KR100533749B1 - Equalization Control Device and Method of Optical Disc Player - Google Patents

Abstract

The present invention provides an apparatus and method for adjusting an equalization coefficient of an optical disc player, wherein the waveform equalization coefficient is selected / varied according to a detection state of an RF signal level read from the optical disc, thereby reading an RF signal according to a characteristic change of a high density optical disc or an optical pickup. An apparatus and method for adjusting an equalization coefficient of an optical disc player for automatically correcting an error, the method for adjusting an equalization coefficient of an optical disc player according to the present invention comprises the steps of: equalizing a waveform of an RF signal read out from the optical disc with a set equalizing coefficient: Detecting the maximum amplitude and the minimum amplitude of the equalized RF signal and calculating a ratio thereof; and three steps of selecting / variing the set equalization coefficient according to the calculated ratio, Detects the level of the RF signal read out according to the characteristics of the high density optical disc and the optical pickup, and according to the detection result, It is a very useful invention that a stable RF signal can be read and reproduced by processing / selecting and changing a waveform equalization coefficient for waveform equalization so that a level RF signal can be detected.

Description

Equalization Control Device and Method of Optical Disc Player

The present invention relates to an equalizing coefficient adjusting apparatus and method for an optical disc player, and more particularly, to select and change a waveform equalizing coefficient according to an RF signal level detection state read from an optical disc, thereby changing the characteristics of a high density optical disc or an optical pickup. The present invention relates to an apparatus and method for adjusting an equalization coefficient of an optical disc player for automatically correcting an RF signal reading error.

A typical optical disc player filters an optical pickup (P / U) 2 for reading out a signal recorded on the optical disc 1 and a signal read out by the optical pickup 2, as shown in FIG. An RF converter 3 for shaping and outputting a radio frequency (RF) signal, a waveform equalizer 4 for waveform equalization with a fixed equalization coefficient, and the equalized RF signal An A / D converter 5 for sampling a predetermined period and converting the digital signal into a digital signal, a signal processing unit (DSP) 6 for reproducing the A / D converted digital signal into video and audio signals, and the waveform equalization And a servo unit 7 for controlling the focusing and tracking operations of the optical pickup 2 in accordance with the RF signal.

The reproduction operation of a general optical disc player constructed as described above is performed by first receiving an optical pickup in a state in which the optical disc 1 is seated and inserted into a tray (not shown) provided in the optical disc player and rotated at a constant speed. 2) emits a laser diode (LD) provided in the optical pickup 2 so as to read a recording signal recorded on the recording surface of the optical disk 1, and emits a predetermined size on the recording surface of the optical disk 1; A light spot is formed, and the reflected light of the formed light spot is converted into an electrical signal using a photo detector (PD) provided in the optical pickup 2 again. The converted electrical signal is converted into an RF signal of a high frequency component by the RF converter 3. The converted RF signal is equalized by the waveform equalizer 4 to be output as an RF signal of a predetermined level suitable for signal processing, and the equalized RF signal is output by the A / D converter 5 at regular intervals. It is sampled and converted into a digital signal. The converted digital signal is processed by the digital signal processor 6 into a digital video and audio signal, while the RF signal is input to the servo unit 7, and the servo unit 7 receives the input RF signal. By controlling the focusing and tracking operation of the optical pickup 2 such that the value is equal to or greater than a predetermined value, the signal recorded on the recording surface of the optical disc 1 is read out as a predetermined level RF signal, and the reproduction signal is processed into a video and audio signal. will be.

On the other hand, the size of the light spot formed by the optical pickup 2 varies depending on the optical wavelength λ of the laser diode LD and the aperture ratio NA of the object lens OL. Equation 1 is used to calculate a light spot size (B spot) used to reproduce a typical CD-based optical disc.

B spot (CD) = 1.22 X λ / NA = 1.22 X 780 nm / 0.45 = 2.11 μm-equation (1)

1.22: Refraction Coefficient (Constant)

λ: wavelength (LD wavelength for CD = 780 nm)

NA: opening ratio (opening ratio for CD = 0.45)

The amount of reflected light suitable for the reproduction signal processing corresponds to about 84% of the total amount of the reflected light, and the formula for calculating the amount of reflected light (B energy) suitable for processing the reproduction signal on the general CD series optical disc is expressed by the following equation. Same as 2.

