KR19990086964A - High speed control device and control method of optical disc - Google Patents

Abstract

According to the present invention, the elapsed time until the predetermined signal is detected from the optically loaded optical disk, or the elapsed time until the number of track crossing signals or the predetermined number of track crossing signals detected within the predetermined time are detected. High speed control device and control method of the optical disk to calculate the vibration amount of the optical disk to be inserted and initially rotated, and to adjust the rotational speed of the optical disk to a high speed of the initially set speed based on the calculated vibration amount of the optical disk The high speed control apparatus for an optical disk according to the present invention comprises: a pickup section (11) for reading a recording signal of the optical disk (10); A drive unit 30 for driving the motors 12a and 12b; An R / F unit 20 for filtering the signal detected by the pickup unit 11; A servo unit 40 for controlling driving of the drive unit 30 and detecting synchronization of an output signal of the R / F unit 20; A digital signal processor (50) for recovering the signal read by the R / F unit (20) to an original digital signal; A timer 70 for advancing the set time; And is configured to include a microcomputer 60 for variably controlling the rotational speed of the optical disk 10 based on the time advanced by the timer 70, the maximum speed (V _max on the optical disk as shown in FIG. 13 The starting point is advanced from R2 to R1, thereby increasing the area where the recording signal reading speed on the optical disc is substantially improved, thereby making the most of the advantage of the high speed.

Description

High speed control device and control method of optical disc

The present invention relates to a high speed control apparatus and a control method of an optical disk, and more particularly, to the elapsed time until a predetermined signal is detected from an initially loaded optical disk, or the number of track crossing signals detected within a predetermined time, or From the elapsed time until the predetermined number of track crossing signals are detected, the vibration amount of the optical disk which is initially inserted and rotated is calculated, and the rotation speed of the optical disk is initially set based on the calculated vibration amount of the optical disk. The present invention relates to a high speed control apparatus and a control method of an optical disc to adjust at a high speed of speed.

In the conventional optical disk rotational speed control, the initial rotational speed (ω) of the optical disk is shown in the graph of Fig. 1 in order to ensure the reliability of data reproduction according to the type (surface vibration and eccentricity) of the optical disk. It was fixed at a double speed (ω ₀ ) set lower than the maximum allowable double speed (ω _max ), whereby the optical disc was rotated to reproduce data.

By the way, an optical disc such as a CD-ROM title has a small amount of recorded data so that it does not exceed about two-thirds of the maximum recording amount. When the optical disc is rotated by the conventional method described above, the optical disc The maximum linear velocity V _max is reached late, so that the point R2 at which the maximum linear velocity is reached becomes far from the innermost circumference, the starting point of data reproduction, as shown in FIG. An optical disk medium having a small amount of data may have a case where a section to be reproduced at the maximum speed is considerably short or no, which does not provide the advantage of substantially high speed data reproduction.

Accordingly, an object of the present invention is to provide a high speed control apparatus and a control method of an optical disc, which are designed to solve the above problems and to advance the high speed point of an inserted optical disc.

Fig. 1 shows the relationship between the optical disk radius R and the rotational speed at the point according to the conventional optical disk driving method.

FIG. 2 exemplarily shows the total data recording section when the type of optical disc is CD-ROM;

Figure 3 shows a part of the configuration of the optical disk reproducing apparatus to which the high speed control apparatus for the optical disk according to the present invention is applied,

4 is a flowchart of a preferred embodiment of the high speed control method of the optical disk according to the present invention;

Fig. 5 shows the form of a frame which is a basic unit of data recorded on an optical disc,

FIG. 6 shows an example of a GFS signal detection time (GFS Time) according to the rotational speed of an optical disc.

7 is a diagram illustrating the shape of a traverse signal over time;

8 is a flowchart of another embodiment of a high speed control method of an optical disk according to the present invention;

Fig. 9 shows the structure of an optical disc reproducing apparatus to which another embodiment of the high speed control apparatus for optical discs according to the present invention is applied.

10 is a flowchart of another embodiment of a high speed control method of an optical disk according to the present invention;

11 illustrates a form of the traverse signal generated according to the vibration amount, for example.

12 is a flowchart of still another embodiment of a high speed control method of an optical disk according to the present invention;

Fig. 13 shows the relationship between the radius R of the optical disk according to the present invention and the rotational speed at that point.

