KR0124153B1 - Signal generator of focus control apparatus - Google Patents

Abstract

When the comparing part(70) inputs a high level signal first, the control part(90) delivers the 1st control signal to the compensating signal generator(100) and outputs the 1st compensating signal that has the voltage value that matches the maximum value of the focus error signal(FE) which was outputted from the focus error signal generator(1) to the adder(110). The focus control signal(FEC) outputted from the adder(110) reaches the maximum value at the linearly increasing point, and gradually declines. Being influenced by the compensating signal generated from the compensating signal generator(100), inputs a focus error signal which has a wider dynamic range into the focus servo and performs the effective focus control.

Description

Focus control signal generator

1 is a block diagram of a conventional focus control signal generator.

FIG. 2 is a characteristic diagram illustrating a focus error signal generated by the focus control signal generator shown in FIG.

3 is a schematic diagram showing the configuration of a light receiving unit employed in the focus control signal generator according to the present invention.

4 is a diagram showing a specific circuit block of the focus control signal generator according to the present invention.

5 is a characteristic diagram of a focus control signal output from the focus control signal generator according to the present invention.

* Explanation of symbols for main parts of the drawings

10: light receiving part (quadrant photodiode) 20,30,50,60: current-voltage conversion amplifier

40: focus error amplifier 70, 80: comparison unit

90: control unit 100: compensation signal generating unit

110: addition unit A to D, P, Q: photodiode

The present invention relates to an apparatus for generating a focus control signal, and more particularly, to an optical recording / reproducing apparatus for optically recording and reproducing data on a recording medium to control the degree of focus error of an optical pickup on a data recording surface of the recording medium. A focus control signal generator for generating a focus control signal for the same.

In general, an optical pickup objective lens used in an optical recording / reproducing apparatus for reproducing data recorded on a recording medium such as an optical disc or recording data on the recording medium generally has a depth of focus of about ± 1 μm. Because of this, it is difficult to accurately focus the light beam generated in the optical pickup on the reflective surface of the recording medium. Also, even when the reflective surface of the recording medium is accurately focused, the distance between the recording medium and the optical pickup is continuously changed due to the bending or eccentricity of the recording medium.

Therefore, in the optical pickup, the coil is wound around the objective lens placed in the magnetic field and the objective lens is moved in the optical axis direction by the focus servo signal to adjust the position of the objective lens so that the reflective surface of the recording medium is within the depth of focus. Done.

Such a conventional focus control signal generating apparatus includes a light receiving portion 10 made of, for example, a four-divided photodiode which receives light reflected from a reflecting surface of an optical recording medium and converts the amount of received light into an amount of current as shown in FIG. Current-voltage conversion amplifiers 20 and 30 for converting the added current amounts of the two photodiodes A and C; B and D, respectively, in the diagonal direction among the four-split photodiodes A to D into voltages, and the currents. And a focus error amplifier 40 which differentially amplifies each output voltage from the voltage conversion amplifiers 20,30.

The focus error signal, which is an output signal of the focus control signal generator, increases in the negative direction (or positive direction) when the focus of the optical pickup moves away from (or close to) the reflective surface of the recording medium, as shown in FIG. At some point, since the light beams incident on the recording medium are scattered around and do not return to the light receiving portion, they become zero (i.e., area ⓐ and ⓑ in FIG. 2). As described above, at the point where the focus error signal becomes zero (Area ⓐ and ⓑ), it becomes difficult to perform the function of the focus servo, so that data cannot be accurately read from the recording medium.

Accordingly, the present invention has been made in view of the above circumstances, and has a wider dynamic range for controlling the degree of focus error of an optical pickup in an optical recording / reproducing apparatus optically recording data to or reproducing data from the recording medium. An object of the present invention is to provide a focus control signal generator for generating a focus control signal having a dynamic range.