B energy (CD) = 0.82 X λ / NA = 0.82 X 780 nm / 0.45 = 1.42 μm-Equation (2)

0.82: reflection coefficient (constant)

λ: wavelength (LD wavelength for CD = 780 nm)

NA: opening ratio (opening ratio for CD = 0.45)

That is, the size of the light spot and the amount of reflected light for reproducing a typical CD-based optical disc are about 2.42 times the size of the minimum recording pit (3T = 0.87 μm) formed on the recording surface of the CD. The spot size (2.11 μm) and the reflected light amount (1.42 μm) corresponding to about 1.63 times are used.

On the other hand, in the case of a high-density optical disk, that is, a DVD, the calculation formula for the size B spot of the light spot formed by the optical pickup 2 is shown in Equation 3.

B spot (DVD) = 1.22 X λ / NA = 1.22 X 635 nm / 0.6 = 1.29 μm-Equation (3)

1.22: Refraction Coefficient (Constant)

λ: wavelength (LD wavelength for DVD = 635 nm)

NA: Opening ratio (opening ratio for DVD = 0.6)

The formula for calculating the reflected light amount B energy suitable for reproducing the optical disc of the DVD series is shown in Equation 4.

B energy (DVD) = 0.82 X λ / NA = 0.82 X 635 nm / 0.6 = 0.868 μm-Equation (4)

0.82: reflection coefficient (constant)

λ: wavelength (LD wavelength for DVD = 635 nm)

NA: Opening ratio (opening ratio for DVD = 0.6)

That is, the size of the optical spot and the amount of reflected light used for the reproduction of the DVD-based optical disc, which are high density optical discs, are approximately 3.22 times the size of the minimum recording pit (3T = 0.4 μm) formed on the recording surface of the DVD. The size of the corresponding light spot (1.29 μm) and the amount of reflected light (0.868 μm) corresponding to about 2.17 times are used.

Therefore, the minimum recording pit (3T = 0.4 μm) formed on the recording surface of the DVD is reduced by two times or more than the minimum recording pit (3T = 0.87 μm) formed on the recording surface of the general CD (CD), that is, the amount of reflected light In addition, the RF signal level read from the DVD is reduced than the RF signal level read from the optical disc of the CD series, and is affected by the interference between codes. There was a problem.

In particular, in the normal servo operation state as shown in FIG. 2, for example, in a state where there is no focus error, a normal RF signal is read as shown in FIG. 2A, but when a focus error occurs as shown in FIG. 2B, There was a problem that the abnormal RF signal is repeatedly read and normal reproduction signal processing is impossible.

Therefore, the present invention was created to solve the above problems, and by selecting / changing the waveform equalization coefficient according to the detection state of the RF signal level read from the optical disc, the RF signal of a predetermined level is read and reproduced. It is an object of the present invention to provide an apparatus and method for adjusting the equalization coefficient of an optical disc player to be processed.

An equalizing coefficient adjusting apparatus for an optical disc player according to the present invention for achieving the above object comprises: equalizing means for equalizing a waveform of an RF signal read out from the optical disc based on a set equalizing coefficient; Detecting means for detecting equalization characteristics of the equalized RF signal level, and control means for selectively varying the equalization coefficients according to the detected equalization characteristics. The equalization coefficient adjusting method includes the steps of: equalizing a waveform of an RF signal read out from an optical disc with a set equalization coefficient; Detecting a maximum amplitude and a minimum amplitude of the equalized RF signal and calculating a ratio thereof; And three steps of selecting / variing the set equalization coefficient according to the calculated ratio.

The equalization coefficient adjusting apparatus and method for an optical disc player according to the present invention, which is configured as described above, performs waveform equalization of an RF signal read out from the optical disc with an initializing equalization coefficient and separates the equalized RF signal based on the zero crossing point. Then, the maximum amplitude and the minimum amplitude of the separated RF signal are detected, and a ratio thereof is calculated, and the value of the equalization coefficient is selected / variable so that the calculated ratio is included in a predetermined range of ratio, thereby providing an optical disc and A correction operation for automatically correcting an RF signal reading error according to an inherent characteristic of the optical pickup is performed.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

3 shows an optical disc player according to the present invention, in which an optical pickup (P / U) 12 for reading out a signal recorded on the optical disc 11 and a signal read out by the optical pickup 12 are shown. An RF converter 13 for filtering a filter to output an RF signal, an A / D converter 14 for sampling the converted RF signal at a predetermined period and converting the converted RF signal into an RF signal of a digital component; A waveform equalizer 15 for waveform equalizing the / D converted RF signal to an arbitrary equalization coefficient, and an equalization coefficient generator 21 for generating / outputting equalization coefficients C0, C1..Cn of different values; And a mux 22 for selectively outputting the equalization coefficients of the different values, a signal processor 16 for reproducing the equalized RF signal into video and audio signals, and the equalization. A servo unit 17 for controlling the focusing and tracking operation of the optical pickup 12 in response to the received RF signal and an equalization characteristic of the equalized RF signal An equalization characteristic detection unit 30 for detecting a signal, a micom 19 for controlling the selection / output operation of the mux 22 according to the equalization characteristic detection result, and varying / setting the waveform equalization coefficient; And an internal memory (not shown) that stores data necessary for the microcomputer operation.

