KR19980079013A - Focusing Servo Device of DVD System - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a focusing servo device of a DVDR system. In the recording, erasing, and reproducing mode of a DVDR system, the amplification degree of the current-voltage change unit cannot be adjusted adaptively to a change in the amount of current detected, so that the focusing control operation is unstable. In order to solve the problem, the optical detector detects light reflected from the optical disk during recording, erasing, and reproducing operations of the DVDR system, and measures an error signal in the current generated. A focusing servo system of a DVDR system for driving and controlling an optical pickup to be positioned within a focal depth of a laser beam of an optical pickup, the current generated by the photodetector with an amplification degree corresponding to each of the recording, erasing, and reproducing modes. A pair of current-voltage converters capable of converting the voltage into a range of voltages and outputting the converted voltages; By providing a focusing servo device of the DVDR system, the microcomputer further comprises a microcomputer for controlling the amplification degree of the current-voltage converter in response to the amount of current detected by the photo detector, thereby improving the reliability of the DVDR system. have.

Description

Focusing Servo Device of DVD System

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a focusing servo device of a DVDR system (Digital Video Disc Rewriter System). In particular, a focusing servo device is provided by varying an amplification degree of a current-voltage converter corresponding to each mode of recording, erasing, and playback. A focusing servo device of a DVDR system that can be controlled more stably.

In general, optical discs are read-only type in which the user can only play the information according to its function and purpose, and additional recording type and repetitive recording of information that the user can record once and read the recorded information many times but cannot erase and re-record It can be divided into erasing rewritable type that can be erased and reproduced. Among such optical discs, a system capable of recording, erasing and playing on an erasable rewritable optical disc is commonly referred to as a DVDR system.

On the other hand, when recording, erasing, and reproducing certain data on such an erased rewritable optical disc, in order for the optical pickup unit of the DVDR system to accurately record, erase, and reproduce data on the optical disc, the signal surface of the optical disc is within the depth of focus of the laser beam of the optical pickup unit. Adjust to position The adjustment of the signal surface of such an optical disk to be located within a certain depth of focus of the laser beam of the optical pickup unit is commonly referred to as a focusing servo device.

A description will now be given of an operation process of a general focusing servo device, which is widely known.

FIG. 1 is a block diagram illustrating a focusing servo device according to the related art, and includes a photodetector 100, a current-voltage converter 200, an error detector 300, a difference compensator 400, and a driver 500. )

First, the photo detector 100 is composed of four photo diodes (D1, D2, D3, D4) divided into four, and is reflected from the optical disk through each photo diode (D1, D2, D3, D4). Light is detected and a current corresponding to the detected light is generated.

The two sets of current-voltage converters 200 are composed of two sets of OP amplifiers. The OP amplifier has a resistor R1 at its inverting input terminal as shown in FIG. 1, and the non-inverting input terminal is grounded. The feedback loop is provided with a loop resistor Rf from the output terminal to the inverting input terminal.

In the pair 210 of the current-voltage converter 200 configured as described above, the currents generated from the pair of diodes D1 and D3 positioned in the diagonal direction of the quadrant photodetector 100 are respectively added, The added current is converted into a constant voltage, and the converted voltage is provided to one input terminal of the error detector 300.

In addition, in another pair 220 of the current-voltage converter 200, the currents generated by the pair of diodes D2 and D4 positioned in the diagonal direction of the quadrant photodetector 100 are respectively added, The added current is converted into a constant voltage, and the converted voltage is provided to another input terminal of the error detector 300.

At this time, the voltage provided from the current-voltage converter 200 is output as a product of the loop resistance Rf with respect to the addition current I generated by the pair of diodes, and the phase is inverted. That is, the output voltage is output as -I * Rf.

The error detector 300 includes a differential amplifier having two input terminals and one output terminal.

When the voltages provided by the two sets of current-voltage converters 210 and 220 are respectively input to two input terminals of the error detector 300, the error detector 300 may input two inputs input by the current-voltage converters 210 and 220. Amplify the difference voltage between voltages. In this case, the generated voltage is a focusing error signal, and represents a degree in which a signal surface of the optical disk deviates from a predetermined depth of focus of the laser beam provided in the optical pickup unit.