※ Explanation of code for main part of drawing

10 optical disc 11 pick-up part

12a: sled motor 12b: spindle motor

20: R / F part 21: traverse counter

30: drive part 40: servo part

50: digital signal processor 60: microcomputer

70: timer

An apparatus for controlling a high speed of an optical disc according to the present invention for achieving the above object includes: reading means for reading a recording signal on the optical disc at the time of initial driving of the optical disc; Confirmation means for confirming whether a read period of a minimum unit synchronization signal is within a predetermined range from the read signal; Time lapse means for advancing time according to the rotational drive of the optical disk; And control means for variably controlling the rotational speed of the preset optical disk on the basis of the advanced time when the reading means is checked within a predetermined range of the reading period.

In addition, the high speed control method of the optical disk according to the present invention, by detecting the time length from the initially loaded optical disk until a predetermined signal is detected, according to the detected time length, the amount of vibration of the optical disk Counting the number of traverse signals generated after the rotational speed of the optical disk reaches a predetermined speed, and variably controlling the preset rotational speed of the optical disk according to the calculated vibration amount. While measuring the elapsed time according to the elapsed time, the vibration amount of the optical disk is calculated from the measured elapsed time or the number of traverse signals, and the variable rotation speed of the predetermined optical disk in accordance with the calculated vibration amount It is characterized by.

In the high speed control apparatus and control method for an optical disk according to the present invention constituted and configured as described above, when the optical disk is first inserted and initially rotated, the reading means reads a recording signal on the optical disk, and the time lapse means The time advances as the optical disk rotates. At this time, the checking means continuously checks whether the reading period of the minimum unit synchronization signal is within a predetermined range from the reading signal, and when it is confirmed that the reading period is within a predetermined range, the control means is configured to pass the time elapsed means. After calculating the vibration amount of the rotating optical disk on the basis of the time proceeded in the variable control according to the maximum possible rotation speed accordingly.

Best Mode for Carrying Out the Invention Preferred embodiments of the high speed control apparatus and control method for an optical disk according to the present invention will be described in detail with reference to the accompanying drawings.

Fig. 3 shows a part of the configuration of an optical disk reproducing apparatus to which the high speed control device of the optical disk according to the present invention is applied, and includes a pickup section 11 for inputting a light source to the optical disk 10 to read out a recording signal; A sled motor 12a for moving the pick-up part 11 in the radial direction of the optical disk; A spindle motor 12b for rotating the optical disc 10; A drive unit 30 for driving the sled motor 12a and the spindle motor 12b; An R / F unit 20 for filtering the signal detected by the pickup unit 11; The driving of the drive unit 30 is controlled from the focus error (FE) and tracking error (TE) signals output from the pickup unit 11, and the rotational speed of the optical disc, and the R / F unit 20 A servo unit 40 for detecting synchronization of an output signal of the controller; A digital signal processor (50) for recovering a signal read by the R / F unit (20) to an original digital signal using the detected synchronization; A timer 70 for advancing the set time; And a microcomputer 60 that variably controls the rotational speed of the optical disk 10 based on the time advance by the timer 70 until the GFS signal is detected.

4 is a flow chart showing the flow of a preferred embodiment of the high speed control method of the optical disk according to the present invention. Hereinafter, the control method of FIG. 4 according to the present invention will be described in detail in parallel with the operation of the reproducing apparatus of FIG. do.

First, when the optical disc 10 is inserted (S10) and initialized, the microcomputer 60 drives the spindle motor 12b through the servo unit 40 and the drive unit 30, thereby providing the optical disc ( 10) is initially loaded. At this time, the microcomputer 60 applies an initial driving voltage to the spindle motor 12b so that the initial loading of the optical disk 10 is performed in a constant angular velocity (CAV) manner. (S11). In addition, the microcomputer 60 controls the pickup unit 11 to detect a recording signal while traveling along the track on the optical disc 10 from the current initial position, and controls the timer 70 to control the time from then on. To proceed (S12).

The R / F unit 20 filters the high frequency signal detected by the pickup unit 11, and the filtered signal is synchronized with the servo unit 40, and the digital signal processing unit detects synchronization. Reference numeral 50 restores the high frequency signal output from the R / F unit 20 to the original digital data by the synchronization detected by the servo unit 40.

The data to be restored as described above is configured in the form of a frame (Frame) which is the basic unit, one frame is composed of 588bit data as shown in Figure 5, the rotational speed of the optical disk 10 is When the predetermined speed is reached, the synchronization signal (24 bits) in the frame is detected at regular time intervals, and the digital signal processing unit 50 performs periodic detection of such synchronization signal within the predetermined time from the restored digital data. It is continuously checked whether eight are continuously detected (S13). As a result of confirming the digital signal processing unit 50, if eight synchronization signals are continuously detected within a predetermined time (S20), the digital signal processing unit 50 generates a Good Frame Sync (GFS) signal and generates the microcomputer 60. When the GFS signal is generated, the GFS signal is generated within a short time as the initial driving speed of the optical disk 10 is higher as shown in FIG. 6, and the GFS signal is generated according to the generation of the GFS signal. The microcomputer 60 stops the time progress operation by controlling the timer 70 (S21).

