KR100290959B1 - Device for compensating defect of optical disk drive and method thereof - Google Patents

Abstract

PURPOSE: A device for compensating a defect of an optical disk drive is provided to lower an amplification rate of a playback signal read from a disk during servo control, if a level of the playback signal is out of a preset stable level range, and to apply the amplification rate-lowered playback signal to a servo control loop. CONSTITUTION: A tracking signal amplifier(51) amplifies a TE(Tracking Error) signal from an applied playback signal. In a playback signal input terminal of the tracking signal amplifier(51), a resistor(R1) is supplied. A resistor(R2) is supplied between the playback signal input terminal and an output terminal of the tracking signal amplifier(51). A defect signal compensator(50) is configured in parallel with the tracking signal amplifier(51), and comprises a switch(53) and a resistor(R3). If a voltage level of an inputted signal is more than or less than firing voltages of a diode 1 and a diode 2(D2), the switch(53) passes the signal. If the voltage level of the signal is within the diode(D2), the switch(53) intercepts the signal.

Description

Defect Compensation Device and Method of Optical Disc Drive

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disc drive for recording data on or reproducing recorded data in an information recording disc such as an optical disc, and more particularly, to an apparatus and method for processing a defect of an optical disc.

In the optical recording and reproducing technique of recording and reproducing information on an optical disc (hereinafter referred to as a disc) by using a laser, information is read as an amount of change of laser beam reflected light with respect to the optical disc. The method of recording data on an optical disc by changing reflected light includes a method of forming a concave pit on a disc substrate to use interference between the pit and a reference plane, a method of changing the polarization direction of a magneto-optical recording medium such as a magneto-optical disc, and To use the difference in the amount of reflected light depending on the crystallizing state of the recording material, such as phase-change discs (CD-RW: CD-ReWritable), and to modify organic pigments, such as CD-R (CD-Recordable). And the like. Among them, a method capable of repeating recording and reproducing, especially a phase change type method, is widely applied to a compact disc (CD) or a digital video disc or a digital versatile disc (DVD).

In the optical disc drive, optical pick-up is used to read data recorded on the optical disc in the above-described manner, or to record data. In the process of reading the data recorded on the disc by the optical pickup, abnormal signals may be detected by the defect such as scratches on the disc, except for normal data reproduction signals. In the data reproducing loop, the error is corrected by an error correction code or the like, and the defect generated when the data related to the servo information is detected is compensated in the servo loop. Hereinafter, the compensation of the defect caused when the data related to the servo information is detected will be described with reference to the accompanying drawings.

FIG. 1 is a schematic block diagram of a related part of a tracking servo among the defect processing related parts of a general optical disk drive, and FIG. 2 is a waveform diagram of each input and output signal of FIG. It didn't work. FIG. 1 illustrates a tracking servo as an example of various servo loops included in an optical disk drive for convenience of description, and other servo loops have a similar defect processing configuration.

The optical pickup 10 first reads data from the disk and applies this data reproduction signal to a radio frequency amplifier (RF AMP) 39. The high frequency amplification unit 39 amplifies such a reproduction signal and applies it to a recording / reproducing data processing unit (not shown) for processing user data. Each of the servo loops (not shown) supplies signals related to various servos in the amplified reproduction signal. To apply. The tracking controller 25 controls the tracking servo, and receives a tracking error signal (TE) from the high frequency amplifier 39 and outputs a tracking output signal (TO) to the tracking coil.

In more detail, in general, an optical disc drive includes a plurality of servo circuits in a basic operation for reproducing data recorded on an optical disc. Such servos include a tracking servo, a focus servo, a rotation servo, and an optical transmission servo. There may be.

The tracking servo is a servo that allows the optical pickup 10 to follow a concentric or spiral track centerline, which is a data recording form of the optical disk, and the focus servo is a lens in which the focus of the laser beam of the optical pickup 10 coincides with the optical disk surface. Servo to maintain the distance between the optical disk and the surface of the optical disk. The rotation (normally CLV: Constant Linear Velocity) servo is a servo for controlling the speed at which the optical disk rotates at a constant speed (or right angle). Refers to a servo for the optical pickup 10 to slide on the optical disk surface to move to a desired track.