The phase compensator 400 compensates for the phase of the focusing error signal generated by the error detector 300, amplifies the signal, and outputs the amplified signal as a drive control signal for driving the driver 500.

The driving unit 500 generates a driving signal for driving the focusing actuator coil by the driving control signal output from the phase compensator 400, and the focusing actuator coil is driven by the driving signal generated by the driving unit 500.

By driving the actuator coil, the objective lens (not shown) moves up and down, and by the movement of the objective lens, the signal surface of the optical disc is adjusted to be located within a certain depth of focus of the laser beam.

On the other hand, as described above, in the focusing servo device of the DVDR system according to the prior art, the current-voltage converter 200 is composed of a single loop resistor (Rf) in forming a feedback loop.

Therefore, the current-voltage converter 200 of the focusing servo device according to the prior art always has a constant amplification degree Rf / R1 by the single loop resistance Rf. At this time, the voltage Vo converted to the input current I is output as a value of -I * Rf.

However, as shown in Figs. 2 and 3, the respective laser powers generated in the laser beam during recording, reproducing, and erasing in the DVDR system are different, and the current generated through the photodetector is detected in the photodetector. Since it is proportional to the amount of light, the amount of current varies according to each mode.

Therefore, since the amplification degree of the focusing servo device in the DVDR system according to the prior art is constant in the recording, reproducing, and erasing modes, the focusing servo apparatus has a different current amount detected by the photodetector 100 in the recording, reproducing, and erasing modes of the DVDR system. Since it cannot be adaptively changed, there was a difficulty in performing stable focusing control.

Accordingly, the present invention has been made in view of the above-described problems, and an object of the present invention is to negatively return the current-voltage converter in response to the amount of current detected differently in the recording, erasing, and reproducing modes in the DVDR system. It is to provide a focusing servo device that can perform a more stable operation by adjusting the amplification degree.

In order to achieve the above object, the present invention measures an error signal in a current generated by detecting a light reflected from an optical disk during the recording, erasing, and reproducing operation of a DVDR system. A focusing servo device of a DVDR system for driving and controlling an optical pickup unit so that a signal surface of the optical pickup unit is located within a focal depth of a laser beam of the optical pickup unit, the focusing servo device of the DVDR system adjusting the amplification degree of negative feedback corresponding to each of the recording, erasing, and reproducing modes. A pair of current-voltage converters capable of converting and outputting a current generated by the photodetector into a constant voltage by means of an adjusted amplification degree; It is to provide a focusing servo device of the DVDR system further comprises a microcomputer for controlling the amplification degree of the current-voltage converter corresponding to the amount of current detected by the photo detector.

1 is a block diagram showing a focusing servo device according to the prior art;

FIG. 2 is a diagram showing respective amounts of current detected by an optical detector during recording, erasing and reproducing for explaining the present invention; FIG.

FIG. 3 is a waveform diagram showing waveform diagrams of respective currents detected by a photodetector during recording, erasing and reproducing for explaining the present invention; FIG.

4 is a circuit diagram showing a current-voltage converter according to an embodiment of the present invention;

5 is a circuit diagram illustrating a current-voltage converter according to another exemplary embodiment of the present invention.

<Description of the code | symbol about the principal part of drawing>

100: photodetector 200: current-voltage converter

300: error detection unit 400: phase compensation unit

500: driving unit 600: microcomputer

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

4 is a block diagram of a focusing servo of a DVDR according to an embodiment of the present invention, and FIG. 5 is a block diagram of a focusing servo of a DVDR according to another embodiment of the present invention.

First, an operation process of a focusing servo device of a DVDR system according to an exemplary embodiment of the present invention shown in FIG. 4 will be described.

When the current generated in the photodetector 100 is added to the input terminal of the two sets of current-voltage converters 210a and 220a, respectively, the added current is added to the variable amplification degree of the current-voltage converters 210a and 220a. Correspondingly, it is converted to a constant voltage. At this time, the amplification degree of the current-voltage converters 210a and 220a is changed by the control of the microcomputer 600.

Here, the current-voltage converter 200a can adjust the amplification degree by the following structure.

First, a feedback loop including a resistor R1 at an inverting input terminal, a non-inverting input terminal is grounded, and a plurality of resistors Rf0, Rf1, and Rf2 are connected in parallel from the output terminal to the inverting input terminal. At this time, the switches SW1 and SW2 are formed at one end of the resistors Rf1 and Rf2, respectively, and the switches SW1 and SW2 are shorted (On) or opened (Off) by the control of the microcomputer 600.

