KR100600086B1 - Optical Recording/Reproducing Apparatus and Method Thereof - Google Patents

Abstract

The present invention relates to an optical recording / reproducing apparatus and method for making it suitable for high density optical recording media.

According to the present invention, the main beam is irradiated to the target track and the subbeams are irradiated to adjacent tracks adjacent to the target track to convert the reflected light of the main beam and the subbeams into electrical signals, respectively, and the frequency characteristics of the subbeams correspond to different driving conditions. The filter coefficients calculated to be converted into frequency characteristics of the torque component are classified and stored in advance to convert the frequency characteristics of each of the reproduction signals of the sub-beams using the filter coefficients.

According to the present invention, the crosstalk component can be removed according to the driving condition by converting the frequency characteristic of the subbeam reproduction signal into the frequency characteristic of the crosstalk component included in the main beam reproduction signal according to different driving conditions.

Description

Optical Recording / Reproducing Apparatus and Method Thereof}

The present invention relates to an apparatus for optically recording / reproducing information on a recording medium, and more particularly, to an optical recording / reproducing apparatus and method adapted to be suitable for a high density optical recording medium.

Optical recording media have been developed and widely distributed following commercially available CDs, and their use is further increased for recording and reproducing audio and video data and computer data. Optical recording media are becoming denser, such as narrowing the track width and reducing the pit size. The optical recording / reproducing apparatus forms smaller optical spots corresponding to the high density structure of the optical recording medium to irradiate the optical spots on the information recording surface of the optical recording medium to record information or to reproduce the recorded information. On the other hand, since the size of the light spot is limited to be smaller than the value (diffraction limit) proportional to λ / NA depending on the wavelength λ of the light source and the numerical aperture NA of the objective lens, the optical recording / reproducing apparatus narrows the density of the high density optical recording medium. The oscillation wavelength λ of the light generated from the light source is reduced and the numerical aperture NA of the objective lens is increased to realize the micro light spot corresponding to the track pitch. On the other hand, if the width of the track is narrower than the diameter of the light spot, the light spot is condensed on the target track for recording / reproducing information (hereinafter referred to as the "target track"), and the track adjacent to the target track as well as the track (hereinafter " Since light is also irradiated to the adjacent tracks, the reflected light reflected from these tracks includes signals reflected from adjacent tracks in addition to the signal from the target track. Here, the signal components reflected from the adjacent tracks become noise components for the desired reproduction signal, and this phenomenon is called crosstalk, and the signal components from the adjacent tracks are called crosstalk components. In order to minimize such influence on crosstalk, the track density is limited by the effective diameter of the light spot so that light is not irradiated to adjacent tracks. As a method for removing crosstalk, a method of removing crosstalk by irradiating each of three beams to a target track and an adjacent track as described in Japanese Patent Laid-Open No. 4-698203 and the like is known. In the crosstalk removal method using the three beams, as shown in FIG. 1, three beams 11, 12, and 13 are generated, and the main beam 12 of the three beams 11, 12, and 13 is connected to the target track 22. The sub-beams 11 and 13 are irradiated to adjacent tracks 11 and 13 adjacent to both sides of the inner and outer circumferential sides of the target track 22. The light beams focused in the form of light spots on the target track 22 and adjacent tracks 21 and 23 on the optical recording medium are respectively a main beam photodetector (hereinafter referred to as "PD _M ") 2 and subbeam photodetectors (hereinafter referred to as "PD _M "). In each of " PDs1, PDs2 " (1, 3), they are converted into electrical signals independently. At this time, the signal converted in the PD _M (2) includes the crosstalk component by the adjacent tracks 21 and 23, and the signal converted in the PDs1 and PDs2 (1, 3) is the adjacent tracks 21 and 23. The light irradiated to each is converted into an electrical signal to detect a crosstalk component included in the reflected light of the main beam 12. Each of the detection signals of PDs1 and PDs2 (1,3) is inputted to a transversal filter (hereinafter referred to as "TF") 4,6 and the output signal of TF (4,6) is inputted to the calculator 8. This is added or subtracted from the reproduction signal detected from the target track 22 (ie, the output signal of the second photodetector) to remove the crosstalk component included in the main beam 12. On the other hand, the crosstalk removal method described above considers the tilt of the recording medium which greatly changes the crosstalk amount of the reproduction signal, the defocus amount and the detracking amount of the optical spot on the optical recording medium. Therefore, it is difficult to remove the crosstalk component that varies depending on such driving conditions. According to the method disclosed in Japanese Patent Laid-Open No. 6-243473 as a method for solving such a problem, the gain value of the output signal of the above-described TF (4, 6) is changed according to the detected tilt amount or the like. However, continuously updating the gain value or the filter coefficient value of the TF (4,6) according to the amount of tilt detected in real time burdens the system and generates a local minimum in the process of calculating the optimum filter coefficient. There is a problem in that it is not easy to find a local minimum), so it is impossible to find an optimum gain value or filter coefficient value.