According to a preferred embodiment of the focus control signal generator according to the present invention for achieving the above object, a focus error signal generator for receiving the light reflected from the reflective surface of the recording medium through the light receiver to generate a focus error signal An optical recording and reproducing apparatus for optically recording and / or playing back on a recording medium; A current-voltage conversion amplifier unit for installing a light receiving element that detects the reflected light as a focus error at both corners of one side of the light receiving unit, and converting a current output corresponding to the received amount of the light receiving element into voltage; A comparison unit which compares each output voltage from the voltage conversion amplifier with a predetermined set voltage and outputs the comparison result signal at a binary level of a high level and a low level, and according to the comparison result signal inputted from the comparison unit. A controller for generating first and second control signals for focus compensation on a recording medium, a compensation signal generator for outputting first and second focus compensation signals according to a control signal from the controller, and the focus error signal generator And an adder for adding the output of the compensation signal generator.

Preferably, one of the light receiving elements is provided so that the light receiving amount first increases when the objective lens is too close to the recording medium, and the other light receiving element is first increased when the objective lens is too far from the recording medium.

The controller may apply a first control signal to the compensation signal generator so that the compensation signal generator outputs a first compensation signal when a high level is first applied from one of the comparison units. When a high level is first applied to the first signal, the second control signal is applied to the compensation signal generator to output the second compensation signal.

The first compensation signal is a voltage value corresponding to the maximum value of the focus error signal output from the focus control signal generator, and the second compensation signal corresponds to the minimum value of the focus error signal output from the focus error signal generator. It is set to the voltage value.

According to the present invention configured as described above, one light receiving element is provided in each corner portion of one side of the light receiving unit for focus error signal detection so that the two light receiving elements when the objective lens of the optical pickup is too close to the recording medium. In one of the light-receiving amounts increases first, if the objective lens of the optical pickup is too far from the recording medium, the light-receiving amount increases first in the other, so that the focus error signal is nonlinear based on the light-receiving amount of the light receiving element. If a region where the target lens appears to become zero (i.e., the region in which the objective lens is located too far or too close to the recording medium) is detected and superimposed, for example, ± V _{FE (MAX)} as the compensation signal on the detection region, A focus error signal having a wider dynamic range can be obtained.

Hereinafter, a focus control signal generator according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a schematic diagram showing the configuration of a light receiving unit employed in the focus control signal generator according to the present invention. In the figure, reference numeral 10 denotes a light receiving unit for detecting the focus error signal shown in FIG. 1, and comprises a quadrature photodiode that receives a light beam reflected from a reflecting surface of the optical recording medium and converts the received light amount into an amount of current. Further, in the present invention, the light receiving elements 10P and 10Q are respectively provided at both corners of one side of the light receiving unit 10, wherein the light receiving element 10P is provided when the objective lens of the optical pickup is close to the recording medium ( That is, when the focus of the light beam is close to the recording medium, the light receiving amount increases before the light receiving element 10Q, while the light receiving element 10Q has the optical pickup when the objective lens of the optical pickup is far from the recording medium (ie, the focus of the light beam). Away from the recording medium), the light receiving amount is increased before the light receiving element 10P.

FIG. 4 is a block diagram illustrating the focus control signal generating apparatus according to the present invention, in which the same reference numerals are attached to the same parts as those of FIG. 1, and detailed description thereof will be omitted.

In the figure, reference numerals A to D are light receiving elements of the light receiving portion 10 shown in FIG. 3, and P and Q are light receiving elements provided on one side edge portion of the light receiving portion 10. As shown in FIG. Reference numeral 50 denotes a current-voltage conversion amplifier for converting a current output corresponding to the amount of light received by the light receiving element P into a voltage, and 70 denotes a predetermined output voltage from the current-voltage conversion amplifier 50. The comparison unit outputs a low level, for example, and a high level, for example, when it is small compared with the set voltage. Reference numeral 60 denotes a current-voltage conversion amplifier for converting a current output corresponding to the light reception amount of the light receiving element Q into a voltage, and 80 denotes each output voltage from the current-voltage conversion amplifier 60. The comparison unit outputs, for example, a low level when it is small compared to a predetermined set voltage, and outputs a high level when it is large, for example.

