A rotational speed detector 10b detecting a rotational speed of the spindle motor 20; And a microcomputer (MICOM) 100 controlling the servo unit 90 and the phase synchronizing unit 70 according to the detected rotational speed information and controlling the data reproduction process.

On the other hand, the phase synchronizer 70, as shown in more detail in Figure 2, the frequency divider for dividing the oscillation signal (74); A phase comparator (71) for comparing the phase of the analog signal output from the R / F unit (50) with the phase of the divided signal to generate a phase difference signal proportional to the difference; A low pass filter 72 for averaging a signal generated by the phase comparator 71; And a voltage controlled oscillator 73 which receives the averaged voltage value from the low pass filter 72 and oscillates while adjusting the frequency around the reference regenerative synchronization clock set from the microcomputer 100. .

3 is a flow chart of a preferred embodiment of the high speed access method of the optical disk according to the present invention. Hereinafter, the high speed access method of FIG. 3 according to the present invention will be described in detail with the operation of the apparatus shown in FIG. 1 and FIG.

First, when the optical disc is inserted (S01) and initialized, the microcomputer 100 rotates the spindle motor 20 through the motor driving unit 10 to regenerate the optical disc at a constant rotational speed. Drive at speed (S10).

Accordingly, when the rotational speed of the spindle motor 20 reaches the normal rpm of the initial track (S11), the normal rpm is maintained by the servo unit 90, and the optical pickup 30 is at the current position. The high frequency signal recorded on the optical disk is detected while traveling along the track.

Meanwhile, the R / F unit 20 filters the high frequency signal detected by the optical pickup 30 and applies the phase synchronizing unit 70 to the phase synchronizing unit 70, and the phase synchronizing unit 70 supplies the R / F unit. The reproduction synchronization signal phase synchronized with the signal applied from 50 is generated and output according to the following procedure.

The phase comparator 71 in the phase synchronizer 70 compares the synchronization signal detected from the R / F unit 20 with the phase corrected regenerated synchronization clock and outputs a signal in a section corresponding to the phase difference. The signal output for each phase difference section is converted into a signal value corresponding to the averaged phase difference through the low pass filter 72 and then applied to the voltage controlled oscillator 73. The voltage controlled oscillator 73 adjusts the frequency of the oscillation signal by the applied average phase difference based on the reference regenerative synchronization clock corresponding to the track set by the microcomputer 100.

The frequency controlled oscillation clock is divided by the frequency divider 74 to the frequency corresponding to the input RF clock and fed back to the phase comparator 71, thereby eliminating the phase difference section output from the phase comparator 71 The phase correction operation is repeatedly performed until the phase coincides with the phase of the synchronization signal detected and applied from the R / F unit 20.

The divided clock phase-matched to the RF reproduction signal by the above process is applied to the digital signal processing unit 60 (S12), and the digital signal processing unit 60 uses the input regeneration synchronous clock. The digital signal of the high frequency signal input from the / F unit 20 is detected, and whether the appropriate number of synchronization signals (Sync) are detected within a predetermined time in the data recording unit, and the GFS (Good Frame Sync) signal is output to the microcomputer 100. From this, the microcomputer 100 causes the digital signal processing unit 60 to restore the input high frequency signal to the original digital data by the applied phase corrected reproduction synchronization clock. (S13).

During such playback, the microcomputer 100 determines that the current playback area is defective when the level of the high frequency signal input from the R / F unit 50 is out of an appropriate level for a predetermined period or more (S20). In operation S21, the motor driving unit 10 lowers the normal rpm, which is the normal rotational speed, to about 4000 rpm. Accordingly, the microcomputer 100 applies a reference regenerative synchronization clock corresponding to the reset rotational speed (4000 rpm) in the corresponding track to the voltage controlled oscillator 73, based on the applied reference regenerative synchronization clock. The phase synchronizer 70 outputs the phase-locked reproduction clock to the reproduction RF signal in the same manner as described above (S22), whereby the digital signal processing unit 60 passes the GFS signal output process to output the data of the recording signal. Restoration output is made (S23).