It is therefore an object of the present invention to provide an optical recording / reproducing apparatus and method for removing crosstalk components in accordance with driving conditions such as tilt amount, coma aberration, defocusing or detracking of an optical recording medium.

In order to achieve the above object, the optical recording / reproducing apparatus according to the present invention divides the light from the light source to irradiate the main beam to the target track, and to irradiate the subbeams to adjacent tracks adjacent to the target track, as well as the main beam and the subbeam. Optical system / photodetecting means for converting the reflected light into electric signals; Driving condition sensing means for sensing a driving condition of the optical recording medium currently being driven; A memory for classifying and storing a filter coefficient calculated to convert frequency characteristics of the sub-beams into frequency characteristics of the crosstalk component of the main beam corresponding to different driving conditions; Filter means for converting each reproduction signal of the sub-beams according to the filter coefficients into frequency characteristics; Frequency characteristic control means for calculating and classifying the filter coefficients and storing and classifying and storing the filter coefficients in the memory, and reading the filter coefficients from the memory and supplying the filter coefficients to the filter means according to driving conditions of the optical sensing medium currently detected; And calculating means for adding or subtracting the output signal of the filter means and the reproduction signal of the main beam.

The driving condition is any one of tilt, coma aberration, defocus, and detracking.

The driving conditions are at least two of tilt, coma aberration, defocus and detracking.

The frequency characteristic control means calculates a filter coefficient according to a normal state, the filter coefficient stored in the memory, and a filter coefficient according to a state out of the normal state, and classifies and stores the filter coefficient in the memory.

The frequency characteristic control means calculates a new filter coefficient in a region near the filter coefficient value stored in the memory when it is detected that the change of the driving condition which is currently sensed is insignificant.

The optical recording / reproducing apparatus according to the present invention divides the light from the light source to irradiate the main beam to the target track, to irradiate the subbeams to adjacent tracks adjacent to the target track, and to transmit the reflected light of the main beam and the subbeams to the electric signal X. Means; Driving condition sensing means for sensing a driving condition of the optical recording medium currently being driven; A first filter coefficient calculated to convert the frequency characteristics of the sub-beams into the frequency characteristics of the crosstalk component of the main beam and the frequency characteristics of the main beams corresponding to different driving conditions, and are generated in the track direction of the target track. A memory for classifying and storing a second filter coefficient calculated to remove inter-interference; First filter means for converting each of the reproduction signals of the subbeams into frequency characteristics of the subbeams according to the first filter coefficient; Second filter means for converting the frequency characteristics of the main beams by converting the frequency characteristics of the main beams according to the second filter coefficients; Calculating and classifying the first and second filter coefficients into the memory, reading the first filter coefficients from the memory, and supplying the first filter coefficients to the first filter means according to driving conditions of the optical recording medium currently sensed. Frequency characteristic control means for calculating the second filter coefficient and supplying it to the second filter means; And calculating means for adding or subtracting the output signal of the first filter means and the output signal of the second filter means.

The optical recording / reproducing method of the present invention comprises the steps of: irradiating a main beam to a target track and irradiating subbeams to adjacent tracks adjacent to the target track to convert reflected light of the main beam and the subbeams into electrical signals, respectively; The filter coefficients calculated to convert the frequency characteristics of the sub-beams into the frequency characteristics of the crosstalk component of the main beam corresponding to different driving conditions are pre-classified and stored to convert the frequency characteristics of each of the reproduction signals of the sub-beams using the filter coefficients. Steps.

Other objects and advantages of the present invention in addition to the above object will become apparent from the description of the preferred embodiment of the present invention with reference to the accompanying drawings.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIGS. 2 to 5.

2 is a block diagram schematically showing an optical recording / reproducing apparatus according to an embodiment of the present invention.