As shown in FIG. 7, the microcomputer 60 compares the time T ₁ progressed by the timer 70 with the reference time T ₀ at the time of no vibration, and calculates a difference value. (S22) The amount of vibration is calculated based on the calculated difference value (S23). Since the GFS detection time is delayed as the amount of vibration increases, the time (T ₁ ) and the preset reference time (T ₁ ) are advanced to the GFS detection time. The difference with ₀ ) is directly proportional to the vibration amount of the optical disk. Therefore, the microcomputer 60 is initially driven and rotated by the formula of n = k ₁ (T ₁ -T ₀ ), where n is the vibration amount and k ₁ is the proportional constant by experiment. When the vibration amount is calculated and the calculated vibration amount is less than the maximum allowable vibration amount, the microcomputer 60 is a driving voltage applied to the spindle motor 12b through the servo unit 40 and the drive unit 30. By varying up from the predetermined driving voltage (S24), the mounted optical disk is driven at the maximum driving voltage, that is, the maximum rotational speed, under the allowable vibration amount.

FIG. 8 is a flow chart showing another embodiment of a high speed control method for an optical disk according to the present invention, in which the control method of FIG. 8 is the same as the control method of FIG. 4 described above. Detecting the level value of the high-frequency signal from the high-frequency signal that is normalized and output from the / F unit 20 (S33), the microcomputer 60 determines the level value of the detected high-frequency signal itself. If the difference is greater than a predetermined value compared with the reference level set (S44) (S45), it is determined as a defect of the optical disk, and the microcomputer 60 determines the rotational speed of the optical disk 10. Without variable control, the preset rotational speed is maintained as it is (S46), which means that the time progressed by the timer 70 is not detected periodically due to the fouling area of the disk, and thus the synchronization signal is not periodically made. Since the output of the GFS signal is delayed until the next miracle detection, it is difficult to calculate the exact amount of vibration by the above-described equation, so that the rotational speed of the optical disk 10 is not variably controlled in consideration of this. .

However, when the difference between the detected high-frequency signal level value and the reference level value does not occur more than a predetermined value, the microcomputer 60 performs the optical disc according to the calculated vibration amount as described above. The rotation speed of the variable 10 is adjusted (S47).

Fig. 9 shows the structure of an optical disc reproducing apparatus to which another embodiment of the high speed control apparatus for an optical disc according to the present invention is applied. In the structure of Fig. 3 described above, the filter is formed by the R / F unit 20. And a traverse counter 21 for detecting a traverse signal from the high frequency reproduction signal and counting the number of traverse signals. The microcomputer 60 has a reference value and a predetermined number of traverse numbers detected within a predetermined time. The running time until the traverse is detected is set as a reference value by itself.

FIG. 10 is a flow chart showing another embodiment of the high speed control method of the optical disk according to the present invention. Hereinafter, the control method of FIG. 10 according to the present invention will be described in detail with the operation of the playback apparatus of FIG. do.

In the high speed control method of the optical disk according to the present invention of FIG. 9 made from the configuration of FIG. 9, when the optical disk 10 is first inserted and initialized (S50), as described above, the microcomputer 60 is the optical disk. Initially driving 10 in a CAV method (S51), the pickup unit 11 is controlled to detect a recording signal while traveling along the track on the optical disc 10 from the current initial position.

Subsequently, the traverse counter 21 is detected from the recording medium 10 and counts the traverse signal from the high frequency reproduction signal normalized by the R / F unit 20 (S52). Is a signal generated as shown in FIG. 11 when the pickup 11 traverses a mirror surface existing between the track and the track. After the rotational speed of the optical disc 10 reaches a predetermined speed, That is, after the GFS signal generated from the digital signal processor 50 is recognized by the microcomputer 60, the number of the number is counted by the traverse counter 21 under the control of the microcomputer 60.