4 illustrates a detailed configuration of the equalization characteristic detection unit 30 of the optical disc player according to the present invention, which divides / separates and outputs an RF signal equalized by the equalization coefficient based on the zero crossing point. A separator 31, a plurality of buffers 32 for temporarily storing the separated RF signal, and the temporarily stored RF signal are added to each other so that the maximum recording pit 11T and the minimum recording pit of the optical disc are added. A plurality of adders 33 for outputting an RF signal level value corresponding to (3T) and respective RF signal level values output from the adder to divide the maximum recording pit 11T and the minimum recording pit 3T. A divider 34 for calculating a ratio of RF signal level values corresponding to and a comparator 35 for comparing the ratio calculated by the divider 34 with a reference ratio (Vth, Vth2) in a predetermined range. It is configured by.

The operation description of the equalizing coefficient adjusting apparatus and method of the optical disk player according to the present invention configured as described above, first, the optical disk 11 is seated and inserted into a tray (not shown) provided in the optical disk player, In the state of constant rotation at the speed, the optical pickup 12 emits a laser diode (LD) provided in the optical pickup 12 to read out a recording signal recorded on the recording surface of the optical disc 11. A light spot of a predetermined size is formed on the recording surface of the optical disc 11, and the reflected light of the formed light spot is again used by using a photo detector (PD) provided in the optical pickup 12. Output converted to. The converted and output electrical signal is converted into an RF signal of a high frequency component by the RF converter 13, and the converted RF signal is sampled at a predetermined period by the A / D converter 14 and output as an RF signal of a digital component. do. The A / D converted RF signal is equalized to a waveform of a predetermined level by an arbitrary equalization coefficient initially set in the waveform equalizer 15 and output as an RF signal of a predetermined level suitable for signal processing. Meanwhile, the equalized RF signal is processed by the digital signal processor 16 into a digital video and audio signal, and the equalized RF signal is input to the servo unit 17. The servo unit 17 Controls the focusing and tracking operations of the optical pickup 12 such that the input RF signal is above a predetermined level.

On the other hand, the RF signal equalized by the variable waveform equalizer 15 is input to the equalization characteristic detection unit 30 configured as shown in Figure 4, the separator 31 of the equalization characteristic detection unit 30 is input The RF signal of the digital component, that is, the A / D conversion and the waveform equalized RF signal, is separated on the basis of the zero crossing (ZC: Zero Crossing) time point of changing polarity as shown in FIG. Is output to the buffer 32 (Buffers 1 to 4), while the signal input to the buffer 1 becomes the maximum value A of the positive RF signal level, and the signal input to the buffer 2 is negative. (Negative) becomes the maximum value (D) of the RF signal level, the signal input to the buffer 3 becomes the minimum value (E) of the positive (RF) signal level, the signal input to the buffer 4 is negative It becomes the minimum value B of the (Negative) RF signal level.

Thereafter, the RF signal level values A and D temporarily stored in the buffer 1 and the buffer 2, respectively, are summed up again by the adder 1 to an absolute value, and the level value of the RF signal corresponding to the maximum recording pit 11T of the optical disc. The RF signal level values (E, B), which are temporarily stored in the buffers 3 and 4, respectively, are added to the absolute value by the adder 2 to correspond to the minimum recording pit 3T of the optical disc. Is output.

The RF signal level values of the adder 1 and the adder 2 that are added and output as described above are divided by the divider 34 again, so that the RF signal RF _11T level corresponding to the maximum recording pit 11T of the optical disk is added. It is calculated as the ratio (Ratio = RF _{3T /} RF _11T ) of the value and the RF signal (RF _3T ) level value corresponding to the minimum recording pit (3T). The ratio is about 0.25.