In the arrangement of Fig. 2, the optical recording / reproducing apparatus according to the present invention electrically transmits the main beam 12 irradiated to the target track 22 and the subbeams 11 and 13 irradiated to the adjacent tracks 21 and 23, respectively. PD _M , PDs1 and PDs2 (1,2,3) and the frequency characteristics according to the driving conditions are stored in advance to convert the signal into the optimal signal, and the optimum frequency characteristics are read out under the current driving conditions according to the change of the driving conditions. A first frequency characteristic controller 42 for calculating the filter coefficient accordingly and a first characteristic for adjusting the frequency characteristics of each of the output signals of PD _M , PDs 1 and PDs 2 (1, 2, 3) to an optimum value according to the driving conditions; A calculator 40 for removing crosstalk components included in the main beam 12 by subtracting the third to third TFs 34, 36, 38 and the output signals of the first to third TFs 34, 36, 38. And a drive for detecting driving conditions such as tilt amount, coma aberration, defocusing or detracking amount of the currently driven optical recording medium. Articles provided with a detector (44). The light emitted from the laser light source is separated into three beams of the main beam 12 and the subbeams 11 and 13 by means of a diffraction grating element or a phase plate (not shown) and the like, respectively by an objective lens (not shown). At 22 and adjacent tracks 21 and 23 are condensed in the form of light spots. The main beam 12 and the sub beams 11 and 13 are reflected from the optical recording medium such that the main beam 12 is irradiated to the PD _M 2 and the sub beams 11 and 13 are respectively PDs 1 (1) and PDs 2 (3). ) Is irradiated and converted into an electrical signal. Here, the PD _M 2 is constituted by a two or four split photodetector so that the focus error signal and the tracking error signal can be detected. The first and third TFs 34 and 38 are connected in series to the PDs 1 and PDs 2, respectively, and are output from the PDs 1 and PDs 2 by a filter coefficient supplied from the frequency characteristic controller 42. The frequency characteristic of the signal is converted and supplied to the calculator 40. Here, the second TF 36 is serially connected to the PD _M 2 and generated by tilting in the track direction (or tangential direction) in the target track 22 by the filter coefficient supplied from the frequency characteristic controller 42. The inter-signal interference component is eliminated. The operator 40 is commonly connected to the frequency characteristic controller 42 and the first to third TFs 34, 36, 38, so that the second TF 36 has a gain value and a delay time supplied from the frequency characteristic controller 42. By subtracting the output signals of the first and third TFs 34 and 38 to the output signals of the < RTI ID = 0.0 >),< / RTI > The driving condition detector 44 senses the tilt amount, skew, and the like of the optical recording medium or the optical pickup using a sensor (for example, an optical sensor), and supplies the driving condition detection signal to the frequency characteristic controller 42 as a driving condition detection signal. And a signal processing unit (not shown) for detecting servo error signals such as focus error signals and tracking error signals from the output signals of the PD _M 2 and supplying the servo error signals to the frequency characteristic controller 42. It will play a role.

The frequency characteristic controller 42 is connected to the driving condition detector 44 to determine the driving condition of the optical recording medium currently driven according to the driving condition detection signal supplied from the driving condition detector 44 to determine the degree of deviation from the normal driving condition. You will know. The frequency characteristic controller 42 is connected to the first to third TFs 34, 36, and 38, respectively, and stores the filter coefficient values according to different driving conditions classified in advance in the form of a ROM table. The optimum filter coefficient is read out from the ROM according to the amount of change in the driving conditions of and is supplied to the first to third TFs 34, 36, 38. The filter coefficients stored in the ROM table form are coefficient values calculated to convert the frequency characteristics of the sub-beam reproduction signals that are different under different driving conditions into the frequency characteristics of the main beam crosstalk components that are different under different driving conditions. The optical recording medium may have a certain amount of tilt due to eccentricity or the like, and the optical pickup may have a certain amount of tilt due to assembling accumulation tolerance and the like. If there is a tilt, the crosstalk components in adjacent tracks 21 and 23 that affect the main beam 12 irradiated to the target track 22 to be reproduced are different. The frequency characteristic controller 42 controls the first and third TFs 34 and 38 by supplying pre-stored filter coefficients to the first and third TFs 34 and 38 according to the tilt amount of the optical recording medium currently driven. As a result, the reproduction signals of the subbeams 11 and 13 reflected by the adjacent tracks 21 and 23 are converted into frequency characteristics corresponding to the crosstalk components of the main beam 12.