Reference numeral 90 denotes a focus error signal output from the focus error signal generator 1 according to, for example, binary level values of high level and low level as comparison result signals input from the comparators 70 and 80. voltage value corresponding to the maximum value of the FE) (V _{FE (mAX)),} the first compensation signal and the voltage value corresponding to the minimum value of the focus, the focus error signal outputted from the error signal generation unit (1) having a (-V _FE And a control unit for outputting the first and second control signals such that the second compensation signal having _(MAX) is superimposed, and reference numeral 100 denotes the focus error signal generation unit in response to the first control signal from the control unit 90. The focus in response to a first compensation signal having a voltage value V _{FE (MAX)} corresponding to a maximum value of the focus error signal FE output from (1) and a second control signal from the controller 90. Minimum value of the focus error signal output from the error signal generator 1 As the compensation signal generation unit for outputting a second compensation signal having the voltage value (-V _{FE (MAX))} which, the compensation signal generating unit 100 is for example preferably is beforehand stored in the first and second compensation signal It consists of a semiconductor memory.

Here, the controller 90 applies a first control signal to the compensation signal generator 100 when a high level is first applied from one of the comparators 70 and 80 to correspond to the first control signal. While outputting a first compensation signal (that is, a voltage value (V _{FE (MAX)} ), if a high level is first applied from the other of the comparators 70, 80, the compensation signal generator 100 The compensation signal generator 100 controls the second compensation signal to output the second compensation signal -V _{FE (MAX)} by applying a second control signal.

Reference numeral 110 denotes a focus error signal FE from the focus error signal generator 1 and a compensation signal FC from the compensation signal generator 100; Is an adder that adds ± V _{FE (MAX} ) to output the focus control signal FEC.

Next, the operation of the focus control signal generator according to the present invention having the above-described configuration will be described.

First, when the objective lens of the optical pickup approaches the recording medium, the light receiving amount of the light receiving elements A and C of the light receiving unit 10 becomes larger than the light receiving amount of the light receiving elements B and D, and thus the focus error signal. (FE) increases linearly as shown in FIG. 5 and reaches a maximum value V _{FE (MAX)} at some point, and from that point on, the light beam starts to receive light beams. Thereafter, when the objective lens of the optical pickup is closer to the recording medium side, the light beam incident on the light receiving unit 10 side is scattered, so that the amount of light received at the light receiving element P side rather than the light receiving element Q side is increased significantly. In this case, when the light receiving element P is converted into a current amount and converted into a voltage in the current-voltage conversion amplifier 50, and the converted voltage signal is input to the comparator 70, the comparator 70 is input. When the voltage signal is greater than the reference value, the control unit 90 outputs a high level signal.

As described above, when the high level signal is first input from the comparator 70, the controller 90 applies the first control signal to the compensation signal generator 100 and outputs the signal from the focus error signal generator 1. The first compensation signal having the voltage value V _{FE (MAX)} corresponding to the maximum value of the focus error signal FE is output to the adder 110. Therefore, the focus control signal FEC, which is the output of the adder 110, increases linearly as shown in FIG. 5, and gradually decreases after reaching a maximum value V _{FE (MAX)} at some point (at this time). Up to the same as the waveform of the focus error signal). After that, it is influenced by [V _{FE (MAX)} ], which is a compensation signal generated by the compensation signal generator 100. Therefore, inputting the focus control signal having such a wider dynamic range to the focus servo enables more efficient focus control.

If the light receiving element P is moved in the direction of arrow (1) as shown by the dotted line in FIG. 3, the focus control signal FEC is also moved in the direction of the arrow (1) as shown by the dotted line in FIG. It appears to overlap as much as stationary (a). Preferably, the predetermined value (a) is set to 1/2 of [V _{FE (MAX)} ]. Therefore, in this case, since the area where the focus error signal becomes zero is eliminated, much more efficient focus control can be performed.