If the optical pickup 30 is requested to move and reproduce another track at a discontinuous position from the track at which the optical pickup 30 is currently located during the slowed down playback due to the fouling of the optical disc (long jump) (S30), the microcomputer ( 100 drives the sled motor 40 through the motor driving unit 10 to horizontally move the optical pickup 30 to a desired target track, and at the same time, the disk information extracted when the optical disk is inserted. The sled motor 40 calculates the travel time (t ₁ of FIG. 4) that the sled motor 40 takes to move horizontally from the current track to the target track (S31).

Thereafter, the microcomputer 100 predicts a rotation speed change amount of the spindle motor 20 that may change during the calculated movement section, that is, the movement time (300 rpm in FIG. 4) (S32), and the optical pickup ( The rotation speed (4300 rpm) of the spindle motor 20 at the time point 30) reaches the target track is calculated (S33). Accordingly, the microcomputer 100 generates a reference reproduction synchronization clock corresponding to the predicted rotational speed (4300 rpm) (S34) and applies the phase synchronization unit 70 to the phase synchronization unit 70, thereby regenerating phase synchronization with the reproduction RF. By applying a synchronous clock to the digital signal processing unit 60 (S34), the GFS from the digital signal processing unit 60 in accordance with the above-described process before the rotational speed of the optical disk reaches the normal speed (5000 rpm) in the track. The signal is output, after which the original recording signal is restored to data (S35).

Since the rotational speed of the spindle motor 20 is increased even during the GFS signal detection and data restoration process, the microcomputer 100 adjusts the phase synchronizer to match the rotational speed detected by the rotational speed detection unit 10b. The reference reproduction synchronous clock applied to 70 is gradually changed.

Further, another embodiment of the optical disk fast access method according to the present invention will be described with reference to the apparatus of Figs. 1 and 2, in the above example, when the long jump in the damaged area, the sled While the motor 20 moves to the target track, the microcomputer 100 does not calculate the rotation speed change amount of the spindle motor 20 according to the movement track, and the optical pickup by the sled motor 20 does not calculate. Immediately after the predicted movement time (t _{1 in} FIG. 4) to the target track 30, the reference speed corresponding to the rotational speed of the spindle motor 20 detected by the rotational speed detection unit 10b and the moved track By applying the synchronous clock to the phase synchronizer 70, the GFS signal is output from the digital signal processor 60 before the rotation speed of the optical disk reaches the normal rotation speed as described above, and then the original recording data. Restored output It is.

The high-speed access method described so far is not only at the time of returning to the normal rotational speed by the movement from the fouling detection area to the other area (B in Fig. 5), but also at the track movement (A in Fig. 5) where the rotational speed is different during the movement between tracks. Of course, the same can be applied to.

The optical disk high speed access device and method according to the present invention constructed and configured as described above do not wait for the time required for adjusting the rotation speed necessary for detecting a recording signal during a long jump of an optical pickup in which the rotation speed of the optical disk is changed. It is a very useful invention that the recording signal can be detected before reaching the target rotational speed, so that the access speed can be increased during the inter-track movement reproduction of the optical disc.

Claims (3)

In the track movement method with a change in the rotational speed of an optical disk, A first step of predicting a rotational speed of the optical disk to be changed corresponding to the time required for approaching the track radial direction of the target track to be moved; Setting a reproduction synchronization clock frequency corresponding to the predicted rotation speed change; And And a third step of detecting a new signal at the time when the access is completed based on the set reproduction synchronization clock frequency. The method of claim 1, The track-to-track movement of the optical pickup in which the rotational speed is changed is a case of moving to another track after decelerating the rotational speed due to the defect detection of the optical disk. In a track moving device with a change in the rotational speed of an optical disc, Rotational speed calculating means for calculating a rotational speed of the optical disk to be changed corresponding to the time required for approaching the track radial direction of the target track to be moved; Clock generation means for generating a reproduction synchronous clock frequency corresponding to the calculated rotational speed change; And And signal detecting means for detecting a reproduction signal at the time when the access is completed based on the generated reproduction synchronization clock frequency.