3 to 5 are characteristic diagrams showing frequency characteristics with and without tilt of the optical recording medium. 3 to 5, the horizontal axis represents spatial frequency (frequency of nT = 1024 / n, n = 3,4 ... 11) according to the pit size (3T-11T), and the vertical axis shows no tilt at all. The normalized value when the DC component value is 1 is shown. In the absence of tilt at all, the crosstalk component of the main beam by the adjacent tracks 21 and 23 has a frequency characteristic as shown in FIG. 3A and the subbeams 11 and 13 irradiated to the adjacent tracks 21 and 23. The reproducing signal has a frequency characteristic as shown in FIG. In this case, as the filter coefficients stored in the ROM table, coefficient values calculated so that the frequency characteristics of the sub-beam reproduction signal as shown in FIG. 3B become the frequency characteristics of the main beam crosstalk component as shown in FIG. 3A are stored. As such, when no tilt exists in the optical recording medium or the optical pickup, the reproduction signal of the sub-beams 11 and 13 reflected by the inner and outer peripheral tracks 21 and 23 around the target track 22 Since the same frequency characteristics as shown in FIG. 3B are provided, the same filter coefficients are supplied to the first and third TFs 34 and 38. On the other hand, if there is a tilt of ± 0.6 ° on the inner circumference and the outer circumference of the target track 22, the adjacent track on the adjacent track side having a tilt of -0.6 ° around the track of the objective track 22 is located on the adjacent track. The crosstalk component of the main beam 12 has the frequency characteristic as shown in FIG. 4A, and the reproduction signal of the sub-beam irradiated to the adjacent track has the frequency characteristic as shown in FIG. 4B. In this case, the filter coefficient stored in the ROM table stores a coefficient value calculated such that the frequency characteristic of the subbeam reproduction signal as shown in FIG. 4B becomes the frequency characteristic of the crosstalk component of the main beam as shown in FIG. 4A. On the adjacent track side where + 0.6 ° tilt exists around the target track 22, the reproduction signal of the crosstalk component of the main beam 12 by the adjacent track has the frequency characteristic as shown in FIG. The reproduction signal of the sub-beam irradiated onto has the frequency characteristic as shown in FIG. 5B. In this case, the filter coefficients stored in the ROM table store coefficient values calculated so that the frequency characteristics of the sub-beam reproduction signals as shown in FIG. 5B become the frequency characteristics of the main beam crosstalk components as shown in FIG. 5A. As such, when the tilt is present in the optical recording medium or the optical pickup, the tilts appear simultaneously at opposite inclinations on the inner and outer peripheral tracks 21 and 23 with respect to the target track 22, so that the count value stored in the ROM table The different filter coefficient values are stored for the sub-beams 11 and 13 reproduction signals.

The filter coefficient values stored in the ROM table are calculated according to the respective tilt amounts when the tilt amounts are varied at predetermined tilt amount periods. For example, filter coefficient values corresponding to the tilt amount are calculated and stored in the ROM at predetermined tilt amount periods such as ± 0.2, ± 0.4, and ± 0.6. On the other hand, when the tilt amount other than the predetermined tilt amount value is detected as described above, the frequency characteristic controller 42 calculates a new coefficient value using the stored filter coefficient value and supplies it to the first and third TFs 34 and 38. That is, the frequency characteristic controller 42 calculates a filter coefficient suitable for the current driving condition by using the set steady state filter coefficient, the filter coefficient stored in the ROM table, and the change of the driving condition of the degree out of the normal state. For example, when the tilt amount of the currently driven optical recording medium is ± 0.3, the sub-beam reproduction signal is supplied by supplying the intermediate values of the filter coefficients according to the tilt amounts of ± 0.2 and ± 0.4 to the first and third TFs 34 and 38. It converts the frequency characteristic of. In addition, since the frequency characteristic controller 42 may have a slight change in the driving conditions due to defocus, detracking, or the like, the frequency characteristic controller 42 calculates the servo error signals such as the focus error signal and the tracking error signal supplied by the driving condition detector 44. The coefficient value is updated little by little around the used filter coefficient. The frequency characteristic controller 42 calculates the filter coefficient in the same manner as described above for the driving conditions such that the regeneration signal of the sub-beam may be degraded, as well as the tilt amount, the defocus amount, the detracking amount, the coma aberration, and the like. Can be tabled

As described above, the optical recording / reproducing apparatus and method of the present invention converts the frequency characteristic of the sub-beam reproduction signal into the frequency characteristic of the crosstalk component included in the main beam reproduction signal according to different driving conditions, and cross-talk according to the driving conditions. Ingredients can be removed.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

1 is a block diagram showing a crosstalk removing apparatus using a conventional three beams.

2 is a block diagram showing an optical recording / reproducing apparatus according to an embodiment of the present invention.