Here, by controlling the switches SW1 and SW2 formed in the negative feedback loop by the microcomputer 600, the amplification degree of the current-voltage converter 200a can be adjusted by varying the loop resistance of the negative feedback loop.

On the other hand, the amplification degree of the current-voltage converter 200a having the above-described structure is adjusted as follows by the control of the microcomputer 600 in the recording, erasing, and reproducing mode of the DVDR system.

First, when the DVDR system is in the recording mode, the amount of current input to the current-voltage converters 210a and 220a is the largest compared to the playback and erasing. Therefore, in the recording mode, it is desirable to reduce the amplification degree of the current-voltage converters 210a and 220a to the maximum. To this end, the microcomputer 600 controls so that both SW1 and SW2 provided in the current-voltage converters 210a and 220a are shorted (On).

Therefore, since the total resistance Rt applied to the negative feedback loop of the current-voltage converter 200a is a parallel sum of Rf0, Rf1, and Rf2, the resistance Rt is Rf1 * Rf2 + Rf0 * Rf2 + Rf0 * Rf1 / Rf0. * Rf1 * Rf2, and the amplification degree will be Rf0 * Rf1 * Rf2 / R1 * (Rf1 * Rf2 + Rf0 * Rf2 + Rf0 * Rf1). In addition, the voltage output from the current-voltage converter 200a may be -I * (Rf1 * Rf2 + Rf0 * Rf2 + Rf0 * Rf1) / Rf0 * Rf1 * Rf2 with respect to the input voltage I.

Next, when the DVDR system is in the playback mode, the amount of current input to the current-voltage converters 210a and 220a is the smallest compared to the recording and erasing. Therefore, in the regeneration mode, it is desirable to increase the amplification degree of the current-voltage converters 210a and 220a to the maximum. To this end, the microcomputer 600 controls so that both SW1 and SW2 provided in the current-voltage converters 210a and 220a are turned off.

Therefore, the total resistance (Rt) applied to the negative feedback loop of the current-voltage converter 200a will be Rf0, and the amplification degree at this time will be Rf0 / Rf1. In addition, the voltage output from the current-voltage converter 200a may be -I * Rf0 with respect to the input voltage I.

Finally, when the DVDR system is in the erase mode, the current-voltage converter (the detected amount of current is an intermediate value between the recording mode and the playback mode. Therefore, the amplification degree of the current-voltage converters 210a and 220a is determined by the recording mode and playback mode. For example, the microcomputer 600 controls only one of SW1 and SW2 of the current-voltage converters 210a and 210a to turn on.

Therefore, if SW1 is shorted, since the total resistance Rt applied to the negative feedback loop of the current-voltage converter 200a is the parallel sum of Rf0 and Rf1, the resistance Rt will be Rf0 * Rf1 / Rf0 + Rf1. The amplification degree at this time will be Rf0 * Rf1 / R1 * (Rf0 + Rf1). In addition, the voltage output from the current-voltage converter 200a may be -I * (Rf0 * Rf1) with respect to the input voltage I.

Meanwhile, FIG. 5 shows a current-voltage converter 200b according to another embodiment of the present invention. The current-voltage converter 200b of FIG. 5 may adjust the amplification degree by the following structure.

First, a feedback loop including a resistor R1 at an inverting input terminal of the OP amplifier, a non-inverting input terminal is grounded, and a plurality of resistors Rf0, Rf1, Rf2 are connected in series from the output terminal to the inverting input terminal. At this time, one end of each of the resistors Rf1 and Rf2 is formed in parallel with the switches SW1 and SW2, and the switches SW1 and SW2 are shorted (On) or open (Off) by the control of the microcomputer 600. do.

Here, by controlling the switches SW1 and SW2 formed in the negative feedback loop by the microcomputer 600, the amplification degree of the current-voltage converter 200b can be adjusted by varying the loop resistance of the negative feedback loop.

On the other hand, the amplification degree of the current-voltage converter 200b having the above-described structure is adjusted as follows by the control of the microcomputer 600 in the recording, erasing, and reproducing mode of the DVDR system.