On the other hand, when the objective lens is far from the recording medium, the light receiving amount of the light receiving elements B and D of the light receiving unit 10 becomes larger than the light receiving amount of the light receiving elements A and C, so that the focus error signal FE is shown in FIG. As shown, it decreases linearly and reaches a minimum value (-V _{FE (MAX))} at which point the light beam starts to be received on the light-receiving element Q side. Thereafter, when the objective lens is further away from the recording medium, the beam incident on the light receiving portion 10 side is scattered, so that the amount of light received on the light receiving element Q side rather than the light receiving element P side is increased significantly. In this case, the amount of light received by the light receiving element Q is converted into an amount of current and converted into a voltage by the current-voltage conversion amplifier 60, and when the changed voltage signal is input to the comparator 80, the comparator 80 is input. When the voltage signal is larger than the reference value, the control unit 90 outputs a high level signal. When a high level signal is first input from the comparator 80, the controller 90 applies a second control signal to the compensation signal generator 100 to output a focus error from the focus error signal generator 1. The second compensation signal having the voltage value [-V _{FE (MAX)} ] corresponding to the minimum value of the signal FE is outputted to the adder 110. Therefore, the focus control signal FEC, which is the output of the adder 110, decreases linearly as shown in FIG. 5, and gradually increases after reaching a minimum value (-V _{FE (MAX)} ) at this point (at this time). Up to the same as the waveform of the focus error signal), and after that, the compensation signal generator 100 is affected by the compensation signal [-V _{FE (MAX)} ]. Therefore, inputting the focus control signal having such a wider dynamic range into the focus servo enables more efficient focus control.

If the light receiving element 10Q is moved in the direction of arrow (1) as shown by the dotted line in FIG. 3, the focus control signal FEC is also moved in the direction of the arrow (1) as shown by the dotted line in FIG. The overlapping state is shown by stationary (a). Here, the predetermined value (a) is preferably set to 1/2 of [-V _{FE (MAX)} ]. Even in this case, since the area where the focus error signal becomes zero is eliminated, much more efficient focus control can be performed.

According to the focus control signal generator according to the present invention as described above, one light receiving element (10P, 10Q) in each corner portion of one side of the light receiving portion 10 for the focus error signal detection to install the light receiving element ( Based on the received light amount of 10P, 10Q, the focus error signal appears nonlinearly and eventually becomes zero (i.e., a position area where the objective lens is too far or too close to the recording medium) and is used as a compensation signal in the detection area. By superimposing [± V _{FE (MAX)} ] on the focus error signal, it is possible to perform focus control having a wider dynamic range.

Claims (4)

Optical recording and reproducing apparatus optically recording and / or reproducing on a recording medium, comprising a focus error signal generator (1) for receiving the light reflected from the reflective surface of the recording medium through the light receiving unit (10) to generate a focus error signal. To; Light receiving elements 10P and 10Q for detecting the reflected light as focus errors are provided at both corners of one side of the light receiving unit 10, and current outputs corresponding to the light receiving amounts of the light receiving elements 10P and 10Q are respectively applied. The output voltages of the current-voltage conversion amplifiers 50 and 60 and the output voltages from the current-voltage conversion amplifiers 50 and 60 are compared with a predetermined set voltage, respectively, and the comparison result signals are converted into high and low levels. A first and second control signals for focus compensation on the recording medium according to the comparison unit 70 and 80 outputting the binary level of the level and the comparison result signal input from the comparison unit 70 and 80. The control unit 90, the compensation signal generator 100 for outputting the first and second focus compensation signal according to the control signal from the control unit 90, the focus error signal generator 1 and the compensation signal generation It includes an adder 110 for adding the output of the unit 100 A focus control signal generation device according to claim. 2. The light receiving device according to claim 1, wherein one of the light receiving elements (10P, 10Q) increases first when the objective lens is too close to the recording medium, and the other is when the objective lens is too far from the recording medium. A focus control signal generator, characterized in that the light receiving amount is installed to increase first. The method of claim 1, wherein the controller 90 generates a compensation signal by applying a first control signal to the compensation signal generator 100 when a high level is first applied from one of the comparators 70 and 80. When the unit 100 outputs the first compensation signal and a high level is first applied from the other of the comparators 70 and 80, the compensation signal generator 100 applies a second control signal to the compensation. Focus control signal generator, characterized in that the signal generator (100) outputs a second compensation signal. 4. The second compensation signal of claim 3, wherein the first compensation signal is a voltage value V _{FE (MAX)} corresponding to a maximum value of the focus error signal FE output from the focus error signal generator 1. And a compensation signal is a voltage value [-V _{FE (MAX)} ] corresponding to the minimum value of the focus error signal output from the focus error signal generator (1).