For example, the servo may be executed by using a focus error signal in the case of a focus servo and a tracking error (TE) signal in the case of a tracking servo. It is applied to the servo loop (in FIGS. 1 and 2, only the tracking servo is shown as an example for convenience of description). In this case, the tracking error signal TE as shown in FIG. 2 shows an abnormal waveform in the defect portion of the reproduction signal, and the tracking controller 25 performs the tracking servo according to the signal of the defect portion of the tracking error signal TE. In this case, serious errors such as track jumping may occur. Accordingly, when the high-definition amplifier 39 detects a defect, the high-definition amplifier 39 applies a DeFeCT detecting signal (DFCT) as shown in FIG. 2 to the tracking control unit 25, and the tracking control unit 25 enables the defect detection signal to be enabled ( In the enable period, the tracking error signal TE is held or the gain of the signal is lowered. Accordingly, the servo control signal for the tracking servo of the tracking control unit 25, that is, the tracking output signal (TO) as shown in FIG. 2, appears as a waveform based on the tracking error signal TE in the absence of a defect. In the enable period of the defect detection signal DFCT, the tracking error signal TE is held. Therefore, although the tracking control unit 25 cannot perform the tracking servo by the tracking error information originally recorded on the disc, the tracking control unit 25 can prevent the malfunction due to the defect.

However, the above-described decomp compensation method should include a signal hold circuit in a servo control unit such as a tracking control unit, and in the case of a large defect such as a scratch of a disc or a continuous hold, the hold timing becomes long, and accordingly control of the tracking servo is performed. Anxiety could cause malfunction such as track jumping. In addition, the signal level was also limited in reducing the gain of the signal during the period in which the defect detection signal was enabled in the servo control unit such as the tracking control unit.

Accordingly, an object of the present invention is to provide a defect compensation apparatus and method which can easily compensate for a defect on a disc in servo control of an optical disc drive.

Another object of the present invention is to provide a defect compensation device capable of compensating for a defect on a disc in servo control of an optical disc drive with a simple configuration.

It is another object of the present invention to provide a defect compensation apparatus and method that can easily compensate for a signal due to a large or continuous defect on a disc in servo control of an optical disc drive.

In order to achieve the above object, the present invention amplifies a playback signal read from a disk during servo control of an optical disk drive, and applies the playback signal for each servo control to the servo control loop for each servo control. Is a level outside the preset stable level range, the amplification factor of the amplification is reduced and applied to the servo control loop.

FIG. 1 is a schematic block diagram of a related part in a tracking servo among defect compensation related parts of a general optical disc drive.

2 is a waveform diagram of each input and output signal of FIG.

3 is a schematic overall block diagram of an optical disk drive to which the present invention is applied.

4 is a schematic block diagram of a related part of a tracking servo among defect compensation related parts of an optical disc drive according to an embodiment of the present invention.

5 is a waveform diagram of each input and output signal of FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, specific matters such as specific building blocks are shown, which are provided to help a more general understanding of the present invention, and the specific matters may be changed or changed within the scope of the present invention. It is self-evident to those of ordinary knowledge in Esau.

3 is a block diagram of an example of an optical disk drive to which the present invention is applied, and a drive capable of repeatedly recording and reproducing data is taken as an example. Referring to FIG. 3, the optical disc drive records information on the optical disc 1 by optical pickup 10, or reproduces the recorded information. The optical pickup 10 is supported by the linear motor 20 and is movable to the inside and the outside of the optical disc 1.