When the DVDR system is in the recording mode, the amount of current input to the current-voltage converters 210b and 220b is largest compared to the playback and erasing. Therefore, in the recording mode, it is desirable to reduce the amplification degree of the current-voltage converters 210b and 220b to the maximum. To this end, the microcomputer 600 controls so that both SW1 and SW2 provided in the current-voltage converters 210b and 220b are open (Off).

Therefore, the total resistance (Rt) applied to the negative feedback loop of the current-voltage converter 200b will be Rf0, and the amplification degree at this time will be Rf0 / Rf1. In addition, the voltage output from the current-voltage converter 200b will be -I * Rf0 with respect to the input voltage I.

Next, when the DVDR system is in the playback mode, the amount of current input to the current-voltage converters 210b and 220b is the smallest as compared with recording and erasing. Therefore, in the regeneration mode, it is desirable to increase the amplification degree of the current-voltage converters 210b and 220b to the maximum. To this end, the microcomputer 600 controls so that both SW1 and SW2 provided in the current-voltage converters 210a and 220a are shorted (On).

Therefore, since the total resistance Rt applied to the negative feedback loop of the current-voltage converter 200b is the sum of Rf0, Rf1, and Rf2, the resistance Rt will be Rf0 + Rf1 + Rf2, and the amplification degree at this time is Will be (Rf0 + Rf1 + Rf2) / R1. In addition, the voltage output from the current-voltage converter 200b may be -I * (Rf0 + Rf1 + Rf2) with respect to the input voltage I.

Finally, when the DVDR system is in the erase mode, the current-voltage converter (the amount of current detected is an intermediate value between the recording mode and the playback mode. Therefore, the amplification degree of the current-voltage converter 210b 220b is set to the intermediate value between the recording mode and the playback mode. To this end, the microcomputer 600 controls only one of SW1 and SW2 provided in the current-voltage converters 210b and 210b to short-circuit (On).

Therefore, if SW2 is shorted, since the total resistance Rt applied to the negative feedback loop of the current-voltage converter 200b is the sum of Rf0 and Rf1, the resistance Rt will be Rf0 + Rf1, and the amplification degree at this time Will be (Rf0 * Rf1) / R1. In addition, the voltage output from the current-voltage converter 200b may be -I * (Rf0 + Rf1) with respect to the input voltage I.

Thereafter, when the focusing actuator coil is driven via the error detector 300, the phase compensator 400, and the driver 500, the objective lens (not shown) moves up and down by driving the actuator coil, By movement, the signal surface of the optical disc is adjusted to be located within a certain depth of focus of the laser beam.

As described above, in the present invention, a process of controlling the amplification degree of the current-voltage converter 200 using three loop resistors has been described. The present invention can be easily implemented by varying the number of.

As described above, according to the present invention, the DVDR system is more stably performed by adjusting the amplification degree of the current-voltage converter to more stably perform the focusing servo operation of the DVDR with respect to the amount of current generated during the recording, reproducing, and erasing of the DVDR system. There is an effect that can improve the reliability of.

Claims (3)

The DVDR system detects light reflected from the optical disk during recording, erasing, and reproducing operation on the optical disk, and measures an error signal at a current generated corresponding to the detected current. A focusing servo apparatus of a DVDR system for driving control of an optical pickup unit such that a signal plane is located within a focal depth of a laser beam of the optical pickup unit; Two sets of current-voltage converters capable of converting a current generated by the photodetector into a constant voltage and outputting the amplification degree corresponding to each of the recording, erasing and reproducing modes; And a microcomputer for adjusting the amplification degree of the current-voltage converter in response to the amount of current detected by the photodetector. The switching circuit of claim 1, wherein the current-voltage converter includes an input resistor at an inverting input terminal, a non-inverting input terminal is grounded, and is switched to a negative feedback loop including a loop resistance from an output to the inverting input terminal. Focusing servo unit of DVDR system, characterized in that the OP amplifier is connected in series with as many resistors as possible The switching circuit of claim 1, wherein the current-voltage converter includes an input resistor at an inverting input terminal, a non-inverting input terminal is grounded, and is switched to a negative feedback loop including a loop resistance from an output to the inverting input terminal. Focusing servo device of the DVDR system, characterized in that the OP amplifier is connected in parallel with as many resistors as possible.