Therefore, when the optical disc 10 reaches a predetermined speed, the traverse counter 21 continuously counts the number of detected traverse signals, and the timer 70 then starts the traverse counter 21. Time progresses according to the count operation of (S53), and the microcomputer 60 continuously checks whether or not the time and the time (T _{c in} Fig. 11) is set to be the same self (S60). When both times are the same as the comparison result of the microcomputer 60, the microcomputer 60 controls the timer 70 to stop the time progress operation, and the traverse counted by the traverse counter 21 during that time. The number of signals is compared with the reference value due to the lowest vibration that is set by itself (S61). The microcomputer 60 calculates the vibration amount according to the comparison result (S62), and the comparison result counts the reference value (for example, the coefficient by the traverse signal ① due to the lowest vibration of FIG. 11). If the value is 2) or less, the microcomputer 60 sees the vibration amount as 0, otherwise, the equation n = k ₂ (N-2) according to the number N of the counted traverse signals, where n Is the vibration amount, k ₂ is the proportional constant by experiment), and when the vibration amount is calculated as described above, the microcomputer 60 determines the spindle motor as described above based on the calculated vibration amount. Variable driving the driving voltage applied to the (12b) to be driven at the maximum speed (S63).

FIG. 12 is a flow chart showing the flow of still another embodiment of the method for controlling the high speed of the optical disk according to the present invention. Referring to FIG.

In the control method of FIG. 12, after the optical disk 10 is inserted (S70), the process of the timer 70 according to the count operation of the traverse signal is performed in the same manner as the method of FIG. 10 described above. In this case, the microcomputer 60 continuously compares the number of traverse signals counted by the traverse counter 21 with the reference value (for example, 2) that is set instead of the running time of the timer 70. If it is confirmed (S80), and if the comparison value is the same value, the timer 70 is controlled to stop the time progress operation at that moment, and then the time t progressed by the timer 70 itself It is compared with the set reference time T _c (S81).

As a result of the comparison, when the advanced time t is greater than the reference time T _c , the microcomputer 60 determines that the vibration amount is equal to or less than the minimum vibration amount and calculates the vibration amount as 0, and the reference time T _c ) If it is less than the vibration amount is calculated based on the time (t), wherein n =-k ₃ (tT _c ), where n is the vibration amount, k ₃ is the proportional constant by experiment The vibration amount is calculated, and for the traverse signal generated and output as shown in FIG. 11, T _a is substituted into the above equation in the case of ② and T _b in the case of ③, so that the corresponding vibration amount is calculated. It will be (S82). When the vibration amount is calculated as described above, the microcomputer 60 variably adjusts the driving voltage applied to the spindle motor 12b based on the calculated vibration amount (S83).

The high speed control apparatus and control method for an optical disk according to the present invention constituted as described above can calculate the vibration amount of the optical disk quickly and accurately at the time of initial driving, and use the same to control the rotation speed of the optical disk within the allowable vibration amount range. By upwardly adjusting, as shown in Fig. 13, the start point of the maximum speed (V _max ) on the optical disk is advanced from R2 to R1, thereby increasing the area where the recording signal reading speed on the optical disk is substantially improved. It is effective to make full use of the advantages of high speed.

Claims (9)

Calculating a vibration amount of the optical disk while the rotational speed of the initially loaded optical disk is accelerated and changed; And And a second step of variably controlling the rotational speed of the preset optical disk according to the calculated vibration amount. The method of claim 1, The first step, Detecting the length of time until a predetermined signal is detected from the initially loaded optical disc, The vibration amount of the optical disk is calculated according to the detected time length. The method of claim 2, And the predetermined signal is a signal generated when the detection period of the minimum unit synchronization signal falls within a predetermined range. The method of claim 1, The first step, Detecting a level change of the high frequency reproduction signal until a predetermined signal is detected from the initially loaded optical disk; And The method may further include detecting a length of time until the time when the predetermined signal is detected. The vibration amount of the optical disk is calculated according to the detected time length and the level change of the high frequency reproduction signal. The method of claim 4, wherein And the predetermined signal is a signal generated when the detection period of the minimum unit synchronization signal falls within a predetermined range. The method of claim 1, The first step, Detecting the amount of traverse signal generated after the rotational speed of the initially loaded optical disk reaches a predetermined speed, The vibration amount of the optical disc is calculated according to the detected traverse signal amount. The method of claim 6, The detected amount of traverse signal is the number of traverse signals generated within a predetermined time after the rotational speed of the initially loaded optical disk reaches a predetermined speed. Reading means for reading out a recording signal on the optical disk during initial operation of the optical disk; Confirmation means for confirming whether a read period of a minimum unit synchronization signal is within a predetermined range from the read signal; Time lapse means for advancing time according to the rotational drive of the optical disk; And And control means for variably controlling the rotational speed of the preset optical disk based on the advanced time when the reading means checks within a predetermined range of the reading period. The method of claim 8, It further comprises a level detecting means for detecting a level change of the high frequency reproduction signal from the read signal, And the control means determines whether to control the preset rotation speed of the optical disk on the basis of the advanced time and the detected level change.