The optical pickup 10 includes a semiconductor laser oscillator 13, various lenses, a half prism 17, a tracking coil 11a, a focus coil 11b, and the like. When recording data, the laser oscillator 13 outputs a laser beam of the data recording level, and the laser beam is scanned to the position to record the optical disk 1 via the half prism 17 and the lens. When data is reproduced, the laser oscillator 13 outputs a laser beam of a data reproduction level, and the laser beam is reflected at the data reproduction position of the optical disc 1 and input to the photodetector 15 via the half prism 17. The laser oscillator 13 is controlled by the laser controller 21 to control the level of the output laser beam and the output on / off interval. The laser controller 21 controls the laser oscillator 13 in accordance with, for example, 2-7 modulation obtained by the modulator 22, and the modulator 22 controls the recording data applied by the error correction part 35 (to be described later) when data is recorded. A signal suitable for recording is converted into, for example, 2-7 modulated data. The laser control section 21 and the modulation section 22 operate in synchronization with a recording clock signal applied by the PLL 41 or the like in the recording / reproducing data processing section 40 (to be described later). The photodetector 15 generates an electrical reproduction signal according to the amount of light of the laser beam reflected from the optical disk 1 and applies the signal to the high frequency amplifier 31. The high frequency amplifier 31 amplifies the reproduced signal and focuses it on the focus control unit 23 and the tracking control unit 25. To the linear motor control unit 27, the spindle motor control unit 29, and the recording / reproducing data processing unit 40.

The focus controller 23 detects the degree of focus of the laser beam from the applied reproduction signal, and applies an operating power to the focus coil 11b to control the laser beam focus of the optical pickup 10 to adjust the focus normally. The tracking controller 25 detects a tracking error signal from the applied reproduction signal, applies an operating power to the tracking coil 11a for the normal tracking operation, and checks the rotational speed of the optical disc 1 from the reproduction signal. Apply the control signal accordingly. The linear motor controller 27 controls the linear motor 20 by detecting the moving speed of the optical pickup 10. On the other hand, a D / A (Digital to Analog) converter 33 is provided for exchanging information between the focus control unit 23, the tracking control unit 25, the linear motor control unit 27, and the central processing unit (CPU) 30 which controls the overall control of the optical disk device. The spindle motor controller 29 controls the spindle motor 3 to control the optical disk 1 to rotate at a constant linear velocity (CLV).

The recording / reproducing data processing unit 40 reproduces the recorded data by receiving the reproduction signal, applies the reproduced data to the error correction unit 35, or performs a process for recording the data. The error correction unit 35 corrects an error by referring to an ECC code or the like in the reproduction data, or adds the ECC code to the memory 31 to be recorded from the external device such as a host through the interface unit 37 and transmits it to the memory 31. The data transferred to the memory 31 is temporarily stored and sequentially applied to the modulator 22 to be recorded on the optical disc 1. The memory 31 also stores the overall operating program of the CPU 30. The CPU 30 controls the overall operation of the optical disk device, and in particular, controls to search or track the correct position for recording or reading information on the disk.

According to the present invention, when the optical disk drive amplifies the playback signal read out from the optical disk 1 and applies a playback signal for each servo control to the respective servo control units, the playback signal is at a level outside the preset stable level range. In this case, the amplification rate of the amplification is reduced and applied to each of the servo controllers, which will be described in more detail with reference to the accompanying drawings.

FIG. 4 is a schematic block diagram of a related part of a tracking servo among defect compensation related parts of an optical disk drive according to an embodiment of the present invention, and FIG. 5 is a waveform diagram of signals of each input and output of FIG. As shown in FIG. 4 and FIG. 5, the case where the present invention is applied to the tracking servo will be described as an example. When the reproduction signal is applied to the high frequency amplifier 31, it is applied to the tracking signal amplifier TEAMP 51 in the high frequency amplifier 31 as shown in FIG. The tracking signal amplifier 51 amplifies the tracking error signal TE in the applied reproduction signal.

A resistor R1 is provided at the reproduction signal input terminal of the tracking signal amplifier 51, and a resistor R2 is provided between the reproduction signal input terminal and the output terminal of the tracking signal amplifier 51. In this case, the amplification ratio of the reproduction signal is represented by the product of the amplification gain of the tracking signal amplifier 51 and R2 / R1. As described above, the reproduction signal was amplified by appropriately adjusting the amplification gain of the tracking signal amplifier 51 and the resistance values of the resistors R2 and R1. The above-mentioned amplification of the reproduction signal is amplified even if the abnormal reproduction signal of the defect portion, in the present invention is provided with a defect signal compensation unit 50 for adjusting the amplification ratio of the reproduction signal as shown in FIG. .