3A and 3B are characteristic diagrams showing frequency characteristics of the crosstalk component of the main beam and frequency characteristics of the subbeam when there is no tilt;

4A and 4B are characteristic diagrams showing frequency characteristics of the crosstalk component of the main beam and frequency characteristics of the subbeam when there is a tilt of -0.6 °.

5A and 5B are characteristic diagrams showing the frequency characteristics of the crosstalk component of the main beam and the frequency characteristics of the subbeam when there is a tilt of + 0.6 °;

<Brief description of symbols for the main parts of the drawings>

1,2,3: photodetector 4,6,34,36,38: transversal filter

8,40 calculator 11,13 bubeam

12: main beam 21, 23: adjacent track

22: destination track 42: frequency characteristic controller

44: driving condition detector

Claims (11)

Optical / photodetecting means for dividing the light from the light source to irradiate the main beam to the target track, to irradiate the subbeams to adjacent tracks adjacent to the target track, and to convert reflected light of the main and subbeams into an electrical signal; Driving condition sensing means for sensing a driving condition of the optical recording medium currently being driven; A memory for classifying and storing a filter coefficient calculated to convert frequency characteristics of the sub-beams into frequency characteristics of the crosstalk component of the main beam corresponding to different driving conditions; Filter means for converting each reproduction signal of the sub-beams according to the filter coefficients into frequency characteristics; Frequency characteristic control means for calculating and classifying the filter coefficients and storing and classifying and storing the filter coefficients in the memory, and reading the filter coefficients from the memory and supplying the filter coefficients to the filter means according to driving conditions of the optical sensing medium currently detected; And calculating means for adding or subtracting the output signal of the filter means and the reproduction signal of the main beam. The method of claim 1, And the driving condition is any one of tilt, coma aberration, defocus, and detracking. The method of claim 1, And the driving condition is at least two of tilt, coma aberration, defocus, and detracking. The method of claim 1, And the frequency characteristic control means calculates a filter coefficient according to a normal state, the filter coefficient stored in the memory, and a filter coefficient according to a state out of the normal state, and classifies and stores the filter coefficient in the memory. . The method of claim 1, And the frequency characteristic control means calculates a new filter coefficient in a region near the filter coefficient value stored in the memory when it is detected that the change of the driving condition currently sensed is insignificant. Optical / photodetecting means for dividing the light from the light source to irradiate the main beam to the target track, to irradiate the subbeams to adjacent tracks adjacent to the target track, and to convert reflected light of the main and subbeams into an electrical signal; Driving condition sensing means for sensing a driving condition of the optical recording medium currently being driven; A first filter coefficient calculated to convert the frequency characteristics of the sub-beams into the frequency characteristics of the crosstalk component of the main beam and the frequency characteristics of the main beams corresponding to different driving conditions, and are generated in the track direction of the target track. A memory for classifying and storing a second filter coefficient calculated to remove inter-interference; First filter means for converting each of the reproduction signals of the subbeams into frequency characteristics of the subbeams according to the first filter coefficient; Second filter means for converting the frequency characteristics of the main beams by converting the frequency characteristics of the main beams according to the second filter coefficients; Calculate and classify the first and second filter coefficients in the memory, and read out the first filter coefficients from the memory and supply the first filter coefficients to the first filter means according to a driving condition of the optical recording medium. Frequency characteristic control means for calculating the second filter coefficient and supplying it to the second filter means; And calculating means for adding or subtracting the output signal of the first filter means and the output signal of the second filter means. Irradiating the main beam to the target track and irradiating the subbeams to adjacent tracks adjacent to the target track to convert reflected light of the main beam and the subbeams into an electrical signal, respectively; The filter coefficients calculated to convert the frequency characteristics of the sub-beams into the frequency characteristics of the crosstalk component of the main beam in response to different driving conditions are pre-classified and stored to convert the frequency characteristics of the reproduction signals of the sub-beams using the filter coefficients. Optical recording / reproducing method comprising the steps of: The method of claim 7, wherein And the filter coefficient is read in response to a driving condition of a currently driven optical recording medium. The method of claim 7, wherein And subtracting a reproduction signal of the sub-beams whose frequency characteristics are converted into the main beam reproduction signal. The method of claim 7, wherein Calculating a filter coefficient according to a steady state, the stored filter coefficient and a filter coefficient according to a state out of the normal state. The method of claim 7, wherein And a new filter coefficient is calculated in a region near the stored filter coefficient value when it is detected that the change of the currently detected driving condition is insignificant.