On the other hand, the ratio Ratio calculated by the divider 34 is input to the comparator 35, and the reference value (ratio) of the comparator 35, for example, reference value 1 (Vth1 = 0.20) , Compared with the reference value 2 (Vth2 = 0.25), the comparator 35 outputs a comparison result as shown in FIG. 5B to the microcomputer 19. The micom 19 reads the RF signal according to the comparison result output from the comparator 35, that is, if the ratio Ratio calculated by the divider 34 is smaller than the reference value 1 (Vth1 = 0.20). The control signal Sel C-Up is outputted to the mux 22 to determine that the level of? Is small, and to select an equalization coefficient that increases the gain of the waveform equalizer 15. If the ratio Ratio calculated by the control unit is larger than the reference value 2 (Vth1 = 0.25), the control signal for determining that the level of the RF signal to be read is large to select an equalization coefficient for reducing the gain of the waveform equalizer 15 ( While outputting Sel C-Down to the mux 22, the ratio calculated by the divider 34 is greater than, for example, reference value 1 (e.g., Vth1 = 0.20), and the reference value. If less than 2 (e.g., Vth = 0.25), it is determined that the level of the RF signal to be read is appropriate, and the equalization coefficient of the waveform equalizer 14 is determined. Select / variable does not output a control signal to.

Accordingly, the mux 22 has an equalization coefficient C0, C1... Having a different value input from the equalization coefficient generator 21 according to the control signal Sel output from the microcomputer 19. One of the corresponding equalization coefficients of .Cn) is selected, and the RF output is varied by the selected equalization coefficient.

In this way, by varying the waveform equalization coefficient according to the equalization characteristic detected by the equalization characteristic detection unit 30, the RF signal reading error due to the characteristic change of the high density optical disc or the optical pickup is automatically corrected.

On the other hand, in another embodiment of the variable / setting of the equalization coefficient, the output of the divider 34 of the equalization characteristic detection unit 30 is directly input to the microcomputer 19, the microcomputer 19 is input to the divider The waveform equalization output is controlled by controlling the selection / output operation of the mux 22 such that the output of 34, i.e., an equalization coefficient inversely proportional to the calculated ratio Ratio is set in the waveform equalizer 15. In another embodiment, an RF signal corresponding to the maximum recording pit 11T may be used to detect equalization characteristics of the RF signal equalized by the waveform equalizer 15. Instead of calculating the ratio (Ratio = RF _{3T /} RF _11T ) between the (RF _11T ) level value and the RF signal (RF _3T ) level value corresponding to the minimum recording pit 3T, the RF corresponding to the maximum recording pit 11T. The RF signal RF _11T level value or the RF signal RF _3T level value corresponding to the minimum recording pit 3T is in a certain range of RF signals. The waveform equalization coefficient may be directly variable / set to be a call level value.

The apparatus and method for adjusting the equalization coefficient of the optical disc player according to the present invention as described above detects the level of the RF signal read out according to the characteristics of the high density optical disc and the optical pickup, and according to the detection result, By automatically selecting / variing the waveform equalization coefficient to be detected, it is a very useful invention for stable reading and RF signal processing.

1 shows a configuration of a general optical disc player,

2 shows the RF output of a typical optical disc player,

3 illustrates a configuration of an equalization coefficient adjusting apparatus for an optical disc player according to the present invention,

4 shows a detailed configuration diagram of the equalization characteristic detection unit according to the present invention,

Figure 5 shows a waveform diagram for RF level detection and control output according to the present invention.

※ Explanation of code for main part of drawing

11: optical disc 12: optical pickup (P / U)

13: RF converter 14: waveform equalizer

15: A / D converter 16: signal processing unit

17: Servo unit 19: Micom

21: Equalization coefficient generator 22: MUX

30: equalization characteristic detection unit

Claims (3)

Equalizing means for equalizing waveforms of the RF signal read out from the optical disc with a predetermined equalization coefficient; Detection means for detecting equalization characteristics of the equalized RF signal level; And A control means for varying the equalization coefficient according to the detected equalization characteristic, The detection means, Separating means for separating the equalized RF signal based on a zero crossing time point; Storage means for temporarily storing the separated RF signal; Calculating means for calculating a peak value between the stored RF signals and calculating a ratio between an RF signal corresponding to a maximum recording pit and a minimum recording pit of the optical disc; And And a comparison means for comparing the calculated ratio of the RF signal with a reference value. Performing waveform equalization with a predetermined equalization coefficient on the RF signal read from the optical disc; Detecting a maximum amplitude and a minimum amplitude of the equalized RF signal and calculating a ratio thereof; And And a three step of selecting / variing the set equalization coefficient according to the calculated ratio. The method of claim 2, The second step, A first sub step of adding a positive maximum value and a negative maximum value, a positive minimum value and a negative minimum value of the equalized RF signal, respectively; And And sub-dividing each of the added RF signals to calculate a ratio between recording pits corresponding to the corresponding RF signals.