The defect signal compensator 50 is configured in parallel with the tracking signal amplifier 51, and is composed of a switching part 53 which performs a switching role according to the signal level, and a resistor R3. In one embodiment of the present invention, the switching unit 53 is composed of diodes D1 and D2 configured in parallel in opposite directions, so that the voltage level of the input signal is positive (+) and the diodes D1 and D2 are firing. When the voltage is above or below the voltage, the signal is passed. When the voltage level of the input signal is positive and negative within the starting voltage of the diodes D1 and D2, the input signal is cut off.

As the defect signal compensator 50 having the above configuration is configured in parallel with the tracking signal amplifier 51, the voltage level of the reproduction signal may be in the range of the starting voltage levels of the diodes D1 and D2 as shown in FIG. In this case, since the switching unit 53 performs an off operation, the amplification ratio of the reproduction signal is expressed as the product of the amplification gain of the tracking signal amplifier 51 and the product of R2 / R1 as in the conventional art. However, when the reproduction signal is at the abnormal voltage level due to the defect, that is, when the reproduction signal is outside the range of the start voltage levels of the diodes D1 and D2 as shown in FIG. 5, the switching unit 53 performs an on operation. The amplification ratio of is expressed as the product of the amplification gain of the tracking signal amplifier 51 and (R2 / R3) / R1. As a result, the playback signal of the defect portion is amplified with a smaller amplification ratio than that of the defect. In order to appropriately adjust the amplification ratio of the reproduction signal of the defective part, the resistance, in particular, the resistance value of the resistor R3 may be adjusted to set the optimum amplification ratio.

Defect compensation by the configuration and method as described above is compensated to some extent before the tracking error signal TE is applied to the tracking control unit 25, according to the design of the circuit can be decompensation only by the configuration of the defect signal compensation unit 50 according to the present invention In addition, the defect signal compensator 50 according to the present invention may be configured in addition to the conventional defect compensation loop.

Meanwhile, in one embodiment of the present invention described above, the present invention is implemented as a tracking servo, but the present invention can be implemented in a focus servo or the like.

As described above, according to the present invention, when the reproduction signal read out from the disk is amplified during the servo control of the optical disc drive and the reproduction signal for each servo control is applied to the servo control loop for each servo control, the reproduction signal is preset. If the level is outside the stable level range, the amplification ratio of the amplification is reduced and applied to the servo control loop. Therefore, the signal compensation for the defects on the disc can be easily and simply performed in the servo control of the optical disc drive. There is an advantage that it is easy to compensate the signal for the size of the phase or the successive defects.

Claims (6)

A method for compensating for the defect of the optical disc of the reproduction signal of the optical disc drive for amplifying a reproduction signal read out from the optical disc and applying a reproduction signal for each servo control to the servo control loop, the amplification of the reproduction signal for the servo control And applying the servo control loop to the servo control loop when the reproducing signal is at a level outside the preset level level, when applying the servo control loop for each servo control. The method of claim 1, wherein the servo is a tracking servo and a focus servo. A compensation device for defecting the optical disc of the reproduction signal of an optical disc drive, comprising an amplifier for amplifying a reproduction signal read out from the optical disc at a predetermined amplification ratio and applying a reproduction signal for each servo control to the servo control loop. In order to reduce the amplification ratio of the reproduction signal by the defect when amplifying the reproduction signal for control, the input, output and input and output terminals of the amplifier are connected together, and the voltage level of the input reproduction signal is inputted by the absolute value due to the defect. Defect compensation device characterized in that it comprises a switching unit which serves as a conduction when the level is a large level, and a defect signal compensation unit composed of a resistance of a predetermined resistance value. 4. The switching unit of claim 3, wherein the switching units are connected in parallel in opposite directions to each other, and an appropriate level among the levels between a portion having a large absolute value of the voltage level due to defect and a portion having a small absolute value of the voltage level which does not depend on the defect. Defect compensation device, characterized in that consisting of the first, second constant voltage element of a predetermined start voltage. The defect compensation device of claim 4, wherein the constant voltage device is a diode. 4. The method of claim 3, wherein the servo is a tracking servo and a focus servo.